Scaling Up Nutrition in the INTERNATIONAL DE VELOPMENT IN FOCUS Arab Republic of Egypt Investing in a Healthy Future Christopher H. Herbst, Amr Elshalakani, Jakub Kakietek, Alia Hafiz, and Oliver Petrovic, Editors INTERNATIONAL DEVELOPMENT IN FOCUS Scaling Up Nutrition in the Arab Republic of Egypt Investing in a Healthy Future CHRISTOPHER H. HERBST, AMR ELSHALAKANI, JAKUB ­K AKIETEK, ALIA HAFIZ, AND ­OLIVER PETROVIC, EDITORS © 2020 International Bank for Reconstruction and Development / The World Bank 1818 H Street NW, Washington, DC 20433 Telephone: 202-473-1000; Internet: www.worldbank.org Some rights reserved 1 2 3 4 22 21 20 19 Books in this series are published to communicate the results of Bank research, analysis, and operational experience with the least possible delay. The extent of language editing varies from book to book. This work is a product of the staff of The World Bank with external contributions. 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Contents Foreword by Rekha Menon   ix Foreword by Bruno Maes   xi Acknowledgments  xiii Executive Summary  xv Abbreviations  xxv Background  1 Study objective and rationale   2 Methods and analytical approach   2 Structure of the report   3 References  3 Undernutrition of Children Under 5 and Women of CHAPTER 1  Reproductive Age in Egypt   5 Jonathan Kweku Akuoku Key messages  5 Introduction  5 Methodology  6 Undernutrition of children 0–59 months of age   8 Conclusions  23 Notes  25 References   26 Overnutrition of Children Under 5 and Women of CHAPTER 2  Reproductive Age in Egypt   29 Frank Hu and Yanping Li Key messages  29 Introduction  29 Childhood overweight and obesity   30 Double burden of stunting and overweight    36 Overweight and obesity in women of reproductive age   40 Conclusions  52 References   53 Undernutrition Interventions in Egypt: Status, Gaps, and CHAPTER 3  Opportunities  57 Fayrouz Sakr-Ashour, Bjorn Ljungqvist, and Matthew Robinson Key messages  57 Introduction  58  iii iv | Scaling Up Nutrition in the Arab Republic of Egypt Nutrition-specific interventions  59 Nutrition-sensitive interventions  75 Recommendations: Potential high-impact ­ policy and program options to consider for Egypt    88 nutrition ­ Approaches to scaling up the identified interventions    92 Elements critical to scale-up success   94 Notes  95 References  95  ost-Effectiveness of Potential Scale-Up Scenarios in CHAPTER 4 C Egypt  101 Davide de Beni Key messages  101 Introduction  101 Methodology   102 Findings  108 Conclusions  124 Notes  125 References   125  iscal Space to Scale Up Nutrition in Egypt   129 CHAPTER 5 F Helen C. Connolly Key messages  129 Estimating the current level of spending on nutrition in Egypt  130 Identifying fiscal space for nutrition: The five pillars   135 Summary of fiscal space   141 Notes  143 References  143  tatistical Methods Applied to Analysis of the Determinants APPENDIX A S of Malnutrition among Egyptian Children   145  istribution of Sample by Key Characteristics and APPENDIX B D Regression Analysis Results  149 Glossary  155 Boxes 1.1 Evidence of and recommendations on the increased nutritional needs of children  7 3.1 Why 1,000 days?   59 3.2 Common challenges in micronutrient supplementation programs in Egypt  67 Figures 1.1 UNICEF conceptual framework for the determinants of malnutrition   6 1.2 Prevalence of stunting among children under 5: Middle East and North Africa economies, various years   9 1.3 Trends in stunting prevalence among children under 5: Middle East and North Africa economies, 1990–2016   10 1.4 Trends in stunting prevalence across regions: Egypt, 1992–2014    10 1.5 Trends in stunting prevalence across wealth quintiles: Egypt, 1995–2014   11 1.6 Trends in stunting prevalence across urban and rural areas: Egypt, 1992–2014  11 1.7 Trends in stunting prevalence by child’s sex: Egypt, 1992–2014   12 1.8 Breastfeeding practices, complementary feeding practices, and incidence of disease among children 0–23 months of age: Egypt   13 1.9 Adjusted odds ratio for significant determinants of stunting among rural Egyptian children 0–23 months of age   15 Contents | v 1.10 Adjusted odds ratio for significant determinants of stunting among urban Egyptian children 0–23 months of age   16 1.11 Prevalence of wasting among children under 5: Middle East and North Africa economies, various years   17 1.12 Trends in wasting prevalence: Middle East and North Africa economies, 1990–2014  18 1.13 Trends in wasting prevalence across regions: Egypt, 1992–2014   18 1.14 Trends in wasting prevalence across wealth quintiles: Egypt, 1995–2014   19 1.15 Trends in wasting prevalence across urban and rural areas: Egypt, 1992–2014  19 1.16 Trends in wasting prevalence by child’s sex: Egypt, 1992–2014   19 1.17 Trends in anemia among children 6–59 months of age: Egypt, 2000, 2005, 2014  21 2.1 Prevalence of overweight among children under 5: Middle East and North Africa economies, various years   30 2.2 Trends in prevalence of childhood overweight: Middle East and North Africa economies, various years   31 2.3 Prevalence of overweight and obesity among children: Egypt, 2014   31 2.4 Time trend of overweight among infants and children by sex: Egypt, 1992–2014  32 2.5 Time trend of overweight among infants and children across urban and rural areas: Egypt, 1992–2014   32 2.6 Prevalence of overweight children by wealth index and region: Egypt, 2014  33 2.7 Prevalence of overweight children by birthweight, family size, mother’s obesity level, and mother’s education level: Egypt, 2014   34 2.8 Multivariate-adjusted odds ratio for overweight among children under 5: Egypt, 2014  35 2.9 Prevalence of overweight and stunting among children under 5: Egypt, 2014  36 2.10 Prevalence of overweight with and without stunting: Egypt, 1992–2014   37 2.11 Odds ratio for overweight (including obesity) with or without stunting: Egypt, 2014   38 2.12 Prevalence of overweight with and without stunting according to the number of food groups children 6–23 months of age living with their mother were fed in last 24 hours: Egypt, 2014   40 2.13 Trends in overweight and obesity among women of reproductive age: Egypt, 2000–2014  41 2.14 Prevalence of obesity among women in Middle East and North Africa countries, 2014    42 2.15 Prevalence of overweight and obesity across women 15–49 years of age: Egypt, 2014  43 2.16 Overweight and obesity prevalence among women in rural and urban areas: Egypt, 2014  43 2.17 Prevalence of obesity across sociodemographic factors: Egypt, 2014    44 2.18 Multivariate-adjusted odds ratio for obesity among women 15–49 years of age: Egypt, 2014   45 2.19 Interactions between education levels and household wealth, total number of childbirths, and age at first birth and their effects on obesity prevalence in women: Egypt, 2014   47 2.20 Comparison of mean BMI across age groups and BMI distribution among women who had a live birth in the five years preceding EDHS interview: Egypt, 1992 and 2014   48 2.21 Overweight and obesity prevalence among women who had a live birth in the five years preceding EDHS interview: Egypt, 1992–2014    49 2.22 Trends of obesity prevalence across education levels among women who had a live birth in the five years preceding EDHS interview: Egypt, 1992–2014   50 2.23 Obesity prevalence and household wealth among women who had a live birth in the five years preceding the EDHS interview: Egypt, 1995–2014   50 2.24 Coexistence of anemia and obesity by age among women: Egypt, 2014    51 vi | Scaling Up Nutrition in the Arab Republic of Egypt 2.25 Coexistence of anemia and obesity among women: Egypt, 2000, 2005, 2014  52 4.1 Estimated annual expenditure by governorate of maintaining interventions at current coverage  109 4.2 Annual financing requirements of maintaining current interventions and expanding to full national coverage by 2022   110 4.3 LiST underlying model for estimating impacts of nutrition preventive interventions: IYCF and micronutrients   111 4.4 LiST underlying model for estimating impacts of nutrition curative interventions: MAM and SAM   112 4.5 LiST underlying model for estimating impacts of maternal, neonatal, and child health interventions  112 4.6 LiST underlying model for estimating impacts of water, sanitation, and hygiene interventions  112 4.7 Under-5 mortality rates: current and full national coverage, 2017–22    114 4.8 Additional deaths of children 0–59 months of age prevented by scaling up interventions to full national coverage   114 4.9 Prevalence of stunting of children 0–59 months of age: current and full national coverage, 2017–30   115 4.10 Number of stunted children 0–59 months of age: current and full national coverage, 2017–30  116 4.11 Additional cases of stunting averted for children 0–59 months of age   116 4.12 Prevalence of wasting in children 0–59 months of age: current and full national coverage, 2017–22   117 4.13 Percentage of pregnant women with iron-deficiency anemia: current and full national coverage, 2017–22   117 4.14 Percentage of children under 6 months of age exclusively breastfed: current and full national coverage, 2017–22   118 4.15 Prevalence of stunting and population by governorate   120 4.16 Total and additional costs by scenario, 2018–22   121 4.17 Investments in nutrition build human capital and boost shared prosperity  123 5.1 Core Consumer Price Index (year-on-year percentage change): Egypt, 2011–18  136 5.2 GDP growth rate: Egypt, 2008–18   136 5.3 Revenue as percentage of GDP: Egypt, 2005–15   137 5.4 Health expenditure share of GDP: selected countries, 2008–14   138 Tables ES.1 Sixteen interventions selected to address malnutrition in Egypt   xix 3.1 Proposed breastfeeding support and complementary feeding practice interventions   62 3.2 Proposed growth monitoring and promotion interventions    64 3.3 Proposed vitamin A intervention for children   65 3.4 Proposed iron intervention for children   66 3.5 Proposed treatment of moderate acute malnutrition and severe acute malnutrition  68 3.6 Proposed treatment of diarrhea with zinc    69 3.7 Proposed deworming interventions    70 3.8 Proposed iron–folic acid interventions    72 3.9 Proposed WASH interventions    88 3.10 Nutrition interventions recommended for scale-up in Egypt   90 3.11 Advantages and disadvantages of scaling up by intervention to full national coverage  92 3.12 Advantages and disadvantages of scaling up package of interventions by region   93 3.13 Advantages and disadvantages of scaling up by intervention    93 4.1 Nutrition-specific and nutrition-sensitive interventions included in the analysis  103 Contents | vii 4.2 Baseline and target coverage rates per intervention   104 4.3 Default program cost categories and percentages    105 4.4 Unit costs per average case by intervention   106 4.5 Total and annual costs for current coverage scenario   108 4.6 Total and annual costs for full national coverage scenario   110 4.7 Costs and benefits for full national coverage scenario   119 4.8 Costs and benefits for all scenarios   122 4.9 Cost, benefits, and benefit-cost ratios   124 5.1 Estimated fiscal space indicators: Egypt, 2016   130 5.2 National Health Accounts indicators of health expenditure: Egypt, 2012 and 2015  132 5.3 Committed and disbursed external funding, total and basic nutrition: Egypt, 2007–16  133 ­ 5.4 Fiscal space for nutrition in Egypt   142 A.1 Indicators for feeding practices   146 B.1 Distribution of sample of children 0–23 months of age by child, ­ maternal, and household characteristics  150 B.2 Adjusted odds ratio of stunting for children 0–23 months of age in Egypt  152 B.3 Adjusted odds ratio of stunting for urban children 0–23 months in Egypt  153 B.4 Adjusted odds ratio of stunting for rural children 0–23 months in Egypt  154 Foreword Maximizing the nutrition status of women and children is not just a moral obli- gation but also critical from an economic perspective to increase the well-being of the individuals and ensure a more inclusive and just society. Nutrition is an essential component of strengthening human capital—the knowledge, skills, and health that people accumulate so they can become productive members of soci- ety. Moreover, investments in nutrition interventions, in particular those that target women and children, pay off not only in economic terms but also in sup- porting the success of other development interventions. The Middle East and North Africa Health, Nutrition, and Population Team of the World Bank is working across the region to maximize rapid progress toward a world in which mothers are healthy and all children arrive in school well-­ nourished and ready to learn, can expect to attain real learning in the classroom, and are able to enter the job market as healthy, skilled, and productive adults. This is closely aligned with the broader efforts by the World Bank of supporting countries in the Middle East and North Africa region move from stabilization to ­ transformation, unlock the vast economic potential of youth and women, and ease the constraints that hamper their creative energies. This report, Scaling Up Nutrition in the Arab Republic of Egypt: Investing in a Healthy Future, was produced in close collaboration with UNICEF Egypt. It gen- erates new important evidence on the nutrition situation in Egypt, including evi- dence to help policy makers understand the potential benefits of scaling up key interventions and to identify and prioritize the most cost-effective package of interventions. The findings of the report will be of interest to researchers and policy makers involved in developing and implementing nutrition interventions and all those who are working toward the goal of maximizing human capital in Egypt and beyond.   Rekha Menon   Practice Manager   Health, Nutrition and Population   Middle East and North Africa Region   World Bank Group  ix Foreword This investment case in nutrition shows that the faces of malnutrition in Egypt are changing, revealing a triple health burden: persistent stunting, increasing wasting, and rapidly rising overweight among children, a rate that is now one of the highest in the world. Far too many children are not getting the diets they need. This deprivation undermines their capacity to grow, develop, and learn to their full potential. UNICEF recently launched The State of the World’s Children report, under- scoring its commitment to improving the nutrition of children and highlighting UNICEF’s new nutrition strategy, setting out the plan to improve the nutrition of children and women. We know what actions are needed to prevent malnutri- tion. A positive change needs the political determination of the government across the sectors of health, education, water and sanitation, and education and food systems. It needs the right amount of funding, including investment from the private sector. By working together, we can ensure that every child, young person, and woman has affordable access to the nutritious, safe, and sustainable diets they need. I want to express our commitment to work for better nutrition for every child, especially in the crucial first 1,000 days—from conception to the age of two years—and during adolescence, two unparalleled windows of opportunity for child development.   Bruno Maes   UNICEF Representative in Egypt  xi Acknowledgments This report was prepared under the overall guidance of Ernest Massiah (practice manager, World Bank) and Asad Alam (director, World Bank). It was led by a team composed of Christopher H. Herbst (senior health specialist, World Bank) and Amr Elshalakani (senior health specialist, World Bank). The team worked closely with Alia Hafiz (senior nutrition officer, UNICEF Egypt), Jakub Kakietek (economist, World Bank), and Oliver Petrovic (chief of Child Survival and Early Development Section, UNICEF Egypt), who provided guidance and support on development of the report. Matthew Robinson (consultant, World Bank) pro- vided invaluable advice and input on ­ editorial and structural matters. Editors of the overall report are Christopher H. Herbst, Amr Elshalakani, Jakub Kakietek, Alia Hafiz, and Oliver Petrovic. Chapters were authored by a combination of World Bank staff and consultants. Chapter 1 was written by Jonathan Kweku Akuoku (World Bank); chapter 2 by Frank Hu and Yanping Li (Harvard University); and chapter 3 by Fayrouz Sakr-Ashour (University of Maryland), Bjorn Ljungqvist, and Matthew Robinson (independent nutrition consultants). Rania Abdelnaeem and Nahla Zeitoun (World Bank) provided crit- ical input for the chapters on social protection–related issues and interventions. Chapter 4 was authored by Davide de Beni (United Nations Population Fund) and chapter 5 by Helen C. Connolly (American Institutes for Research). The team would like to extend particular thanks to the following World Bank staff (in alphabetical order) for their valuable advice and support throughout the development of the report: Hanzada Aboudoh, Gustavo Demarco, Mariam Ghaly, Poonam Gupta, Sherif Hamdy, Aliya Husain, Fatima Mansouri, Layla Mohamed- Kotb, Rekha Menon, and Mariam William Guirguis. The team would also like to sincerely thank the minister and staff of Egypt’s Ministry of Health and Population and other key agencies and development partners for their guidance, assistance, and contributions during this study. Last but not least, the team would like to thank Meera Shekar (global lead on nutrition, World Bank) and the Scaling up Nutrition (SUN) Trust Fund donors for the financial contribution that made the production of this report possible. Financial support for this work was provided by the government of Japan through the Japan Trust Fund for Scaling Up Nutrition.  xiii Executive Summary The Arab Republic of Egypt has achieved significant improvements in key health indicators over the last 30 years, particularly maternal and infant mortality. However, Egypt has been identified as one of the 36 countries in which 90 ­percent of the global burden of malnutrition falls (Horton et al. 2010). It is, then, facing the growing challenge of a “double burden” because overweight and obesity among children and women of reproductive age are rising, along with the inci- dence of wasting, whereas the level of stunting has plateaued. As a result, Egypt is currently on track to meet only one of the six nutrition targets established by the World Health Assembly (WHA) for 2025 (WHO 2017). Malnutrition is a huge burden on Egypt’s economy. According to the study The Cost of Hunger in Egypt (IDSC 2014), undernutrition, as manifested in poor linear growth (stunting), wasting and micronutrient deficiencies in children, and anemia in women of reproductive age, will sap an estimated 1.9 percent of Egypt’s annual gross domestic product (GDP) through productivity foregone and costs to the health system. Altogether the economic hemorrhaging will amount to about $3.6 billion a year. At the same time, as noted, Egypt is facing a further challenge from the coexistence of overweight and obesity with undernu- trition among children, leading to a double burden of malnutrition. The government of Egypt (GoE) has shown a strong political commitment to assessing and addressing malnutrition. A nutrition “landscape analysis,” the first in Arab countries, was carried out by the Ministry of Health and Population (MOHP) and the United Nations Children’s Fund (UNICEF) in 2011 (MOHP 2012) to complement the ministry’s 10-year National Food and Nutrition Policy and Strategy 2007–2017 (NFNPS). The landscape analysis described the extent of the malnutrition problem (including rising obesity rates) in Egypt and pro- vided possible solutions to optimize outcomes with the available resources. It provided clear immediate, medium-term, and long-term recommendations to guide investments in nutrition. Two more recent policy reports, the Nutrition Agenda for Action (MOHP, NNI, and UNICEF 2017) and the Nutrition Stakeholder and Action Mapping Report (MOHP and UNICEF 2017) further specified the key challenges and corresponding priority actions needed to strengthen nutrition governance, coordination, and accountability mechanisms, as well as mobilize the available resources to improve the targeting and coordination of nutrition interventions in the most vulnerable areas.  xv xvi | Scaling Up Nutrition in the Arab Republic of Egypt The objective of this report, developed at the request of the government of Egypt in close collaboration with UNICEF, is to help inform the development of an updated nutrition policy and strategy and to guide nutrition investments over the next five years. The report provides an updated overview of Egypt’s nutrition situation, the nutrition-specific and nutrition-sensitive interventions currently in place, opportunities to scale up the response to alleviate the burden of malnu- trition, estimates of the costs and benefits of scaling up key interventions, and analyses of the fiscal space required to implement these key interventions at scale. Although the overnutrition situation in Egypt is discussed in chapter 2, in the remainder of the chapters in this book the emphasis is on undernutrition. Additional considerations and analyses will be needed to address overnutrition challenges and the rising obesity rates. Nutrition status and determinants among children and women in Egypt This assessment of nutrition status uses the UNICEF conceptual framework of malnutrition and analyses data from the Egypt Demographic and Health Survey (EDHS) to understand the status and trends of key indicators and identify the immediate, underlying, and basic determinants of malnutrition in Egypt. Stunting remains at a high level of public health significance in Egypt, with the prevalence among children under 5 higher than the average in the Middle East and North Africa region. Although there are less discernible differences in the levels across wealth quintiles, the reduced disparity has been due in part to the greater downward trends among the poorest wealth quintiles and in part to a significant upward trend among children from the richest wealth ­ quintiles. There is a general downward trend across the regions of Egypt, but prevalence has sharply increased in urban Upper Egypt in more recent years. The declining trend is significant for both boys and girls, as well as in rural but not urban areas. Key determinants of stunting include being a boy, maternal ­ education, size at birth, urban residence, and residence in urban Upper Egypt. Wasting has increased significantly since 2000, rising from a low to a medium level of public health significance after 2005 and steadily climbing since. The increasing trend is significantly higher for the frontier governorates (versus urban governorates) and among girls. The increasing trend in wasting preva- lence is also significant across urban and rural areas. Similarly, there is an increasing trend across all wealth quintiles. Key determinants of wasting include residence in the frontier governorates, younger age, birth order, and maternal body mass index (BMI). Egypt is facing the challenge of the double burden of malnutrition, with almost 15 percent of children under 5 overweight. Overweight is a significant and increasing public health problem in Egypt, with rates increasing steadily since the 1990s among children under 5, and particularly among those living in urban areas. Children who are overweight or obese are at an increased risk of obesity in adulthood (Black et al. 2013) and are at a higher risk of developing serious health problems, including type 2 diabetes, high blood pressure, and liver disease (WHO 2014). Meanwhile, among the 14.9 percent of overweight children in Egypt in 2014, 7.6 percent were also stunted. This double burden should be considered in any strategy or intervention designed to tackle malnutrition. High levels of overnutrition are affecting women of reproductive age, with more than 80 percent overweight or obese. The prevalence of obesity among Executive Summary | xvii women is alarmingly high across all wealth groups and education levels. Diet quality in Egypt is heavily influenced by long-standing food subsidy policies that focus on energy-dense foods. This may have resulted in the overconsumption of calories by Egyptians, especially poor and rural populations. Rising food prices and food inaccessibility have led more families to revert to calorie-dense foods rather than consume nutrient-rich foods (WFP 2013), resulting in a higher like- lihood of being overweight. EDHS data and the literature reveal that maternal obesity is a critical factor in the development of childhood obesity, and thus the time period of pregnancy and childbirth is an important window for the preven- tion of maternal obesity. Although the recent data on micronutrient status and deficiency are limited, the available data indicate high levels of anemia among both children and women and reduced consumption of iron and vitamin A–rich foods among children under 5. In 2014 almost one-third of children between 6 and 59 months of age were anemic, which was an improvement since 2008, but still detrimentally high. The anemia prevalence among children has been especially high in the frontier governorates and rural areas and in children from poorer households. Fewer than one in seven children 6–59 months of age received a vitamin A sup- plement in the short term. However, this low rate is likely due to vitamin A cap- sule (VAC) supplementation being provided only in conjunction with the immunization visits at 9 and 18 months. Only about one in three women of reproductive age in Egypt report receiving vitamin A supplements after their delivery, although it can prevent night blind- ness and support the immune function. The level of supplementation is showing a declining trend and also varies significantly across regions of Egypt. Anemia in pregnancy is related to higher maternal mortality, low birthweight, and increased perinatal mortality. Iron deficiency can result from inadequate consumption of iron-rich foods and, among women of reproductive age, the depletion of iron stores during menstruation. Iron supplementation during pregnancy is a key intervention to reduce levels of anemia. In 2014 a majority of women (67 ­percent) reported receiving iron supplements during their last pregnancy—a significant increase over 2008 (42.5 percent). Undernutrition interventions in Egypt: status, gaps, and opportunities Compared with many other countries affected by a large and detrimental burden of malnutrition, Egypt, as a lower-middle-income country, has strong resources and institutional frameworks (including private sector) that should be able to initiate and sustain effective nutrition actions at scale. To date, however, Egypt has not achieved a high or sustained level of impact from implementing a signif- icant number of nutrition-relevant interventions over an extended period of time. Recent global evidence points toward focusing on critical nutrition interven- tions during the 1,000-day period from a child’s conception until second birth- day. Because the majority of the linear growth deficits that make up the under-5 stunting burden accumulate during this time, reflecting nutrition deficiencies, interventions during this period have the greatest impact on nutrition outcomes and ensure that children have every opportunity to grow and thrive (Victora et al. 2010). The 2013 Lancet series on maternal and child nutrition identified 10 evidence-based, nutrition-specific interventions that would most effectively xviii | Scaling Up Nutrition in the Arab Republic of Egypt address undernutrition and micronutrient deficiencies within this period (Bhutta et al. 2013). However, Egypt is currently experiencing gaps in the cover- age of many key interventions, resulting in suboptimal nutritional status among infants and young children. Nutrition interventions provided at nominal fees (almost free of charge) by the public primary health care and maternal and child health system have mainly targeted pregnant and lactating women as well as children under 5. These inter- ventions include growth monitoring and promotion (GMP), infant and young child feeding (IYCF), social and behavior change communication (SBCC), iron– folic acid (IFA) supplementation in pregnancy, iron supplementation in children 0–24 months of age, and vitamin A supplementation for postpartum mothers and infants and young children. Other major investments in addressing hunger and malnutrition on a national scale have been primarily through food fortification and heavy food subsidies. Universal salt iodization (USI) can be considered a success story, currently reach- ing 91 percent of households. National programs to fortify oil with vitamin A and wheat flour with iron unfortunately were suspended in the aftermath of the 2011 revolution before they could be fully evaluated. Food subsidy interventions have existed for decades in Egypt. However, the mainly calorie-dense and nutrient-poor food items provided through the subsidy program may have encouraged greater consumption of these at the expense of other food groups, notably in urban Egypt. A recent study found that, when compared with nonbeneficiaries, the probability of mothers being overweight was higher among beneficiary families (Breisinger et al. 2013). However, recent changes to the subsidy program have added a wider range of subsidized foods, although beneficiaries are now required to submit a copayment for the subsidized commodities, which may limit access among poorer households. As for other nutrition-sensitive interventions that involve the nonhealth sec- tors, emerging evidence points toward good opportunities in the area of water, sanitation, and hygiene (WASH) interventions (especially in underserved com- munities). The cash transfer scheme, Takaful, has added conditionalities that give households incentives to invest in health, nutrition, and education (regular school attendance and health care visits for pregnant women and young chil- dren). A 2018 evaluation by the International Food Policy Research Institute (IFPRI) revealed some encouraging results in terms of nutrition outcomes (Breisinger et al. 2018). The Ministry of Social Solidarity (MOSS) is also piloting an approach with the World Food Programme (WFP), MOHP, and the Ministry of Supply and Internal Trade (MOSIT) as part of the first 1,000 days program model in three governorates in Upper Egypt. The pilot is targeting Takaful ben- eficiaries, including pregnant women and children 0–24 months of age, for receipt of a food voucher for nutritious foods after they meet the conditionality that they receive regular nutrition services within the primary health care (PHC) units. However, the approach will have to be evaluated for impact in due course. Although there are four recognized pathways through which agriculture can positively affect nutritional status (Ruel and Alderman 2013) and the GoE is investing heavily in national agriculture production and logistics, these investments do not have explicit objectives for affecting nutrition outcomes in Egypt. A countrywide early childhood development (ECD) initiative was recently launched to reorganize, revamp, and scale up a comprehensive ECD program linked to the health system, spanning from motherhood to early Executive Summary | xix primary school. However, it is too early to determine whether it could have an impact on nutrition outcomes. In primary education, the focus is on school feeding. However, this aspect of the initiative is primarily aimed at encourag- ing enrollment and attendance at school and supporting learning by alleviating short-term hunger with, at best, modest effects on health and nutrition outcomes. Overall, the analysis of nutrition status reveals still high levels of malnutrition in Egypt among children under 5, adolescents, and women of reproductive age, in particular. Moreover, there is little evidence that any of these interventions and programs are currently contributing as effectively as they could be to the control of the most urgent problems of malnutrition: stunting, wasting, over- weight/obesity, and anemia and other forms of micronutrient deficiency. Meanwhile, there are some noticeable gaps in programming, particularly in interventions that could affect overweight and obesity. Based on the identified gaps in programming, the global evidence base on the key effective nutrition-specific interventions, the available evidence around nutrition-sensitive programs, and the availability of delivery platforms in Egypt, interventions and programs with the most impact and scale-up potential were identified in order to address malnutrition more comprehen- sively in Egypt. The 16 interventions selected based on these criteria are listed in table ES.1. TABLE ES.1  Sixteen interventions selected to address malnutrition in Egypt INTERVENTION DESCRIPTION TARGET POPULATION Infant and young child feeding (IYCF) and micronutrients Promotion and support of 1.  Communication of optimal breastfeeding practices Pregnant women and mothers ­breastfeeding of children 0-6 months 2. Promotion of complementary feeding Communication of complementary feeding practices Mothers of children (excluding provision of food) 6–23 months Growth monitoring and promotion 3.  Systematic strengthening of GMP guidelines and Children 0–59 months (GMP) operational procedures, training, and scale-up 4. Iron supplementation Weekly supplementation with iron drops for three Children 6–59 months months, followed by three months of no supplementa- tion and repeated until child is 5 years old 5. Vitamin A supplementation Biannual supplementation of vitamin A capsules Children 6–59 months Curative interventions (MAM/SAM) Treatment of moderate acute 6.  Treatment of MAM in supplementary feeding programs Children 6–59 months ­malnutrition (MAM) Management of severe acute 7.  Severely malnourished children admitted in either Children 6–59 months ­malnutrition (SAM) inpatient or outpatient therapeutic feeding programs Disease prevention and management 8. Treatment of diarrhea (ORS) Management of mild and moderate diarrhea with oral Children 6–59 months rehydration solution (ORS) 9. Therapeutic zinc supplementation As part of diarrhea management with ORS Children 6–59 months 10. Deworming Annual or biannual single-dose albendazole (400 Children 12–59 months milligrams) or mebendazole (500 milligrams) to reduce the worm burden of soil-transmitted helminth infection continued xx | Scaling Up Nutrition in the Arab Republic of Egypt TABLE ES.1,  continued INTERVENTION DESCRIPTION TARGET POPULATION Maternal nutrition 11. Iron–folic acid supplementation Three months supplementation of iron–folic acid Pregnant women during pregnancy Water, sanitation, and hygiene (WASH) 12. Use of improved water source Regulation and advocacy activities to ensure access to All households water supply services from an “improved” source within 1 kilometer of the user’s dwelling. An “improved” source is one that is likely to provide “safe” water. 13. Use of water connection in home Regulation and advocacy activities to ensure access to All households safe water from a household connection Improved excreta disposal 14.  Promotional activities to ensure access to improved/ All households (latrine/toilet) hygienic excreta disposal (access to improved latrine or flush toilet) 15. Hand washing with soap Promotional activities for “appropriate” hand washing All households behavior 16. Hygienic disposal of children’s stools Promotional activities for the proper disposal of All households children’s stools Successful scaling up of these identified nutrition interventions in Egypt will require careful sequencing and selection of implementation approaches. It will be important to both demonstrate confidence-boosting early achievements and simultaneously build a foundation for sustained nutrition interventions reach- ing all vulnerable groups. Three potential scale-up scenarios were identified: (1) scale up all 16 interventions to full national coverage; (2) prioritize all 16 inter- ventions only in the governorates with the highest burden of stunting; and (3) scale up to full national coverage the most cost-effective interventions for stunting reduction out of the 16. Because the majority of the nutrition interventions proposed are delivered through the health system, strengthening this system is fundamental to the success of any nutrition scale-up plan. Key platforms for delivering nutrition-­ ­ relevant interventions include antenatal care, well-baby clinic visits, communi- ty-based nutrition programs, and child health days. The GoE has already taken steps in this direction by initiating an operational trial to test the provision of an integrated “best practice” package of nutrition services under the primary health care (PHC) system in two districts in Lower Egypt in 2017. It includes a fully revised Standardized Protocol of Action for Nutrition Services (SPANS) within the first 1,000 days, aiming to address weaknesses in the demand side, supply side, and enabling environment for stunting prevention. The trial is intended to continue for a total cycle of five years, paying particular attention to cost and impact and a discussion of results as the trial proceeds. Egypt is also set to undergo broader health care system reform and health sector restructuring. Both are expected to improve public health care service dramatically in terms of quality and equity. Furthermore, in the scaling-up process the GoE must assume effective lead- ership, while recognizing that effective internal coordination and linkages (among government sectors, administrative levels, and agencies) as well as external cooperation (with development partners, civil society organizations, and the private sector) will be critical for success. Executive Summary | xxi Cost-effectiveness of potential scale-up scenarios Although Egypt is a lower-middle-income country, the cost of scaling up even a limited number of high-impact nutrition interventions to improve nutri- tion outcomes may be prohibitive. However, the potential economic benefits from scaling up key interventions could far outweigh the costs of implemen- tation. With that in mind, an economic analysis was carried out to help policy makers understand the potential benefits of scaling up key interventions and to identify and prioritize the most cost-effective package of interventions. This analysis was conducted by combining costs with estimates of impact to identify the most significant and cost-effective combinations of interven- tions in the Egyptian context based on the three scale-up scenarios just outlined. Of the 16 interventions singled out as having the greatest potential to be scaled up and a positive effect on malnutrition (particularly stunting) in the Egyptian context, 13 could be modeled using the Lives Saved Tool (LiST). LiST estimates the global health impacts of scaling up key interventions by modeling outcomes around health and nutrition outcomes, among others. The modeled interven- tions included IYCF (promotion of breastfeeding and complementary feeding), micronutrients (IFA for pregnant women and vitamin A for children), MAM/ SAM treatment, treatment of diarrhea (oral rehydration solution and zinc), and five WASH interventions. Analysis of the three scale-up scenarios revealed that, to prevent stunting of the highest number children, Egypt should prioritize funding the most cost-­ effective interventions that achieve the same result as full coverage: IYCF (­ especially promotion of appropriate breastfeeding and complemen- tary ­feeding), IFA supplementation, vitamin A supplementation for children, and promoting hygienic disposal of children’s stools—all resulting in 421,360 cases of stunting prevented. When comparing the costs and benefits of delivering only the most cost-effective interventions in stunting reduction ­ to the other two scenarios, this scenario provides better value for money: the cost per death prevented is $19,412; the cost per stunting case prevented is $196. Prioritizing implementation of the most cost-effective interventions for stunting reduction is also estimated to translate into and return the highest economic benefits over the productive lives of children who receive the inter- ­ ventions (a return of $17.87 in economic benefits for each dollar invested). However, this approach comes at a cost: by not implementing the treatment of acute malnutrition (MAM/SAM), it will not have any impact on the current ­levels of wasting and will prevent only 4,249 additional deaths (30 percent of the full national coverage scenario). Maintaining the supplementation of oral rehy- dration solution (ORS) and zinc for the treatment of diarrhea at current coverage levels means that further potential gains in combating malnutrition will not be realized. This scenario is also estimated to translate into and return the highest economic benefits over the productive lives of the children who receive the interventions. The estimated benefit-cost ratio for implementing this sce- nario in Egypt, 17.87, suggests that every dollar invested would result in about $18 in economic returns and $1,326 million in productivity gains, indicating that the benefits of investing in nutrition significantly outweigh the costs. xxii | Scaling Up Nutrition in the Arab Republic of Egypt Fiscal space to scale up nutrition Identification of funding options is critical to ensuring that one or more of the scale-up scenarios can be implemented to improve nutrition outcomes. Thus an analysis of the existing and projected fiscal space was carried out to understand whether it is conducive to absorbing the additional costs of implementing the scale-up scenarios. The analysis found that improved macroeconomic conditions in the long run as well as medium-run efficiency gains are two areas with good prospects of generating significant additional resources for nutrition. Other potential sources offer more limited opportunities. These include (1) higher funding through the health budget but limited by competing priorities for finite resources and highly centralized decision making; (2) raising further funds in the health sector through, for example, earmarked taxes for health (or nutrition), and yet difficul- ties arise from the evolving and multisectoral nature of nutrition and the poten- tial negative impacts of such taxes; and (3) foreign assistance, but Egypt is not reliant on external funding for nutrition. In the long run, it is reasonable to expect significant economic growth from the increased productivity of Egypt’s workforce arising from the reduction in stunting. Lower levels of stunting and the resulting improved health will also reduce reli- ance on social programs and cut stunting-related health costs. Aside from eco- nomic growth, the government’s revenue could also increase if tax revenue grows through an expanded tax base, new taxes, or more efficient tax collection. Allocative and operational efficiency gains can be obtained in the medium run by focusing on delivery of the most cost-effective interventions in stunting reduction: IYCF (especially complementary feeding), IFA supplementation for pregnant women, iron and vitamin A supplementation for children, and promo- tion of hygienic disposal of children’s stools. These interventions are also those that can be scaled up quickly either with existing capacity or with relatively small investments. This strategy is expected to translate into substantial eco- nomic benefits and return the highest economic benefits over the productive lives of the children who receive the interventions. REFERENCES Bhutta, Z. A., J. K. Das, A. Rizvi, M. F. Gaffey, N. Walker, S. Horton, P. Webb, A. Lartey, and R. E. Black. 2013. “Evidence-Based Interventions for Improvement of Maternal and Child Nutrition: What Can Be Done and at What Cost?” Lancet 382 (9890): 452–77. Black, R. E., C. G. Victora, S. P. Walker, Z. A. Bhutta, P. Christian, M. de Onis, M. Ezzati, S. Grantham-McGregor, J. Katz, R. Martorell, and R. Uauy. 2013. “Maternal and Child Undernutrition and Overweight in Low-Income and Middle-Income Countries.” Lancet 382 (9890): 427–51. doi:10.1016/S0140-6736(13)60937-X. Breisinger, C., P. Al-Riffai, O. Ecker, R. Abuismail, J. Waite, N. Abdelwahab, A. Zohery, H. El-Laithy, and D. Armanious. 2013. “Tackling Egypt’s Rising Food Insecurity in a Time of Transition.” Joint IFPRI-WFP Country Policy Note. IFPRI andWFP, Washington, DC, and Rome. Breisinger, C., D. Gilligan, N. Karachiwalla, S. Kurdi, H. El-Enbaby, A. H. Jilani, and G. Thai. 2018. “Impact Evaluation Study for Egypt’s Takaful and Karama Cash Transfer Program: Part 1: Quantitative Report.” MENA RP Working Paper 14. International Food Policy Research Institute (IFPRI), Washington, DC, and Cairo, Egypt. http://ebrary.ifpri.org/cdm​ /ref/collection/p15738coll2/id/132719. Executive Summary | xxiii Horton, S., M. Shekar, C. McDonald, A. Mahal, and J. K. Brooks. 2010. Scaling up Nutrition: What Will It Cost? Washington, DC: World Bank. doi:10.1596/978-0-8213-8077-2. IDSC (Egyptian Cabinet Information and Decision Support Center). 2014. The Cost of Hunger in Egypt: Implications of Child Undernutrition on the Social and Economic Development of Egypt. Cairo. MOHP (Ministry of Health and Population). 2012. Egypt Nutrition Landscape Analysis Report 2012. Government of Egypt, Cairo. MOHP (Ministry of Health and Population), NNI (National Nutrition Institute), and UNICEF (United Nations Children’s Fund). 2017. Nutrition Agenda for Action: A Policy Paper on Scaling Up Nutrition Interventions in Egypt. Cairo: UNICEF. https://www.unicef.org/egypt​ /reports/nutrition-agenda-action-cairo-2017. MOHP (Ministry of Health and Population) and UNICEF (United Nations Children’s Fund). 2017. Nutrition Stakeholder and Action Mapping Report. Cairo: UNICEF. https://www​ .unnetworkforsun.org/sites/default/files/2018-08/Nutrition%20Stakeholder%20%26%20 Action%20Mapping%20Report-Egypt.pdf. Ruel, M. T., and H. Alderman. 2013. “Nutrition-Sensitive Interventions and Programmes: How Can They Help to Accelerate Progress in Improving Maternal and Child Nutrition?” Lancet 382 (9891): 536–51. https://doi.org/10.1016/S0140-6736(13)60843-0. Victora, C. G., M. de Onis, P. C. Hallal, M. Blössner, and R. Shrimpton. 2010. “Worldwide Timing of Growth Faltering: Revisiting Implications for Interventions.” Pediatrics 125 (3): e473–e480. doi:10.1542/peds.2009-1519. WFP (World Food Programme). 2013. The Status of Poverty and Food Security in Egypt: Analysis and Policy Recommendations. Preliminary Summary Report, Cairo. WHO (World Health Organization). 2014. “Global Nutrition Targets 2025: Childhood Overweight Policy Brief.” WHO/NMH/NHD/14.6. Geneva. ———. 2017. “Global Targets 2025 Tracking Tool: Country Progress Report 2017—Egypt.” Geneva. https://extranet.who.int/sree/Reports?op=vs&path=%2FWHO_HQ_Reports/G16/PROD​ /­EXT/Targets_Menu&VSPARAM_varLanguage=E&VSPARAM_varISOCODE=ALB. Abbreviations ANC antenatal care BFHI Baby Friendly Hospital Initiative BMI body mass index CAPMAS Central Agency for Public Mobilization and Statistics CCT conditional cash transfer CHW community health worker CRS Creditor Reporting System CSO civil society organization DAC Development Assistance Committee DALY disability-adjusted life year DHS Demographic and Health Survey ECD early childhood development EDHS Egypt Demographic and Health Survey EU European Union FAO Food and Agriculture Organization of the United Nations FDI foreign direct investment GAIN Global Alliance for Improved Nutrition GDP gross domestic product GMP growth monitoring and promotion GoE Government of Egypt HCWW Holding Company for Water and Waste Water IFA iron–folic acid IFPRI International Food Policy Research Institute IMAM Integrated Management of Acute Malnutrition IMCI Integrated Management of Childhood Illness IYCF infant and young child feeding LBW low birthweight LE Egyptian pound LiST Lives Saved Tool MAM moderate acute malnutrition MCH maternal and child health MOALR Ministry of Agriculture and Land Reclamation MOE Ministry of Education  xxv xxvi | Scaling Up Nutrition in the Arab Republic of Egypt MOHP Ministry of Health and Population MOHUUC Ministry of Housing, Utilities and Urban Communities MOSIT Ministry of Supply and Internal Trade MOSS Ministry of Social Solidarity MOWRI Ministry of Water Resources and Irrigation NCD noncommunicable disease NFNPS National Food and Nutrition Policy and Strategy NGO nongovernmental organization NHA National Health Accounts NNI National Nutrition Institute NRSP National Rural Sanitation Program NSFP National School Feeding Program ODA official development assistance OECD Organisation for Economic Co-operation and Development ORS oral rehydration solution PER public expenditure review PHC primary health care SAM severe acute malnutrition SBCC social and behavior change communication SDG Sustainable Development Goal SHA System of Health Accounts SPANS Standardized Protocol of Action for Nutrition Services SUN Scaling Up Nutrition (movement) TGE total government expenditure TNE total nutrition expenditure UNICEF United Nations Children’s Fund USAID U.S. Agency for International Development USI universal salt iodization WASH water, sanitation, and hygiene WFP World Food Programme WHA World Health Assembly WHO World Health Organization In this report, all dollar amounts are U.S. dollars, unless otherwise indicated. Background Since 1990, the Arab Republic of Egypt has achieved significant improvements in key health indicators, with maternal mortality falling from 106 to 33 deaths per 100,000 live births and infant mortality falling from 63 to 20 deaths per 1,000 births (World Bank 2015). Significant regional and urban/rural disparities per- sist, however, and more recent data suggest the rate of progress on these indica- tors is slowing. Life expectancy, though rising from 66 to 71 years over this period, remains below the Middle East and North Africa average of 73 years. However, during the same period Egypt has not made the same progress in reducing malnutrition, and it has been identified as one of 36 countries in which 90 percent of the global burden of malnutrition falls (Horton et al. 2010). Egypt also faces the challenge of dealing with the double burden of malnutri- tion, with overweight and obesity rising, while stunting in children under 5 remains of high public health significance, and wasting has risen since 2005 from a low to a medium level of public health significance. Children who are overweight or obese are at a higher risk of developing serious health prob- lems, including type 2 diabetes, high blood pressure, and liver disease (WHO 2014). At the same time, over one-third of child deaths in Egypt are caused by undernutrition, mostly from the greater severity of the disease. Globally, a large number of studies have confirmed the adverse impacts of malnutrition (under- nutrition and overweight) on quality of life and life expectancy (Zheng et al. 2014). In 2014, Egypt ranked 59th out of 89 low- and middle-income countries in relation to the severity of nutrition indicators (Webb 2014), and it presently is not on track to meet the majority of the six nutrition targets established by the World Health Assembly in 2012 (WHO 2017). Malnutrition is also a huge burden on Egypt’s economy. According to the study The Cost of Hunger in Egypt (IDSC 2014), undernutrition, as is mani- fested by poor linear growth (stunting), wasting and micronutrient deficien- cies in children, and anemia among adult women, is sapping an estimated 1.98 ­percent of Egypt’s annual gross domestic product (GDP) through produc- tivity foregone and costs to the health system, representing an economic hem- orrhage of about $3.6 billion a year (reference year 2009). The study concludes that long-term sustainable development cannot happen without effectively combating undernutrition and eliminating childhood stunting, designating them key elements of the social development agenda.  1 2 | Scaling Up Nutrition in the Arab Republic of Egypt The government of Egypt (GoE) has shown a strong political commitment to assessing and addressing malnutrition in Egypt. A nutrition landscape analysis, the first in Arab countries, was carried out by Egypt’s Ministry of Health and Population (MOHP) and the United Nations Children’s Fund (UNICEF) in 2011 to comple- ment the country’s 10-year National Food and Nutrition Policy and Strategy 2007– 2017 (NFNPS). The landscape analysis described the extent of the malnutrition problem (including rising obesity rates) in Egypt, provided possible solutions to optimize outcomes with the available resources, and set out clear immediate, medium-term, and long-term recommendations to guide investments until 2017 (MOHP 2012). More recently, the MOHP, in close collaboration with UNICEF, developed a Nutrition Agenda for Action (MOHP, NNI, and UNICEF 2017) and Nutrition Stakeholder and Action Mapping Report (MOHP and UNICEF 2017). Both of these reports have helped to build momentum toward updating the National Food and Nutrition Policy and Strategy and developing an action plan (2018–25) as well as increasing Egypt’s commitment to nutrition. STUDY OBJECTIVE AND RATIONALE This report was developed at the request of the government of Egypt and in close collaboration with UNICEF. It is intended to help inform the development of an updated national food and nutrition policy and strategy and to guide nutrition investments over the next five years. The report provides an updated overview of Egypt’s nutrition situation, the programs currently in place, and opportunities to scale up the response to alleviate the burden of malnutrition. Beyond an assessment of the prevalence of overnutrition, the emphasis of the report is on undernutrition throughout. The specific aims are the following: • Document the magnitude and severity of malnutrition in Egypt, including overweight and obesity, and country-specific key determinants. The last com- prehensive assessment was the landscape analysis carried out in 2011. • Provide an overview of the current nutrition-specific and nutrition-sensitive programs in Egypt; map the coverage of various donor and government pro- grams; and document gaps in the scope, coverage, and financing of these programs. • Identify for the government and the development partner community poten- tial nutrition-specific and nutrition-sensitive policy options for scaling up programs and interventions and strengthening the overall response to address undernutrition in the country. • Provide estimates and the costs and benefits of a select number of highly effec- tive interventions and policy scenarios to address undernutrition. • Analyze the fiscal space required to implement nutrition interventions at scale. METHODS AND ANALYTICAL APPROACH This report documents the current state of the nutrition landscape using recent data from a variety of sources, including: • Demographic and nutrition epidemiology data from existing surveys • Network assessment of key stakeholders in nutrition in Egypt Background | 3 • Review of legal, strategy, policy, and guideline documents from the relevant ministries and agencies in the health and nonhealth sectors • Review of gray and published literature, as well as program and evaluation reports in the health and nonhealth sectors from the GoE and nongovern- ment agencies. Primary quantitative data were not collected as a part of the assessment, and the report does not serve as an evaluation of the impact and effectiveness of pro- grams. It draws on extant data and sources to synthesize and analyze the nutri- tion situation, policies, and programs to identify promising areas for further consideration. STRUCTURE OF THE REPORT The remainder of this report is organized into five chapters. Chapters 1 and 2 analyze, respectively, the undernutrition and overnutrition status and determinants among children under 5 and women of reproductive age in Egypt. Chapter 3 is an overview of nutrition-specific and nutrition-­sensitive programs, the existing gaps, and the opportunities to scale up such ­interventions. Chapter 4 calculates the cost-effectiveness of the scale-up of different policy scenarios, and chapter 5 assesses the fiscal space needed to scale up. Appendix A then p ­ resents the statistical methods used for the determinants of malnutrition among Egyptian children, and appendix B reports the distribution of the sample by key characteristics and regression analysis results. Although chapter 2 highlights the growing overnutrition challenge in Egypt, the emphasis of all other chapters is on undernutrition. While not within the scope of this report, future research to help identify the high impact and cost effective solutions needed to address the growing overweight and obesity crisis in Egypt is critical. REFERENCES Horton, S., M. Shekar, C. McDonald, A. Mahal, and J. K. Brooks. 2010. Scaling up Nutrition: What Will It Cost? Washington, DC: World Bank. doi:10.1596/978-0-8213-8077-2. IDSC (Egyptian Cabinet Information and Decision Support Center). 2014. The Cost of Hunger in Egypt: Implications of Child Undernutrition on the Social and Economic Development of Egypt. Cairo. MOHP (Ministry of Health and Population). 2012. Egypt Nutrition Landscape Analysis Report 2012. Government of Egypt, Cairo. MOHP (Ministry of Health and Population), NNI (National Nutrition Institute), and UNICEF (United Nations Children’s Fund). 2017. Nutrition Agenda for Action: A Policy Paper on Scaling Up Nutrition Interventions in Egypt. Cairo: UNICEF. https://www.unicef.org/egypt​ /reports/nutrition-agenda-action-cairo-2017. MOHP (Ministry of Health and Population) and UNICEF (United Nations Children’s Fund). 2017. Nutrition Stakeholder and Action Mapping Report. Cairo: UNICEF. https://www.unicef​ .org/egypt/reports/nutrition-stakeholder-and-action-mapping-report-cairo-2017. Webb, P. 2014. “Nutrition and the Post-2015 Sustainable Development Goals.” A Policy Brief, Geneva, UNSCN Secretariat. 4 | Scaling Up Nutrition in the Arab Republic of Egypt WHO (World Health Organization). 2014. “Global Nutrition Targets 2025: Childhood Overweight Policy Brief.” WHO/NMH/NHD/14.6. Geneva. ————. 2017. “Global Targets 2025 Tracking Tool: Country Progress Report 2017—Egypt.” Geneva. https://extranet.who.int/sree/Reports?op=vs&path=%2FWHO_HQ_Reports/G16/PROD​ /EXT/Targets_Menu&VSPARAM_varLanguage=E&VSPARAM_varISOCODE=ALB. World Bank. 2015. World Bank Open Data (database): Egypt (2015). Washington, DC. https://data​ .worldbank​.org/country/egypt-arab-rep. Zheng, X. Y., Y. L. Han, C. Guo, L. Zhang, Y. Qin, and G. Chen. 2014. “Progress in Research of Nutrition and Life Expectancy.” Biomedical and Environmental Sciences 27 (3): 155–61. https://pdfs.semanticscholar.org/26e8/ebd94de643a5e737ffccb21a3d3191f906be.pdf. 1 Undernutrition of Children Under 5 and Women of Reproductive Age in Egypt JONATHAN KWEKU AKUOKU KEY MESSAGES • Stunting remains at a high level of public health significance in Egypt and the country continues to have higher prevalence of stunting than many of its regional counterparts. – Although there are fewer discernible differences in the levels across wealth quintiles, the diminished disparity has been due in part to a greater down- ward trend among children in the poorest wealth quintile and in part to a significant upward trend among children in the richest wealth quintiles. –– A general downward trend across regions was evident in earlier years, but prevalence has sharply increased in urban Upper Egypt in more recent years. –– The declining trend is significant for both boys and girls, as well as in rural but not urban areas. –– Key determinants of stunting include being a boy, maternal education, size at birth, urban residence, and residence in urban Upper Egypt. • Wasting has increased significantly since 2000, and the rising trend is consid- erably higher for the frontier governorates (versus the urban governorates) and among girls. –– The upward trend in wasting prevalence is also significant across urban and rural areas. –– Similarly, there is an upward trend across all wealth quintiles. –– Key determinants of wasting include residence in the frontier governor- ates, younger age, birth order, and maternal body mass index (BMI) • Although recent data on micronutrient status and deficiency are limited, the data available indicate high levels of anemia among children, adolescents, and women and falling consumption of iron- and vitamin A–rich foods among children under 5. INTRODUCTION This chapter describes undernutrition among children under 5 and women of reproductive age in Egypt. The chapter utilizes data from the 1992, 1995, 2000, 2005, 2008, and 2014 rounds of the Egypt Demographic and Health Survey (EDHS) (El-Zanaty et al. 1993, 1996; El-Zanaty and Way 2001, 2006, 2009;  5 6 | Scaling Up Nutrition in the Arab Republic of Egypt MOHP, El-Zanaty and Associates, and ICF International 2015), as well as data from other literature and databases. The chapter begins by presenting the methodology used to develop this over- view of the nutrition situation among children under 5 and women of reproduc- tive age in Egypt. It then examines the current prevalence and historical trends of and risk factors for stunting and wasting. The final section summarizes the findings. METHODOLOGY Understanding the determinants of malnutrition The Conceptual Framework for the Determinants of Malnutrition, developed by the United Nations Children’s Fund (UNICEF) and its partners is a multilevel, multisectoral framework for understanding the causes and consequences of maternal and child malnutrition (UNICEF 1990, 2013). In doing so, it identifies three levels of causes of malnutrition: immediate, underlying, and basic (figure 1.1). FIGURE 1.1 UNICEF conceptual framework for the determinants of malnutrition Intergenerational consequences Long-term consequences: Short-term consequences: Adult height, cognitive ability, Mortality, economic productivity, reproductive morbidity, performance, overweight and disability obesity, metabolic and cardiovascular diseases Maternal and child undernutrition Immediate Inadequate dietary Diseases causes intake Unhealthy household Underlying Household food Inadequate care and environment and causes security feeding practices inadequate health services Household access to adequate quantity and quality of resources: land, education, employment, income, and technology Basic Inadequate financial, human, physical, and social capital causes Social, cultural, economic, and political context Source: UNICEF 2013 (CC by 3.0 Unported). Undernutrition of Children Under 5 and Women of Reproductive Age in Egypt | 7 The immediate causes of malnutrition refer to adequacy of diet, including breastfeeding, frequency of feeding, and dietary diversity, along with disease, especially infections, which are direct causes of stunting (see box 1.1). Diet ade- quacy and disease act synergistically in their effect on childhood stunting. Infections can affect growth by reducing appetite, impairing the absorption of nutrients, and forcing the immune system to reallocate nutrients from growth to fighting the infection, while inadequacy in food intake increases the risk, sever- ity, and prolonged morbidity of infections (Dewey and Mayers 2011). Diarrhea has a particularly strong dose–response relationship with increased likelihood of stunting (Checkley et al. 2008), and respiratory infections accompanied by fever are associated with increased risk of stunting (Dewey and Mayers 2011). The underlying causes of malnutrition affect the immediate causes of ­stunting. Appropriate breastfeeding and complementary feeding to improve the adequacy of a child’s diet are directly influenced by the availability of diverse foods in the household, caregivers’ knowledge of the appropriate feeding and care practices, and the application of this knowledge to feeding a child appro- priately. Likewise, disease incidence and severity are not only synergistic with feeding practices, but also affected by a hygienic household environment and access to and utilization of available health services (UNICEF 2015). Sociopolitical, economic, and cultural factors at the basic level affect the avail- ability and utilization of resources at the underlying level. Household wealth and income may influence access to nutritious foods, utilization of health ser- vices, and availability of improved household infrastructure, while education of caregivers may influence access to information on improved child caring and feeding practices. The basic causes of malnutrition include the extent of human and environ- mental resources, economic systems, and political and ideological factors at var- ious levels of society that affect financial, human, physical, and social capital as well as a household’s access to resources. Although determinants such as house- hold wealth and maternal education are important and were included in the BOX 1.1 Evidence of and recommendations on the increased nutritional needs of children In their first two years of life, children have greater 2016), the evidence on the association between exclu- nutrient needs for proper physical and cognitive sive breastfeeding and stunting among children under growth and development, and, more than adults, 6 months is inconclusive. However, there is also an they must consume foods with higher nutrient den- indirect pathway between breastfeeding and stunting sity (Dewey 2016). For children under 6 months, lack through reductions in the incidence of diarrhea. It is of exclusive breastfeeding is associated with recommended that children 6–24 months of age con- increased mortality and morbidity from infectious tinue breastfeeding and be frequently fed with diverse diseases such as diarrhea, pneumonia, and malaria. nutrient-rich complementary foods (Dewey 2016; Diarrhea is especially important because of its impact WHO 2008). Appropriate frequency and quantity of on the absorption of nutrients from food (Black et al. food provide a child with the caloric energy needed 2008). for this period of rapid growth, and a diet rich in nutri- Although some studies find that exclusive breast- ents such as zinc and vitamin A protects against the feeding may be a protective factor for children living incidence and severity of diarrhea and respiratory in environments with high rates of infection (Dewey infections (Black et al. 2013). 8 | Scaling Up Nutrition in the Arab Republic of Egypt analytic model, they are not an explicit focus of this analysis. Rather, the main goal is to inform the design of effective interventions that can be implemented in the short to medium term—that is, interventions that focus on the immediate and underlying causes of malnutrition. Data Data for the foregoing analyses are from the 2014 round of the EDHS (MOHP, El-Zanaty and Associates, and ICF International 2015). The EDHS utilized a multistage cluster sampling design, allowing representative and precise esti- mates of population and health indicators at the national level and in six major subnational groupings: urban governorates, urban Lower Egypt, rural Lower Egypt, urban Upper Egypt, rural Upper Egypt, and frontier governorates. Two of the frontier governorates comprising less than 1 percent of the national popula- tion, North Sinai and South Sinai, were excluded from data collection in EDHS 2014 (MOHP, El-Zanaty and Associates, and ICFInternational 2015) because of security concerns. The analysis described in this chapter is based on data from the women’s questionnaire of the EDHS. This questionnaire contains information on wom- en’s demographic and health characteristics, as well as on children’s health, nutrition, and care. The questionnaire is administered to all ever-married women 15–49 years of age resident in a household during the survey, and it includes height and weight measurements of resident children under 5 years. However, questions on feeding behavior are asked for children under 2 who reside with the mother. Therefore, the analytic sample is restricted to the youngest child of each woman 0–23 months of age. Methods The analysis uses the UNICEF conceptual framework of malnutrition and draws on data from the EDHS to undertake a regression analysis to identify the imme- diate, underlying, and basic determinants of malnutrition in Egypt. The key EDHS data analyzed at each level of the causes of malnutrition include the following: • Immediate causes: disease incidence (infectious diseases) • Underlying causes: feeding practices, care practices, household environment, health services, women’s empowerment • Basic causes: maternal education, household wealth. A more detailed explanation of the methodology used to understand the key determinants of malnutrition in Egypt is provided in appendix A. UNDERNUTRITION OF CHILDREN 0–59 MONTHS OF AGE Stunting Prevalence and trends Stunting in Egypt is of high public health significance, according to the World Health Organization (WHO) classification1—more than one in five children under 5 are stunted. The WHO Child Growth Standards define stunting in young children as having height or length more than two standard deviations below the median height of a child of the same age and sex (de Onis and Onyango 2008). Undernutrition of Children Under 5 and Women of Reproductive Age in Egypt | 9 Stunting is the result of multiple factors, from basic causes such as poverty and food insecurity to underlying and more immediate causes such as poor maternal health and nutrition during pregnancy, inadequate nutrition and health during the early years, and poor child care practices (de Onis, Blössner, and Borghi 2012). In the short term, stunting increases the risk of mortality and morbidity from diarrhea, pneumonia, and other childhood illnesses (Black et al. 2008, 2013). In the longer term, stunting may affect cognitive development, educa- tional attendance and attainment, and economic productivity (de Onis, Blössner, and Borghi 2012). Despite a small decline in prevalence since the early 1990s, the stunting prev- alence in Egypt remains higher than the regional average of 15.8 percent among Middle East and North Africa countries (figure 1.2) and one of the highest among those with recent data. Between 1992 and 2014, stunting declined from 30.6 ­percent to 21.5 percent (p < 0.001 for trend),2 but fluctuated and remained above the regional average during that period (figure 1.3). Stunting prevalence is significantly higher in Upper Egypt, especially in rural (p < 0.05) and urban (p < 0.001) Upper Egypt when compared with the urban governorates (figure 1.4). Since the early 1990s, stunting prevalence has steadily fallen in some regions. Across the regions, significant declining trends were experienced in the frontier governorates (p < 0.001), rural Upper Egypt (p < 0.001), and rural Lower Egypt (p < 0.001). The frontier governorates cover Sinai and the deserts that lie west and east of the Nile River and are home to less than 2 percent of the Egyptian population. The spike in stunting prevalence between 2005 and 2008 has been attributed to the reduced intake of animal protein in certain regions due to the outbreak of avian influenza. It affected the availability and cost of poultry and eggs and the incomes of certain households, and it created the perception that less nutritious substitutes were less likely to make children ill (Kavle, El-Zanaty, et al. 2015). FIGURE 1.2 Prevalence of stunting among children under 5: Middle East and North Africa economies, various years Yemen, Rep., 2013 Djibouti, 2012 Syrian Arab Republic, 2009 Iraq, 2011 Egypt, Arab Rep., 2014 21.5% Libya, 2007 Morocco, 2011 Oman, 2014 Algeria, 2012 Tunisia, 2012 Jordan, 2012 Middle East and North Africa average West Bank and Gaza, 2014 (15.8%) Kuwait, 2014 0 5 10 15 20 25 30 35 40 45 Stunting prevalence (%) Sources: Egypt: EDHS microdata 2014 (dataset), Ministry of Health and Population and ICF International, Cairo, Egypt, and Rockville, MA, https://dhsprogram.com/data/; other countries: World Development Indicators (database), World Bank, Washington, DC, https:// databank.worldbank.org/source/world-development-indicators. 10 | Scaling Up Nutrition in the Arab Republic of Egypt FIGURE 1.3 Trends in stunting prevalence among children under 5: Middle East and North Africa economies, 1990–2016 60 Stunting prevalence among children 50 40 0–59 months (%) 30.6 30 28.9 23.5 22.9 21.5 20 10 0 1990 1992 1995 2000 2005 2008 2010 2014 2016 Economy: Egypt, Arab Rep. Jordan Kuwait Middle East and North Africa average Morocco Oman Tunisia West Bank and Gaza Yemen, Rep. Sources: Egypt: EDHS microdata various years (dataset), ICF International, Rockville, MA, https://dhsprogram. com/data/; other countries: World Development Indicators (database), World Bank, Washington, DC, https:// databank.worldbank.org/source/world-development-indicators. FIGURE 1.4 Trends in stunting prevalence across regions: Egypt, 1992–2014 45 40 Stunting prevalence among children 0–59 months (%) 35 30 25 20 15 10 5 0 1992 1995 2000 2005 2008 2014 Region: Urban governorates Frontier governorates Rural Lower Egypt Urban Lower Egypt Rural Upper Egypt Urban Upper Egypt Source: EDHS microdata various years (dataset), ICF International, Rockville, MA, https://dhsprogram.com/data/. Stunting affects children from both poor and rich households, and the preva- lence among children from the wealthiest households has increased signifi- cantly. Although stunting is significantly lower among children from the third (p < 0.001) and fourth (p < 0.01) wealth quintile households when compared with those from the poorest households, stunting is not significantly lower among those in the wealthiest quintile (p = 0.66)—see figure 1.5. The gap in stunting prevalence between the poor and the rich has narrowed, driven in part by the Undernutrition of Children Under 5 and Women of Reproductive Age in Egypt | 11 FIGURE 1.5 Trends in stunting prevalence across wealth quintiles: Egypt, 1995–2014 50 Stunting prevalence among children 0–59 months (%) 40 30 20 10 0 1995 2000 2005 2008 2014 Wealth quintile: Poorest Second Third Fourth Richest Source: EDHS microdata various years (dataset), ICF International, Rockville, MA, https://dhsprogram.com/data/. FIGURE 1.6 Trends in stunting prevalence across urban and rural areas: Egypt, 1992–2014 40 Stunting prevalence among children 0–59 months (%) 30 20 10 0 1992 1995 2000 2005 2008 2014 Area of residence: Urban Rural Source: EDHS microdata various years (dataset), ICF International, Rockville, MA, https://dhsprogram.com/data/. increasing trend in prevalence among those from the wealthiest households (p  <  0.05). Between 2008 and 2014, stunting declined across all wealth quintiles. Stunting prevalence has been declining among children from rural areas figure 1.6). Although stunting prevalence has historically been higher among (­ children from rural households, these children have also experienced a more significant decline in stunting prevalence when compared with their urban counterparts (p < 0.001). Data from the most recent EDHS shows a higher prev- alence of stunting among urban children, although this difference is not statisti- cally significant (p < 0.1). In 2016 the rural population comprised 56.8 percent of Egypt’s total population.3 Boys are more likely to be stunted than girls. Stunting prevalence has been consistently higher among boys than girls, and it was significantly higher in 2014 (p < 0.001)—see figure 1.7. However, the stunting prevalence among both groups have declined significantly (p < 0.001). 12 | Scaling Up Nutrition in the Arab Republic of Egypt FIGURE 1.7 Trends in stunting prevalence by child’s sex: Egypt, 1992–2014 40 Stunting prevalence among children 0–59 months (%) 30 20 10 0 1992 1995 2000 2005 2008 2014 Child’s sex: Male Female Source: EDHS microdata various years (dataset), ICF International, Rockville, MA, https://dhsprogram.com/data/. Determinants of stunting among children 0–23 months of age Stunting is the result of a complex interaction of household, environmental, socio- economic, and cultural influences, captured in the UNICEF conceptual ­framework on malnutrition (figure 1.1). Using this framework and data from EDHS 2014, the study team undertook bivariate and multivariate regression analysis to examine the significant factors associated with stunting among Egyptian children.4 It first summarizes the distribution of select demographic characteristics across the analytic sample before summarizing results from the multivariate analysis. A more detailed explanation of the methodology used appears in appendix A. Demographic characteristics across the analytic sample and factors potentially associated with stunting Seventy percent of the sample is from rural households, there are slightly more boys than girls, and half the children in the sample are 1 year or older. Finally, more than half are first- or second-born, and one in six is considered small or very small at birth by his or her mother (see appendix B, table B.1). An alarming 75 percent of mothers are overweight or obese. About two out of three (66.3 percent) have completed secondary school or higher education, whereas 16 percent have no education. Nearly 90 percent delivered at a health facility during their last pregnancy, almost all (97.7 percent) had a postnatal checkup after their last delivery, and more than 80 percent attended four or more antenatal care visits during their most recent pregnancy. Women reported they are involved in decision making about household purchases (64 percent), visits to their family (72 percent), and their own health care (80 percent). A number of differences in characteristics are evident across urban and rural areas: • Rural Upper Egypt and the rural frontier governorates have the highest pro- portions of women with no education (30 percent and 36 percent, respec- tively), and consequently the lowest proportions of women who have completed secondary school or higher education. • Urban Upper Egypt has the highest proportion of women who are overweight or obese (80 percent). Undernutrition of Children Under 5 and Women of Reproductive Age in Egypt | 13 • Relative to the national level and other regions, the rural frontier governor- ates have a lower proportion of women who attended four or more antenatal care visits during their most recent pregnancy (64 percent versus 83 percent nationally and 85 percent in urban frontier governorates). • The rural frontier governorates also have the lowest proportion of women reporting being involved in decisions about their own health care (69 ­percent). In general, a lower proportion of women in the rural governorates reported being involved in decision making. • None of the households from the rural governorates is in the highest wealth quintile, while nearly all of the households in the urban governorates are in the top two wealth quintiles. • Although there is nearly universal coverage of piped water into dwellings, households in the frontier governorates are less likely to have access, with only 60 percent of households having access to piped water in the rural fron- tier governorates. Overall, the prevalence of breastfeeding is relatively high. However, the prevalence of early initiation and exclusive breastfeeding is much lower, partic- ularly in urban areas. Although the proportion of children 12–15 months of age who were still being breastfed ranges from 67 to 84 percent, low proportions of children were initially breastfed within one hour of birth (16 percent in urban governorates and 45 percent in rural frontier governorates) (figure 1.8). FIGURE 1.8 Breastfeeding practices, complementary feeding practices, and incidence of disease among children 0–23 months of age: Egypt 100 75 Percent 50 25 0 Continued breastfeeding Diarrhea Early breastfeeding Exclusive breastfeeding 100 75 Percent 50 25 0 Introduction Minimum dietary Minimum meal Respiratory complementary food diversity frequency infection Region: National Rural frontier governorates Rural Lower Egypt Rural Upper Egypt Urban frontier governorates Urban governorates Urban Lower Egypt Urban Upper Egypt Source: Reanalysis of EDHS microdata 2014 (dataset), Ministry of Health and Population and ICF International, Cairo, Egypt, and Rockville, MA, https://dhsprogram.com/data/. Note: = 95% confidence interval. 14 | Scaling Up Nutrition in the Arab Republic of Egypt The timely introduction of complementary foods is relatively high, but the proportion of children fed the minimum number of times and with a nutrition- ally diverse diet is generally very low (figure 1.8). Disease incidence among children is particularly high in rural Upper Egypt. In the rural frontier governorates, one in 10 children had an episode of diarrhea in the two weeks preceding the survey compared with one in four children in rural Upper Egypt. The incidence of potential respiratory infection is also lowest in the frontier governorates (5.4 percent for rural and 9.5 percent for urban) and ranges from 15 to 24 percent in the other regions. Results from the multivariate analysis examining significant factors associated with stunting Boys are more likely than girls to be stunted, and this relationship remains statis- tically significant after adjusting for other covariates. Boys had 47 percent higher odds than girls of being stunted in a model with all children 0–23 months of age, and 100 percent higher odds among children 0–6 months of age. This finding is consistent with those across other countries8 and previous findings in Egypt (Khatab 2010; Zottarelli, Sunil, and Rajaram 2007), as well as the trends from previous rounds of the EDHS (1992, 1995, 2000, 2005, 2008). Children of mothers with an incomplete secondary education (versus com- pleted secondary) have significantly higher odds of stunting (35 percent). In a recent review of the drivers of the decline in stunting across countries in Sub- Saharan Africa and South Asia, Headey, Hoddinott, and Park (2017) find strong positive associations between higher parental education and the height-for-age z-score. A multicountry study of the link between maternal education and child nutritional status also finds higher levels of maternal education to be protective against malnutrition, including stunting, noting that there is a threshold level of education at which this effect is significant (Makate and Makate 2017; Makoka 2013). Greater maternal education is thought to influence child health and nutri- tional status by empowering mothers to seek and appropriately utilize informa- tion, as well as to mobilize resources in the care of children (Caldwell 1979; Mosley and Chen 1984; Ruel et al. 1992). Among children under 6 months of age, those who were small or very small at birth have nearly double the odds of being stunted compared with those who were average weight at birth. Although birth size is based on mothers’ reports, previous studies have shown it to be a good predictor of outcomes related to birthweight, particularly in settings with poor quality of birthweight data (Haque, Tisha, and Huq 2015; Sreeramareddy, Shidhaye, and Sathiakumar 2011). Small birth size is linked to maternal nutrition before and during pregnancy (Black et al. 2013). Micronutrient deficiencies and a low body mass index not only increase the risk of maternal mortality and morbidity during pregnancy, but also affect fetal development and birth outcomes such as low birthweight, preterm births, and cognitive defects. Children from urban Upper Egypt (versus urban governorates) are at signifi- cantly higher odds of being stunted (75 percent). In a recent study examining the factors associated with stunting more generally in Upper and Lower Egypt, Kavle et al. (2014) find that cultural barriers and lack of knowledge of the causes of poor childhood growth play significant roles in how children are nourished. In Upper Egypt, children are not fed adequately with animal source foods and are often given tea, juices, and energy-dense food of poor nutritional quality, a Undernutrition of Children Under 5 and Women of Reproductive Age in Egypt | 15 situation due in part to government subsidies on sugar and oil (Kavle, Mehanna, et al. 2015). This situation is contributing to the increasing double burden of undernutrition and overnutrition in Egyptian children. Egyptian children from urban households are more likely to be stunted than children from rural households. This is contrary to findings from other countries and evidence from a large body of research indicating that children in rural areas are generally at greater risk for stunting than their urban counterparts (Menon, Ruel, and Morris 2000; Smith, Ruel, and Ndiaye 2005). The rationale is that urban areas have favorable endowments in the underlying determinants of stunting—that is, they are more likely to have access to improved water and ­ sanitation, have residents in the higher wealth quintiles, and have access to ­ ­better-quality health services. And yet the most recent national survey shows that children in urban areas are more likely to be stunted, and this analysis is stratified to examine the different factors associated with stunting across each area. The full regression results are presented in appendix B, tables B.2, B.3, and B.4. Figure 1.9 shows that among Egyptian children 0–23 months of age from rural households, similar factors as found earlier are associated with the odds of stunt- ing: being a boy, small size at birth, and lower maternal education are associated with a 40–50 percent higher odds of stunting, similar to the associations found for the whole sample. Early initiation of breastfeeding is even more protective for rural children than the national average (36 percent reduced odds versus 25 percent). For the rural sample of children 6–23 months of age, being large at birth and early initiation of breastfeeding significantly reduce the odds of stunt- ing (65 percent and 35 percent reductions, respectively). Beyond the increased odds of stunting in male infants, there are no other significant determinants of stunting among rural children under 6 months of age. FIGURE 1.9 Adjusted odds ratio for significant determinants of stunting among rural Egyptian children 0–23 months of age Early initiation of breastfeeding Small or very small at birth At least some primary education Variable Large or very large at birth Boy Incomplete secondary education 0 1 2 3 4 5 6 7 8 9 10 Odds ratio Age group: 0–23 months 0–5 months 6–23 months Source: EDHS microdata 2014 (dataset), Ministry of Health and Population and ICF International, Cairo, Egypt, and Rockville, MA, https://dhsprogram.com/data/. 16 | Scaling Up Nutrition in the Arab Republic of Egypt In urban children, large size at birth and child postnatal checkup appear to significantly reduce the odds of stunting among children under 6 months of age (95 percent and 79 percent odds reduction, respectively)—see figure 1.10. However, only 15 percent of urban children under 6 months of age had a postna- tal checkup, and mothers reported that less than 3 percent of urban children were large or very large at birth. Among children 0–6 months of age, increasing socioeconomic status is asso- ciated with higher odds of being stunted. However, this finding is in line with the fact that urban children are more likely to be stunted in Egypt and are more likely to reside in households in the higher wealth quintiles. This finding is statistically significant among children from households in the fourth wealth quintile, with their odds of stunting more than double that of those in the poorest wealth quintile. A comparison of the prevalence of some key determinants of stunting by household wealth quintile reveals that children in the higher wealth quintiles are more likely than those in lower quintiles to have been delivered in a health facility (96 percent versus 78 percent). In addition, they are more likely to have had a postnatal check after birth (17 percent versus 13 percent), are just as likely to have been exclusively breastfed and for their mother to have had a postnatal checkup, and are less likely to have had an incidence of diarrhea or symptoms of respiratory infection in the past two weeks (17 percent versus 25 percent and 13 percent versus 17 percent, respectively). Children in the higher wealth quin- tiles, however, are less likely to have been initiated on breastfeeding within one hour of birth, although a chi-squared test found no significant difference in early breastfeeding initiation (p = 0.101). This analysis shows, then, that other factors are likely at play among higher wealth quintiles in determining the increased odds of being stunted. FIGURE 1.10 Adjusted odds ratio for significant determinants of stunting among urban Egyptian children 0–23 months of age Large or very large at birth Variable Boy Child received postnatal checkup 0 1 2 3 4 Odds ratio Age group: 0–23 months 0–5 months 6–23 months Source: EDHS microdata 2014 (dataset), Ministry of Health and Population and ICF International, Cairo, Egypt, and Rockville, MA, https://dhsprogram.com/data/. Undernutrition of Children Under 5 and Women of Reproductive Age in Egypt | 17 Wasting Prevalence and trends Almost one in 10 children under 5 in Egypt is wasted, which is substantially higher than the regional average (figure 1.11) and of medium public health signif- icance, according to the WHO classification.5 Childhood wasting6 is symptom- atic of acute malnutrition caused by insufficient consumption of foods or frequent episodes of infectious diseases such as diarrhea. These causes can act synergistically, with inadequate food consumption increasing the severity of dis- eases, while severe and multiple episodes of infectious diseases may decrease the absorption of nutrients from food. Wasting among children under 5 has increased steadily since 2000. As shown in figure 1.12, each round of the EDHS since 2000 has shown a consis- tent increase in wasting among Egyptian children (p < 0.001 for trend), and this upward trend is present across several demographic categories. It increased from 3.8 percent in 1992 to 8.5 percent in 2014, and if the trend continues it could soon become of high public health significance, according to the WHO classification. The prevalence of wasting has increased across all regions in Egypt since 2000, with the frontier governorates having a significantly higher increasing trend when compared with the urban governorates (p < 0.05 for interaction between year and region). However, there was no statistically significant differ- ence in wasting prevalence across the regions in 2014 (figure 1.13). Wasting prevalence has increased for children from both rich and poor households. Across wealth quintiles, wasting prevalence increased significantly as of 2000 ( p < 0.001 for trend in each wealth quintile), although there is no significant difference in the increasing trend across the quintiles and no signifi- cant difference in prevalence in 2014 (figure 1.14). The prevalence of wasting has increased for children in both urban and rural areas. Over the study period, wasting increased among both urban (p < 0.001) FIGURE 1.11 Prevalence of wasting among children under 5: Middle East and North Africa economies, various years Djibouti, 2012 Yemen, Rep., 2013 Syrian Arab Republic, 2009 Egypt, Arab Rep., 2014 8.5% Oman, 2014 Iraq, 2011 Libya, 2007 Algeria, 2012 Tunisia, 2012 Kuwait, 2014 Jordan, 2012 Middle East and North Africa average Morocco, 2011 (7.4%) West Bank and Gaza, 2014 0 5 10 15 20 Wasting prevalence (%) Sources: Egypt: EDHS microdata 2014 (dataset), Ministry of Health and Population and ICF International, Cairo, Egypt, and Rockville, MA, https://dhsprogram.com/data/; other countries: World Development Indicators (database), World Bank, Washington, DC, https:// databank.worldbank.org/source/world-development-indicators. 18 | Scaling Up Nutrition in the Arab Republic of Egypt FIGURE 1.12 Trends in wasting prevalence: Middle East and North Africa economies, 1990–2014 30 25 Wasting prevalence among children 0–59 months (%) 20 15 10 8.5 5.7 7.3 3.8 4.8 5 3.0 0 1990 1992 1995 2000 2005 2008 2010 2014 Economy: Egypt, Arab Rep. Jordan Kuwait Middle East and North Africa average Morocco Oman Tunisia West Bank and Gaza Yemen, Rep. Source: Egypt: EDHS microdata various years (dataset), ICF International, Rockville, MA, https://dhsprogram.com/ data/; other countries: World Development Indicators (database), World Bank, Washington, DC, https://databank. worldbank.org/source/world-development-indicators. FIGURE 1.13 Trends in wasting prevalence across regions: Egypt, 1992–2014 30 Wasting prevalence among children 0–59 months (%) 25 20 15 10 5 0 1992 1995 2000 2005 2008 2014 Region: Urban governorates Frontier governorates Rural Lower Egypt Urban Lower Egypt Rural Upper Egypt Urban Upper Egypt Source: EDHS microdata various years (dataset), ICF International, Rockville, MA, https://dhsprogram.com/data/. and rural (p < 0.001) children, with no significant difference in trend and no sig- nificant difference in prevalence in 2014 (figure 1.15). Since 2000, there have been significant increasing trends in wasting for both boys and girls, with a significant difference between them in trends (p < 0.05 for interaction between year and child’s sex) but no difference in prevalence in 2014 (figure 1.16). Determinants of wasting among children 0–59 months of age Using the UNICEF framework and a set of covariates with significant bivariate associations with wasting, the study team found several factors significantly associated with the odds of wasting in a multivariate model. Undernutrition of Children Under 5 and Women of Reproductive Age in Egypt | 19 FIGURE 1.14 Trends in wasting prevalence across wealth quintiles: Egypt, 1995–2014 10 Wasting prevalence among children 0–59 months (%) 8 6 4 2 0 1995 2000 2005 2008 2014 Wealth quintile: Poorest Second Third Fourth Richest Source: EDHS microdata various years (dataset), ICF International, Rockville, MA, https://dhsprogram.com/data/. FIGURE 1.15 Trends in wasting prevalence across urban and rural areas: Egypt, 1992–2014 10 Wasting prevalence among children 0–59 months (%) 8 6 4 2 0 1992 1995 2000 2005 2008 2014 Area of residence: Urban Rural Source: EDHS microdata various years (dataset), ICF International, Rockville, MA, https://dhsprogram.com/data/. FIGURE 1.16 Trends in wasting prevalence by child’s sex: Egypt, 1992–2014 10 Wasting prevalence among children 0–59 months (%) 8 6 4 2 0 1992 1995 2000 2005 2008 2014 Child’s sex: Male Female Source: EDHS microdata various years (dataset), ICF International, Rockville, MA, https://dhsprogram.com/data/. 20 | Scaling Up Nutrition in the Arab Republic of Egypt Children in the frontier governorates have increased odds of wasting. After adjustments are made for multiple factors, children from frontier governorates have 72 percent higher odds of wasting when compared with children from urban governorates. The association is not significant in other regions. In the multivariate model, younger children have increased odds of wasting. Compared with children 24–59 months of age, children under 6 months of age have 94 percent (p < 0.001) higher odds of being wasted, whereas children 12–23 months of age have 26 percent (p < 0.01) higher odds of being wasted. This finding is consistent with evidence from studies in other countries showing that younger infants are more vulnerable to wasting (Akombi et al. 2017; Harding, Aguayo, and Webb 2018). Higher birth order is associated with increased odds of wasting. Children who are fourth or higher birth order have 31 percent (p < 0.01) higher odds of wasting. This finding is consistent with prior evidence that lower birth order ­ children have better nutritional status (Horton 1988). Furthermore, because higher birth order children would be of younger age, this finding is also consis- tent with the negative association between age and the odds of wasting reported earlier. Mother’s BMI status and health decision-making power are significantly associated with the odds of child wasting. In the multivariate-adjusted model, children whose mothers are overweight or obese have 20 percent lower odds of wasting (p < 0.05), and those whose mothers participate in decisions about their own health care have 25 percent lower odds of wasting (p < 0.01). The association between maternal BMI and child wasting has been documented in previous studies (such as Rahman, Chowdhury, and Hossain 2009), and it may stem from the fact that these children likely live in households with greater food security. Measures of women’s empowerment have been associated with improved child nutritional status, although this is dependent on how this con- cept is operationalized (Carlson, Kordas, and Murray-Kolb 2015; Cunningham et al. 2015). Micronutrient status among children 6–59 months of age Vitamin A In EDHS 2014, 16.7 percent of children 6–59 months of age were reported to have had a vitamin A supplement in the six months preceding the survey, com- pared with 12.4 percent in 2008.7 As further explained and discussed in ­chapter 3, this low figure may be a result of only providing vitamin A capsule (VAC) supple- mentation in conjunction with the immunization visits at 9 and 18 months. Adequate levels of vitamin A in children help to boost immune function and reduce morbidity and mortality from infectious diseases such as measles and diarrhea, as well as prevent blindness and other vision impairments (Black et al. 2008; Imdad et al. 2010). Infants and young children require higher levels of vitamin A to sustain rapid growth (WHO 2011). With evidence that a single large dose of vitamin A can be absorbed and utilized as needed for a period of four to six months, WHO recommends that children be given a vitamin A supplement once every six months, particularly in settings where vitamin A deficiency is a public health problem (WHO 2011).8 This is especially important for children who may lack access to vitamin A–rich foods such as meat, eggs, fruits, and veg- etables. The most recent survey on vitamin A deficiency dates back to 1999 (Stevens et al. 2015; Wirth et al. 2017). Undernutrition of Children Under 5 and Women of Reproductive Age in Egypt | 21 Whereas there is generally no difference in boys and girls, more children from richer households receive vitamin A supplements than children from poorer households. Boys and girls are just as likely to receive vitamin A supplements (16.7 percent and 16.8 percent, respectively), whereas more chil- ­ dren in the richest wealth quintile receive the supplements, compared with those in the poorest (19.6 percent versus 14.5 percent). A greater proportion of children in urban Lower Egypt receive supplementation (20.2 percent), whereas the lowest proportion of children in the frontier governorates receive supplementation. Consumption of vitamin A–rich foods by children is fairly low, particularly in Upper Egypt. Diet is one key pathway for children to maintain adequate levels of micronutrients, including vitamin A. In EDHS 2014, 61 percent of children 6–23 months of age were reported to have consumed foods rich in vitamin A the day preceding the survey, compared with 71 percent in 2008. Consumption of vitamin A–rich foods in 2014 was highest among children from the frontier gov- ernorates (73 percent) and rural Lower Egypt (64.4 percent), and lowest among those from rural and urban Upper Egypt (57.5 percent). Iron and iron-deficiency anemia In 2014 almost one-third of children in Egypt were anemic, an improvement since 2008 but still detrimentally high. As shown in figure 1.17, among children 6–59 months of age the prevalence of any anemia significantly increased between 2000 and 2005, from 30 to nearly 50 percent, before declining to 27 percent in 2014 (p < 0.001 for declining trend), which, according to the WHO classifica- tion, is a moderate public health problem.9 The prevalence of moderate anemia was 9.6 percent and mild anemia was 17 percent. Iron deficiency has been identified as a major cause of anemia in young children. It can be caused by inadequate dietary intake of iron-rich foods and ­ FIGURE 1.17 Trends in anemia among children 6–59 months of age: Egypt, 2000, 2005, 2014 60 50 48.7 Prevalence of anemia (%) 40 30.5 30 27.4 20 10 0 2000 2005 2014 Source: EDHS microdata various years (dataset), ICF International, Rockville, MA, https:// dhsprogram.com/data/. 22 | Scaling Up Nutrition in the Arab Republic of Egypt helminthic infections (FAO and WHO 2004). Although term infants are born with an adequate supply of iron stores (provided that the mother is not anemic), iron requirements after six months are supplied largely by the appropriate com- plementary foods. Iron deficiency can result in reduced immune function and increased susceptibility to infectious disease, as well as impaired physical devel- opment and cognitive function among children (Black et al. 2013; FAO and WHO 2004). Fortification of staple foods, daily iron supplementation, as well as con- sumption of iron-rich foods such as meat, fish, poultry, and eggs, have been rec- ommended as preventive measures against iron deficiency (FAO and WHO 2004; WHO 2016). According to EDHS 2014, less than 8 percent of children 6–59 months of age received an iron supplement in the seven days prior to the survey. Anemia prevalence among children is particularly high in the frontier gover- norates, in rural areas, and in poorer households. Compared with the urban gover- norates, anemia prevalence is significantly higher in the frontier governorates (44.5 percent, p < 0.001) and rural areas of both Upper Egypt (30.3 percent, p < 0.01) and Lower Egypt (28.5 percent, p < 0.05). Prevalence is significantly higher in rural areas than urban areas (29.4 percent versus 23.2 percent, p < 0.001) and highest among children from the poorest households (34.6 percent versus 21.2 percent in richest, p < 0.001), and it decreases with increasing wealth quintile (p < 0.001). Only about half of children under 2 consume iron-rich foods, a situation that has worsened since 2008. Consumption of iron-rich foods by children 6–23 months of age declined from 65.6 percent in 2008 to 53 percent in 2014.10 The highest proportion of children consuming iron-rich foods are from the fron- tier governorates (66.3 percent), and the lowest proportion are from rural Upper Egypt (47.1 percent). The proportions are similar by sex, area of residence, and wealth quintile. Micronutrient status among women of reproductive age Vitamin A About one in three women of reproductive age in Egypt report receiving ­ vitamin A supplements after their delivery of a child. In the EDHS 2014 survey, only 31 percent of women reported receiving vitamin A supplements two months after their last delivery, representing a significant decline from 57 percent in 2008. Vitamin A deficiency in pregnant women has been linked to night blind- ness and higher maternal mortality, with subsequent effects on low birthweight and infant mortality (Black et al. 2013; Rice, West, and Black 2004). Maternal deficiencies can be addressed through supplementation during pregnancy in areas in which vitamin A deficiency is a severe public health problem and during the postpartum period. It can be used as well to prevent night blindness (WHO 2016). Lower Egypt has the highest proportion of women who received postpar- tum vitamin A supplementation (32.3 percent), and the frontier governorates have the lowest proportion (22.2 percent). The proportion is also higher in rural areas (32.8 percent) than in urban areas (27.9 percent). Iron and iron-deficiency anemia The majority of women in Egypt report receiving iron supplements during their last pregnancy, yet almost one in four pregnant women are anemic. In 2014, 67 percent of women reported receiving iron supplements during their last pregnancy, a significant increase over 2008 (42.5 percent). The prevalence Undernutrition of Children Under 5 and Women of Reproductive Age in Egypt | 23 of anemia among nonpregnant Egyptian women of reproductive age in 2012 was 29.6 percent and among pregnant women, 24.7 percent,11 both of which are of moderate public health significance, according to the WHO classification (WHO 2001). These percentages are lower than in some Middle East and North Africa countries (such as Tunisia, 27.9 percent and 34.4 percent; Morocco, 34 percent and 38.6 percent, respectively; Jordan, 20.6 percent and 34 percent) but higher than others (such as Kuwait, 20.7 percent and 28.8 percent). Anemia in pregnancy is associated with higher maternal mortality, low birthweight, and higher perinatal mortality (Black et al. 2013; Stoltzfus, Mullany, and Black 2004). Deficiency can result from inadequate consumption of iron-rich foods and, among women of reproductive age, the depletion of iron stores during menstruation. Proper fetal development requires higher levels of iron, and thus pregnant women are at greater risk of deficiency (Black et al. 2008). Increased consumption of iron-rich foods, as well as routine supplementation during pregnancy and deworming, are recommended solutions to improving the iron levels of pregnant women (WHO 2012). CONCLUSIONS Malnutrition, both chronic (stunting) and acute (wasting) remain at elevated levels of public health significance in Egypt, and they are at levels higher than those found in most of Egypt’s regional counterparts and the Middle East and North Africa regional average. This analysis found that one in five children 0–23 months of age in Egypt is stunted. Stunting prevalence varies across Egypt’s regions, from a low of percent in the rural frontier governorates, to a high of 28.9 percent in urban 15.3 ­ Upper Egypt. Disparities in stunting prevalence between the richest and poorest wealth quintiles have significantly narrowed due in part to a more consistent decline in the poorest quintile since 2000 and in part as a result of slower declines or increases in the top wealth quintiles. In the multivariate regressions, several determinants are consistently associ- ated with stunting across the models. A child’s sex, reported size at birth, early initiation of breastfeeding, maternal education, and household wealth remain consistent determinants of childhood stunting in this analysis. Boys have from 50 to 100 percent higher odds of being stunted, and small birth size is associated with a 90 percent increase in the odds of stunting among children under 6 months of age. Early initiation of breastfeeding appears to protect against stunting, reducing the odds by 35 percent among children in rural households in the anal- ysis, although the current global evidence base on the relationship between stunting and breastfeeding is inconclusive. Maternal education below comple- tion of secondary schooling increases the odds of childhood stunting by 50 ­percent. Studies have shown that boys, particularly in Sub-Saharan Africa and some Asian countries, face greater odds of stunting, although the mechanism for this differential remains unclear (Keino et al. 2014; Rakotomanana et al. 2017; Wamani et al. 2007). Some studies have theorized that males are more vulnera- ble to morbidity in early life (Green 1992), and thus increased morbidity will affect early nutrition. The prevalence of wasting has consistently increased since the 2000 round of the EDHS, and this upward trend is evident and significant across several 24 | Scaling Up Nutrition in the Arab Republic of Egypt demographic factors. Wasting has sharply increased in the frontier governorates since 2000, and the upward trend is higher than in the urban governorates. There is an increasing trend among children from both rural and urban house- holds, and although prevalence is nearly identical in both boys and girls, the upward trend is more pronounced among girls than boys. For the wasting outcome, a child’s age, birth order, mother’s BMI, and resi- dence in the frontier governorates are significant factors in the multivariate regression. Younger children, children of later births, and children living in fron- tier governorates have significantly greater odds of wasting, whereas children whose mothers are overweight or obese have significantly reduced odds of wast- ing. Frontier governorates, comprising largely desert areas, may be more suscep- tible to climate change and greater food insecurity and thus have a greater likelihood of acute malnutrition among children. The prevalence of key underlying determinants was high: 90 percent of women delivered in a health facility; 98 percent received a postnatal checkup after delivery; 80 percent attended four or more antenatal care visits during their most recent pregnancy; and 80 percent were involved in decisions about their own health care. Women in the frontier governorates generally have lower par- ticipation in health care decision making, which is in line with women in rural frontier governorates having the lowest attendance at four or more antenatal care visits during their most recent pregnancy. Although access to improved san- itation is nearly universal, there are significant disparities in access to piped water, with only 60 percent of households in the rural frontier governorates hav- ing such access. Overall, the prevalence of key feeding and care practices is low nationally and varies considerably across regions. Only one in three children under 6 months of age is exclusively breastfed, which drops to one in eight at 4–5 months of age. Although almost four in five children are introduced to complementary foods in a timely manner, only one in four children 6–23 months of age are fed both an adequate number of times and with a nutritionally diverse diet. This analysis indicates that five key areas for interventions should be explored: 1. Priority should be given to interventions that improve maternal nutrition before and during pregnancy as well as in the postpartum period to ensure optimal birth and early childhood outcomes. Such interventions should include ensuring adequate micronutrient status by providing antenatal micronutrient supplements, screening and treating micronutrient deficien- cies (mainly anemia), improving access to and consumption of nutritionally diverse foods among pregnant women, and monitoring weight gain during pregnancy as part of antenatal care. 2. Meeting nutritional requirements is a key factor in ensuring that infants and young children are able to survive and thrive. Suboptimal breastfeeding and complementary feeding practices along with micronutrient deficiencies hinder their potential. Therefore, a focus on implementation of an infant and young child feeding (IYCF) social and behavioral change strategy and ensuring infants and young children are receiving sufficient micronutrients through either com- plementary feeding or supplementation are important areas to explore. 3. Infections have a negative effect on malnutrition, including in Egypt. Ensuring that key interventions are systematically implemented at scale can help to Undernutrition of Children Under 5 and Women of Reproductive Age in Egypt | 25 break this vicious cycle, including therapeutic zinc supplementation in cases of diarrhea, deworming, and ensuring proper sanitation and hygiene prac- tices to control intestinal infections during infancy and childhood. Scaling up water, sanitation, and hygiene (WASH) interventions, particularly in rural areas with lower coverage, can also help to reduce the cycle of infection and malnutrition. 4. Other nutrition-sensitive interventions should be investigated to under- stand the potential to decrease food insecurity and poverty, improve health and nutrition knowledge, and broadly contribute to meeting nutri- tion goals. 5. Because of the current high level of wasting (8 percent), development and implementation of an integrated management of acute malnutrition (IMAM) strategy would help to ensure the short-term effective treatment of children with severe or moderate acute malnutrition, thereby reducing rates of mor- tality among this age group. NOTES  1. WHO classifies the country-level prevalence of stunting into levels of public health signif- icance. The latest revised threshold levels for stunting are as follows: prevalence of <2.5 percent (very low public health significance), 2.5–9 percent (low), 10–19 ­ percent (medium), 20–29 percent (high), ≥30 percent (very high)—see de Onis et al. (2018).  2. Test for trend was based on a logistic regression model fitting the outcome, stunting, on a continuous year variable. The model accounted for weighting and clustering inherent in the complex design of the EDHS survey.  3. World Development Indicators (database), World Bank, Washington, DC, https://databank​ .worldbank.org/source/world-development-indicators..  4. Because stunting stems from a multitude of factors, other significant factors may not be captured in the EDHS (and so are not examined here), and yet they also affect the levels and severity of stunting.  5. WHO classifies the country-level prevalence of wasting into levels of public health signifi- cance. The latest revised threshold levels for wasting are as follows: prevalence of less than 2.5 percent (very low public health significance), 2.5–9 percent (low), 10–19 percent (medium), 20–29 percent (high), equal to or greater than 30 percent (very high)—see de Onis et al. (2018).  6. Children are classified as wasted if their weight-for-height (WHZ) z-score is more than two standard deviations below the median weight of a child of the same height and sex, according to the WHO Child Growth Standards median.  7. Based on EDHS data compiled by ICF International on the STATcompiler.com website.  8. WHO recommends that in settings where vitamin A deficiency is a public health problem (that is, where the prevalence of night blindness is 1 percent or higher in children 24–59 months of age or where the prevalence of vitamin A deficiency—serum retinol of 0.70 micromoles per liter or lower—is 20 percent or higher in infants and children 6–59 months of age), high-dose vitamin A supplementation be given to infants and children 6–59 months of age.  9. WHO classifies the country-level prevalence of anemia into levels of public health signifi- cance (2001). The threshold levels for anemia are as follows: prevalence of <4.9 percent, no public health problem; 5–19.9 percent, low; 20–39.9 percent, moderate, and ≥40 percent, severe. 10. Based on EDHS data compiled by ICF International on the STATcompiler.com website.   11. 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Rajaram. 2007. “Influence of Parental and Socioeconomic Factors on Stunting in Children under 5 Years in Egypt.” Eastern Mediterranean Health Journal 13 (6): 1330–42. 2 Overnutrition of Children Under 5 and Women of Reproductive Age in Egypt FRANK HU AND YANPING LI KEY MESSAGES • There is a rising trend in childhood overweight (and obesity) in Egypt, and the prevalence is higher than in most countries in the Middle East and North Africa region. – The proportion of overweight children with stunting has also increased in the last few decades. – Key determinants of overweight and obesity in children include urban liv- ing, maternal obesity, and a calorie-dense diet. • High levels of overnutrition among women of reproductive age predominate in Egypt, with more than 80 percent of such women overweight or obese. – More than 10 percent of women in Egypt show signs of both obesity and anemia. – Based on data from the Egypt Demographic and Health Survey and the literature, maternal obesity is a critical factor in the development of child- hood obesity. – Key determinants of overweight and obesity among women of reproduc- tive age include sedentary lifestyles and consumption of energy-dense foods, with women from richer households and urban areas slightly more likely to be overweight. INTRODUCTION This chapter describes the situation on overnutrition among children under 5 and women of reproductive age in Egypt. The chapter utilizes data from the 1992, 1995, 2000, 2005, 2008, and 2014 rounds of the Egypt Demographic and Health Survey (EDHS) (El-Zanaty et al. 1993, 1996; El-Zanaty and Way 2001, 2006, 2009; MOHP, El-Zanaty and Associates, and ICF International 2015), as well as data from other literature and databases. This chapter also examines the trends in overweight and obesity and the prevalence of anemia among women of reproductive age.  29 30 | Scaling Up Nutrition in the Arab Republic of Egypt CHILDHOOD OVERWEIGHT AND OBESITY Prevalence and trends In Egypt, almost 15 percent of children under 5 are overweight, and of those almost 5 percent are obese. Overweight among children, defined as having a weight-for-height z-score greater than two standard deviations above the WHO Child Growth Standards median (WHO 2008), has both immediate and long- term consequences (Black et al. 2013), and it increases the risk of obesity in adulthood. According to the World Health Organization (WHO) classification (WHO 2008), the prevalence of overweight individuals in Egypt is currently a significant public health problem with growing concern over the increasing per- vasiveness and long-lasting impact. The prevalence of overweight in children under 5 was 14.9 percent in Egypt in 2014, the third-highest in Middle East and North Africa countries (figure 2.1). In Egypt, 10.1 percent of overweight children had a weight-for- height z-score (WHZ) of greater than 2, but less than or equal to 3, and 4.8 percent of these children were obese, with a weight-for-height z-score above 3, according to the WHO criteria (WHO 2008). Despite fluctuations, Egypt has seen a steady increase in child overweight prevalence since the early 1990s, with a small reduction recorded after 2008. The prevalence of overweight among children in Egypt was 13.8 percent in 1992, 13.4 percent in 1995, 17.6 percent in 2000, 13.2 percent in 2005, 19.1 percent in 2008, and 14.9 percent in 2014, with a significant upward trend over time (p = 0.001 for trend). In all of the survey years, the estimates in Egypt were much higher than the average level of overweight in Middle East and North Africa countries for which data are available (figure 2.2). In 2014 in Egypt, the prevalence of overweight (including obesity) is 15.3 ­ percent among boys and 14.3 percent among girls, while the prevalence of obesity is 4.9 percent among boys and 4.7 percent among girls (figure 2.3). FIGURE 2.1 Prevalence of overweight among children under 5: Middle East and North Africa economies, various years Libya, 2007 Syrian Arab Republic, 2009 Egypt, Arab Reb., 2014 14.9% Tunisia, 2012 Algeria, 2012 Iraq, 2011 Morocco, 2011 Kuwait, 2014 West Bank and Gaza, 2014 Djibouti, 2012 Middle East and North Africa Jordan, 2012 average (10.6%) Oman, 2014 Yemen, Rep., 2013 0 5 10 15 20 25 Overweight prevalence (%) Sources: Egypt: EDHS microdata 2014 (dataset), Ministry of Health and Population and ICF International, Cairo, Egypt, and Rockville, MA, https://dhsprogram.com/data/; other countries: World Development Indicators (database), World Bank, Washington, DC, https:// databank.worldbank.org/source/world-development-indicators. Overnutrition of Children Under 5 and Women of Reproductive Age in Egypt | 31 FIGURE 2.2 Trends in prevalence of childhood overweight: Middle East and North Africa economies, various years 30 25 Overweight prevalence among children 0–59 months (%) 20 19.1 17.6 14.9 15 13.8 13.4 13.2 10 5 0 1990 1992 1995 2000 2005 2008 2010 2014 2018 Economy: Egypt, Arab Rep. Jordan Kuwait Middle East and North Africa Morocco Oman average Tunisia West Bank and Gaza Yemen, Rep. Sources: EDHS microdata various years (dataset), ICF International, Rockville, MA, https://dhsprogram.com​ /data/; other countries: World Development Indicators (database), World Bank, Washington, DC, https:// databank.worldbank.org/source/world-development-indicators. FIGURE 2.3 Prevalence of overweight and obesity among children: Egypt, 2014 Girls 9.6 4.7 14.3 Boys 10.4 4.9 15.3 Total 10.1 4.8 14.9 0 2 4 6 8 10 12 14 16 18 20 2 < WHZ ≤ 3 WHZ > 3 (Obesity) Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). Note: WHZ = weight-for-height z-score. The steady increase in overweight is consistent for both girls and boys. As shown in figure 2.4, the upward trend in overweight is consistent in boys ( p =0.08 for trend) and girls ( p = 0.004 for trend) without significant gender differences ( p = 0.4 for interaction). ­ The upward trend in overweight prevalence is greater in urban than in rural areas. When stratified by living area (figure 2.5), a significant upward trend in overweight prevalence is observed among children living in urban areas ( p < 0.0001 for trend) but not rural areas ( p = 0.33 for trend; p = 0.005 for interaction). 32 | Scaling Up Nutrition in the Arab Republic of Egypt FIGURE 2.4 Time trend of overweight among infants and children by sex: Egypt, 1992–2014 22 20 18 Percent 16 14 12 10 1992 1995 2000 2005 2008 2014 Females Males Linear (females) Linear (males) Sources: EDHS 1992, 1995, 2000, 2005, 2008, 2014 (El-Zanaty et al. 1993, 1996; El-Zanaty and Way 2001, 2006, 2009; MOHP, El-Zanaty and Associates, and ICF International 2015). FIGURE 2.5 Time trend of overweight among infants and children across urban and rural areas: Egypt, 1992–2014 22 20 18 Percent 16 14 12 10 1992 1995 2000 2005 2008 2014 Urban Rural Linear (urban) Linear (rural) Sources: EDHS 1992, 1995, 2000, 2005, 2008, 2014(El-Zanaty et al. 1993, 1996; El-Zanaty and Way 2001, 2006, 2009; MOHP, El-Zanaty and Associates, and ICF International 2015). Risk factors associated with overweight among children under 5 Childhood overweight and obesity are caused by increased energy storage from overconsumption of calories beyond growth needs and energy expendi- ture (Anderson and Butcher 2006; Goran and Treuth 2001). The increasing prevalence of overweight in Egyptian children could be attributed largely to rapid urbanization and the accompanying nutritional transition characterized by dietary shifts from traditional foods and local fruits and vegetables to Westernized diets that are higher in fat, sugar, and calories (Aboul-Enein, Bernstein, and Neary 2016; Farrag, Cheskin, and Farag 2017). According to Hassanyn (2000), as early as between 1981 and 2000 the consumption of meat and dairy increased substantially (also see Aly et al. 1981; Hassan, Moussa, and Ismail 2006). In Egypt, children from both the poorest and richest households have a sig- nificantly higher likelihood of being overweight. And yet socioeconomic status Overnutrition of Children Under 5 and Women of Reproductive Age in Egypt | 33 and obesity tend to be inversely related in high-income countries and positively related in developing countries (Kim and von dem Knesebeck 2018; Newton, Braithwaite, and Akinyemiju 2017; Wu et al. 2015). In Egypt, however, the prev- alence of overweight is 17.7 percent among children under 5 from the richest households, 15.8 percent among children from the poorest households, and 13.9 percent among households within the middle wealth index (figure 2.6, panel a). The government of Egypt (GoE) subsidizes certain foods such as sugar and flour despite their low nutritional value, and thus the poorest households have access to affordable, energy-dense foods. The high prevalence of over- weight among the richest households may be explained by urbanization and its associated transition to more Western diets and sedentary lifestyles (Angkurawaranon et al. 2014). The negative coping strategies employed by poor families, including reverting to calorie-dense foods to cope with higher food prices and food inaccessibility rather than consuming nutrient-rich foods, may explain their greater likelihood of being overweight (WFP 2013). Children in urban governorates tend to be more overweight in Egypt, indicat- ing a link with urbanization. The prevalence of overweight is 8.4 percent among children living in frontier governorates and 14.5 percent among children living in the urban governorates, suggesting a link between urbanization and obesity rates (figure 2.6, panel b). FIGURE 2.6 Prevalence of overweight children by wealth index and region: Egypt, 2014 a. Wealth index Poorest 15.8 Poorer 12.9 Middle 13.9 Richer 14.9 Richest 17.7 0 5 10 15 20 Overweight prevalence (%) b. Region Urban governorates 14.5 Lower Egypt 16.5 Urban 17.3 Rural 16.3 Upper Egypt 13.3 Urban 16.9 Rural 12 Frontier governorates 8.4 0 5 10 15 20 Overweight prevalence (%) Regions Subgroups of urban and rural within regions Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). 34 | Scaling Up Nutrition in the Arab Republic of Egypt In Egypt, children with large birth size as well as very small birth size have a higher prevalence of overweight than those with normal birth size, although birth size does not reach a significant level in the multivariate-adjusted model (figure 2.7, panel a). This finding partially supports the finding in a recent meta-analysis that high birthweight is associated with increased risk of obesity from childhood to early adulthood (Yu et al. 2011). Several other characteristics are relevant to childhood overweight, includ- ing family size and birth order. In particular, a smaller family size is associated with childhood obesity. For children under 5, the childhood overweight prev- alence is 15.3 percent in families with one child; 14.9 percent, two children, 13.9 percent, three children; 12.7 percent, four children; and 8.1 percent, five or more children. Birth order also seems to be relevant to childhood overweight. Children who are born first have a 15.7 percent prevalence of overweight, whereas children born second have a 15.5 percent prevalence; third, 14.6 per- cent; and fourth or later, 13.7 percent. However, when simultaneously adjusting for birth order, the number of children under 5, and family size, only family size is significantly associated with the likelihood of being overweight: chil- dren from households with fewer members are more likely to be overweight (figure 2.7, panel b; figure 2.8). FIGURE 2.7 Prevalence of overweight children by birthweight, family size, mother’s obesity level, and mother’s education level: Egypt, 2014 a. Birthweight b. Family size Very large 16.9 First 15.7 Larger 17.0 Second 15.5 Average 14.9 Third 14.6 Smaller 13.6 Fourth 13.7 Very small 16.6 Fifth or later 12.1 0 5 10 15 20 0 5 10 15 20 Overweight prevalence (%) Overweight prevalence (%) c. Mother’s BMI d. Mother’s education level No education 13.3 18.5–24.9 kg/m2 13.2 Primary 15.3 25–29.9 kg/m2 15.2 Secondary 14.9 ≥30 kg/m2 15.6 Higher 16.2 0 5 10 15 20 0 5 10 15 20 Overweight prevalence (%) Overweight prevalence (%) Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). Note: BMI = body mass index; kg/m2 = kilograms per square meter. Overnutrition of Children Under 5 and Women of Reproductive Age in Egypt | 35 FIGURE 2.8 Multivariate-adjusted odds ratio for overweight among children under 5: Egypt, 2014 Males vs. Females Household wealth index Poorest vs. middle * Poorer vs. middle Richer vs. middle Richest vs. middle * Regions (vs. urban goverates) Urban area of Lower Egypt Rural area of Lower Egypt * Urban area of Upper Egypt Rural area of Upper Egypt Frontier governorates * Number of household members Three or two vs. six or more * Four vs. six or more Five vs. six or more Mother’s body weight Overweight vs. normal weight Obesity vs. normal weight * 0.5 1.0 2.0 Odds ratio (95% CI) for overweight Significant associations Associations not reached significant level Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). Note: CI = confidence interval. *p < 0.05. Finally, children from mothers who have higher levels of education, as well as from mothers who are obese, are more likely to be overweight. A recent study in Egypt finds that children whose mothers had higher education levels were less likely to be stunted than children whose mothers had lower education levels (Sharaf, Mansour, and Rashad 2018). Data from EDHS 2014 suggests that chil- dren from mothers with higher education levels are more likely to be overweight 36 | Scaling Up Nutrition in the Arab Republic of Egypt than children from mothers with lower education levels, but the association is not statistically significant after multivariate adjustment (figure 2.7, panel d). Another study of Egyptian mothers and children indicates that maternal con- sumption of beverages with added sugar is a significant predictor of children’s body mass index, likely because of the access to these beverages in the household (Hassan et al. 2016). Elsewhere, parental obesity is found to be associated with approximately a threefold increase in the odds of overweight among Lebanese adolescents (Nasreddine et al. 2014) and a twofold increase in the presence of obesity among children in Jordan (Al-Kloub et al. 2010). In Egypt, children under 5 are more likely to be overweight if their mothers are overweight or obese, even after adjustment for multiple risk factors (figure 2.7, panel c; figure 2.8). DOUBLE BURDEN OF STUNTING AND OVERWEIGHT Prevalence and trends In Egypt, for all age groups from 3 to 59 months, the prevalence of stunting is higher than overweight (figure 2.9). Although overweight is generally an indica- tor of overnutrition, stunting reflects the cumulative effects of undernutrition (Tzioumis et al. 2016). The double burden of malnutrition, defined as stunting and overweight occurring simultaneously, is a major public health concern in low- and middle-income countries experiencing rapid economic and nutrition transitions, including the Middle East and North Africa countries (Black et al. 2013; Tzioumiset al. 2016). In 2014, 22 percent of Egyptian children under 5 were stunted and 15 percent were overweight. However, almost 51 percent of overweight children are also stunted, a figure that has increased by more than half since the early 1990s. Among the FIGURE 2.9 Prevalence of overweight and stunting among children under 5: Egypt, 2014 35 Prevalence of overweight and stunting (%) 30 25 20 15 10 5 0 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 42 44 46 48 50 52 54 56 58 Age (months) Overweight Stunting Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). Overnutrition of Children Under 5 and Women of Reproductive Age in Egypt | 37 14.9 percent of overweight children in Egypt in 2014, 7.6 percent were overweight with stunting (accounting for 50.9 percent of all of the overweight children). In 1992, out of 13.8 percent of children overweight, only 36.6 percent were stunted (figure 2.10). However, only a few studies—in China (Li et al. 2011), Mexico (Fernald and Neufeld 2007), and South Africa (Mamabolo et al. 2005)— have examined the presence and determinants of undernutrition (stunting) and overnutrition (overweight) within the same individuals. The following section examines risk factors of the double burden of stunting and overweight among children 0–59 months of age in Egypt. Risk factors associated with double burden of stunting and overweight among children 0–59 months of age Compared with single-birth children, twins were more likely to be overweight with stunting but less likely to be overweight without stunting in Egypt in 2014 (figure 2.11). Being a twin has also been found to be inversely related to children’s height-for-age z-score (Sharaf, Mansour, and Rashad 2018). In addition, accord- ing to the EDHS data, boys are more likely to be overweight with stunting than girls. A meta-analysis of 16 Demographic and Health Survey (DHS) data sets also found that boys were more stunted than girls in Sub-Saharan countries (Wamani et al. 2007). Children from the poorest households have a higher likelihood of being over- weight with or without stunting, compared with children from households within the middle wealth index. Children from the richest households have a significantly higher likelihood of being overweight without stunting (figure 2.11). Compared with those living in urban governorates, children living in frontier governorates have a lower likelihood of being overweight with and without stunting. Children living in urban areas of Upper Egypt have a significantly higher likelihood of being overweight with stunting (figure 2.11). Upper Egypt is the poorest region in Egypt, and therefore undernutrition and stunting FIGURE 2.10 Prevalence of overweight with and without stunting: Egypt, 1992–2014 25 20 Prevalence of overweight (%) 15 8.6 10.8 7.3 10 5.8 8.8 6.8 5 10.4 7.6 6.8 7.6 6.4 5.0 0 1992 1995 2000 2005 2008 2014 Overweight with stunting Overweight without stunting Sources: EDHS 1992, 1995, 2000, 2005, 2008, 2014 (El-Zanaty et al. 1993, 1996; El-Zanaty and Way 2001, 2006, 2009; MOHP, El-Zanaty and Associates, and ICF International 2015). 38 | Scaling Up Nutrition in the Arab Republic of Egypt FIGURE 2.11 Odds ratio for overweight (including obesity) with or without stunting: Egypt, 2014 Males vs. Females * Twins: yes vs. no * * Household wealth index Poorest vs. middle * * Poorer vs. middle Richer vs. middle Richest vs. middle * Regions (vs. urban governorates) Urban area of Lower Egypt Rural area of Lower Egypt Urban area of Upper Egypt * Rural area of Upper Egypt Frontier governorates * * Age in years 0 vs. 2 1 vs. 2 3 vs. 2 4 vs. 2 * Number of household members Three or two vs. six or more * Four vs. six or more * Five vs. six or more Mother’s body weight (vs. normal weight) Overweight Obesity * Mother currently employed: yes vs. no * 0.4 1.0 4.0 Odds ratio for overweight with or without stunting Odds ratio for overweight with stunting Odds ratio for overweight without stunting Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). *p < 0.05. are common. At the same time, the environment of urban areas might be more “obesogenic” than that of rural areas. In low- and middle-income countries, rapid urbanization has been linked to poor diet and reduced physical activity (Angkurawaranon et al. 2014). In Brazil and the Russian Federation, dual burden households (with both underweight and overweight members) are more likely to be urban and low-income than households with only overweight members but no underweight members (Doak et al. 2005). Maternal characteristics also appear to play a role in childhood overweight and stunting. Obese mothers in Egypt are more likely to have an overweight child without stunting, compared with normal weight mothers (figure 2.11). Overnutrition of Children Under 5 and Women of Reproductive Age in Egypt | 39 Another study in Egypt finds that maternal employment has a significant nega- tive impact on child nutritional status as measured by the height-for-age z- score; children of unemployed mothers are taller than those of employed mothers (Rashad and Sharaf 2017). Employed mothers were also more likely to have stunted overweight children (figure 2.11). Maternal employment may reduce the time mothers can devote to childcare, feeding, and preparation of nutritious food. Additional data from Egypt suggest that older siblings play an important role in feeding young children when mothers are away from home, and often feed them junk foods such as processed snack foods containing added sugar (Kavle et al. 2015). A prospective study in rural South Africa found that having a working or student mother increased the risk of concurrent stunting and over- weight among children 3 years of age (Mamabolo et al. 2005). Perceptions and the availability of certain complementary foods may also affect childhood obesity rates in Egypt. Complementary foods given to children weaning from breastfeeding are important for balancing weight and height growth. In the Middle East and North Africa region, including Egypt, comple- mentary foods are often sugary drinks and snacks that are low in nutritional value and high in calories (Aitsi-Selmi et al. 2014; Nasreddine et al. 2012; Popkin, Adair, and Ng 2012; Zottarelli, Sunil, and Rajaram 2007). Government subsidies of sugar and oil have played an important role in the Egyptian diet by increasing the accessibility and affordability of these types of energy-dense foods (Asfaw 2007; Austin, Hill, and Fawzi 2013; Kavle et al. 2014, 2015). Among the Egyptian population, sponge cakes and sugary biscuits are not perceived as unhealthy and are considered “ideal” common complementary foods. Unhealthy foods such as sugary biscuits, candy, chips, and cakes make up one-third of the foods con- sumed daily by Egyptian infants (Kavle et al. 2015). Child consumption of sugary snack foods is associated with a 51 percent higher likelihood of being part of a “stunted child and obese mother” household (Aitsi-Selmi 2015). Poor dietary diversity can also obstruct healthy child growth. One study finds that of 300 Egyptian infants, only half meet the WHO cutoff for adequate diver- sity at 12 months (Kavle et al. 2016). The same study finds a significant associa- tion between a minimum dietary diversity (infants consuming at least four food groups from 6 months of age) and the weight-for-length z-score in Lower Egypt (Kavle et al. 2016). An earlier study in China (Li et al. 2010) indicated that the overall dietary diversity score was significantly lower in stunted overweight chil- dren than in normal weight and overweight children. Specifically, stunted over- weight children consume a lower diversity of vegetables and fruits and animal food groups than normal weight and overweight children. On the other hand, stunted overweight children consume a larger diversity of cereal and tubers than stunted children without overweight. As recommended by WHO for measuring dietary diversity in infants and young children 6–23 months of age (WHO 2008), EDHS 2014 collected food intake data on children under 2. The following food groups were used to calcu- late dietary diversity scores: (1) infant formula, milk other than breast milk, cheese, or yogurt or other milk products; (2) foods made from grains, roots, and tubers; (3) vitamin A–rich fruits and vegetables; (4) other fruits and vegetables; (5) eggs; (6) meat, poultry, fish, shellfish, and organ meats; (7) legumes and nuts. Children who did not consume any foods within the seven identified food groups had the highest prevalence of overweight with stunting. The prevalence of overweight was highest among children who consumed foods in all seven food groups in the last 24 hours, especially overweight without stunting (figure 2.12). 40 | Scaling Up Nutrition in the Arab Republic of Egypt FIGURE 2.12 Prevalence of overweight with and without stunting according to the number of food groups children 6–23 months of age living with their mother were fed in last 24 hours: Egypt, 2014 20 Prevalence of overweight (%) 15 7.1 8.0 6.7 7.6 10 7.2 6.8 7.3 11.8 5 7.4 7.7 7.3 5.5 6.1 4.8 0 0 1 2 3 4 5 6 or 7 Number of food group Overweight with stunting Overweight without stunting Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). Note: Food groups: (0) = children did not eat any food from the following seven food groups; (1) infant formula, milk other than breast milk, cheese, or yogurt or other milk products; (2) foods made from grains, roots, and tubers; (3) vitamin A–rich fruits and vegetables; (4) other fruits and vegetables; (5) eggs; (6) meat, poultry, fish, shellfish, and organ meats; (7) legumes and nuts. Because research has indicated that Egyptian children under 2 frequently consume energy-dense junk foods, children not consuming foods in the seven ­ groups may have been consuming more junk food (Kavle et al. 2015). In the study by Kavle et al. (2015), Egyptian mothers stated that their primary reasons for withholding the introduction of nutritious food and delaying family/table foods until 1 year of age were fears of illness, inability to digest these foods, or allergies. After analyzing each of the seven food groups, this study found that infant for- mula, milk other than breast milk, cheese, or yogurt or other milk products was the only food group significantly associated with a lower likelihood of being overweight with stunting. Although the consumption of soft drinks in Egypt was not assessed in EDHS 2014, there is evidence that it has increased substantially over the past few decades. A 2011 survey of the health behavior of Egyptian teenagers indicated that 60 percent of boys and 51 percent of girls consumed one or more carbon- ated, sugar-sweetened drink daily, and 87 percent did not participate in regular physical activity (WHO and UNICEF 2003). Future EDHS surveys should include an assessment of sugar-sweetened beverage consumption. OVERWEIGHT AND OBESITY IN WOMEN OF REPRODUCTIVE AGE Prevalence and trends In Egypt, more than a third of women are overweight and close to half of all women are obese—a situation that has worsened since 2000. Overweight and obesity, defined as having a body mass index of 25–29.9 for overweight and 30 or Overnutrition of Children Under 5 and Women of Reproductive Age in Egypt | 41 FIGURE 2.13 Trends in overweight and obesity among women of reproductive age: Egypt, 2000–2014 90 80 70 60 Percent 50 40 30 20 10 0 2000 2005 2008 2014 Overweight Obese Sources: EDHS 2000, 2005, 2008, 2014 (El-Zanaty and Way 2001, 2006, 2009; MOHP, El-Zanaty and Associates, and ICF International 2015). greater for obesity, increase the risk of adverse pregnancy outcomes such as hemorrhaging and maternal death, as well as increased infant mortality and preterm birth (Black et al. 2013). According to EDHS 2014, the prevalence of overweight and obesity among Egyptian women of reproductive age is 36.5 percent and 48.1 percent, respec- tively (figure 2.13). Moreover, more than five out of every six Egyptian women 15–49 years of age are overweight or obese (85 percent). Only 15.1 percent of women are at a normal weight, and the prevalence of underweight is very low (0.3 percent). In a WHO report on obesity in adults over age 18 (WHO 2014), Egypt had a prevalence of obesity among women of 37.5 percent, ranking it in the middle of the Middle East and North Africa countries (figure 2.14, panel a). However, the average BMI among Egyptian women was higher than that in all the other Middle East and North Africa countries, except for Kuwait at 31 percent (figure 2.14, panel b). Another analysis of obesity among urban women found that Egyptian women had the highest prevalence of overweight and obesity among the 24 African countries in 2014 (Amugsi et al. 2017). Whereas the prevalence of obesity among women tends to increase rapidly with age, the prevalence of overweight tends to decrease slightly with age. In 2014, 16.4 percent of women age 16 were obese, compared with 67.2 percent of women age 49. By contrast, 29 percent of women age 16 were overweight, com- pared with 27.3 percent of women age 49. Considering overweight and obesity together, 45.4 percent of 16-year-old and 90 percent of 36-year-old Egyptian women were overweight or obese. Nearly all 49-year-old Egyptian women (94.5 percent) were overweight or obese (figure 2.15). For women in Egypt, the likelihood of obesity increases by approximately 8 percent a year as they age (figure 2.18). The prevalence of overweight and obesity is higher among women from urban households than among their rural counterparts (figure 2.16). This finding has emerged over several rounds of the EDHS. 42 | Scaling Up Nutrition in the Arab Republic of Egypt FIGURE 2.14 Prevalence of obesity among women in Middle East and North Africa countries, 2014 a. Prevalence of obesity 50 45 40 Prevalence of obesity (%) 35 30 25 20 15 10 5 0 n n ti . co ic q ria p. sia p. n an an a a n t ar ep ai by bi da da no ai ou Ira bl at Re Re oc m rd ge w ni hr ra ,R pu Li Q Su Su ba jib Ku O Tu Jo or iA Al Ba ic ab en Re Le D am M h Ar ud m ut ab Isl Ye So Sa t, yp Ar n, Eg Ira n ria Sy b. Mean body mass index 32 31 30 Kilograms per square meter 29 28 27 26 25 24 23 22 ti co . n n ria am an Tu . Le sia Ba n iA n a q ic a an ab r Ku . t ep p p Ar ata ai bi by da da no ud rai ou Ira bl Re Re oc m rd ge w ni ra ,R pu Li h Q Su Su ba jib O Jo or Al ic en Re D M h m ut ab Isl Ye So Sa t, yp Ar n, Eg Ira n ria Sy Source: WHO 2014. Risk factors associated with overweight and obesity in women of reproductive age in 2014 Women from poorer households in rural areas tend to be slightly less obese than women from richer households in urban areas. The prevalence of obe- sity is 44.6 percent among the poorest women, 51.3 percent among women living in richer households, and 47.7 percent among the richest women figure 2.17, panel a). After multivariate adjustment, the poorest women have (­ Overnutrition of Children Under 5 and Women of Reproductive Age in Egypt | 43 FIGURE 2.15 Prevalence of overweight and obesity across women 15–49 years of age: Egypt, 2014 100 Prevalence of overweight and obesity (%) 90 80 70 60 50 40 30 20 10 0 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 Age Obesity Overweight Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). FIGURE 2.16 Overweight and obesity prevalence among women in rural and urban areas: Egypt, 2014 100 Prevalence of overweight and obesity (%) 90 80 70 49.5 60 47.2 48.0 50 40 30 20 38.7 36.6 35.4 10 0 Rural Urban Total Obesity Overweight Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). a significantly lower likelihood of obesity, compared with those in the middle wealth index. A positive association between wealth index and obesity is observed for all women except for the richest (figure 2.18). Obesity preva- lence varies across regions of Egypt, ranging from 37.4 percent in rural areas of Upper Egypt to 54.6 percent in urban areas of Lower Egypt (figure 2.17, panel b) and the difference persists after adjustment for wealth index, edu- cation level, and age (figure 2.18). There is a dose-response relationship between lower education levels and increased prevalence of obesity 44 | Scaling Up Nutrition in the Arab Republic of Egypt FIGURE 2.17 Prevalence of obesity across sociodemographic factors: Egypt, 2014 a. Wealth index b. Region Urban governorates Poorest Lower Egypt Poorer Urban Rural Middle Upper Egypt Richer Urban Rural Richest Frontier governorates 25 30 35 40 45 50 55 60 65 25 30 35 40 45 50 55 60 65 Prevalence of obesity (%) Prevalence of obesity (%) Regions Subgroups of urban and rural within regions c. Education level d. Age at time of first birth No education ≤15 years 16–20 years Primary 21–25 years Secondary 26–30 years Higher >30 years 25 30 35 40 45 50 55 60 65 25 30 35 40 45 50 55 60 65 Prevalence of obesity (%) Prevalence of obesity (%) e. Total children ever born f. Family size 0 or 1 ≤3 2 or 3 4 4 or 5 5 ≥6 ≥6 25 30 35 40 45 50 55 60 65 25 30 35 40 45 50 55 60 65 Prevalence of obesity (%) Prevalence of obesity (%) Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). figure 2.17, panel c), but the association is not statistically significant after (­ multivariate adjustment (figure 2.18). Earlier age of first childbirth, larger number of childbirths, and greater num- ber of household members are all significantly associated with a higher likeli- hood of obesity. Childbirth is commonly associated with weight gain and obesity (Davis et al. 2009; Onubi et al. 2016; Smith et al. 1994). Among Egyptian women, the age of first childbirth appears to influence obesity risk; the prevalence of obesity is 59.6 percent among those who had their first child before age 16 and 50.3 percent for women who had their first child after age 30 (figure 2.17, panel d). The prevalence of obesity among women also increases with number of chil- dren (figure 2.17, panel e), consistent with a meta-analysis by Onubi et al. (2016) that observed an increased risk of obesity in multiparous women compared with nulliparous women in African countries. Larger family size is associated with a Overnutrition of Children Under 5 and Women of Reproductive Age in Egypt | 45 FIGURE 2.18 Multivariate-adjusted odds ratio for obesity among women 15–49 years of age: Egypt, 2014 Increasing age (per year) ** Household wealth index Poorest vs. middle ** Poorer vs. middle Richer vs. middle ** Richest vs. middle Regions (vs. urban governorates) Urban area of Lower Egypt ** Rural area of Lower Egypt ** Urban area of Upper Egypt Rural area of Upper Egypt Frontier governorates Number of household members 4 vs. ≤3 ** 5 vs. ≤3 ** ≥6 vs. ≤3 ** Highest education level Primary vs. no education Secondary vs. no education Higher vs. no education * Currently have a job Yes vs. no ** Age of respondent at time of first birth ≤15 vs. 21–25 years ** 16–20 vs. 21–25 years ** 26–30 vs. 21–25 years >30 vs. 21–25 years ** Number of childbirths 2 or 3 vs. 0 or 1 ** 4 or 5 vs. 0 or 1 ** ≥6 vs. 0 or 1 ** Ate green vegetables in the last 24 hours Yes vs. no ** Ate meat in the last 24 hours Yes vs. no * 0.5 1.0 5.0 Odds ratio (95% CI) for obesity Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). Note: Figure reflects survey logistic models with listed factors simultaneously adjusted. Analyses of sociodemographic factors are based on women 15–49 years of age from EDHS 2014. Analyses of age of first birth and total number of children born are limited to women 30–49 years of age. Analysis of dietary factors is based on EDHS 2005 and EDHS 2008 when dietary surveys are included. Orange bar represents nonsignificant associations at p > 0.1. CI = confidence interval. *p < 0.1 **p < 0.05. 46 | Scaling Up Nutrition in the Arab Republic of Egypt higher likelihood of obesity (figure 2.17, panel f ), which is also consistent with previous findings in Egyptian women (Hassan et al. 2016). After multivariate adjustment, earlier age of first childbirth, larger number of childbirths, and greater number of household members are all significantly associated with a higher likelihood of obesity (figure 2.18). Previous studies have also observed that overweight and obese Egyptian women have a statistically significant higher incidence of unemployment (Hassan et al. 2016), in agreement with studies from Gulf countries (ALNohair 2014) that have shown that high obesity prevalence is strongly related to low education level and unemployment. Consistent with previous findings, the EDHS 2014 data indicate that employed women have a significantly lower like- lihood of obesity (figure 2.18). Lower intake of green vegetables and higher meat consumption by women are linked to an increased likelihood of obesity. Thirty-one percent of women reported intake of green leafy vegetables within 24 hours of the EDHS interview. Those women had a significantly lower likelihood of obesity as compared with women who reported not eating green leafy vegetables, even after multivariate adjustment (p = 0.04). A study of overweight and obese Egyptian women found that vegetable consumption was the only significant dietary factor related to obe- sity; 71.4 percent of the nonobese women consumed vegetables four to seven times a week, compared with only 30.5 percent of overweight and obese women (Hassan, El Shebini, and Ahmed 2016). The subsidization of energy-dense foods, which may have resulted in the overconsumption of calories among Egyptians, is likely a factor in this trend (Aboulenein et al. 2010). As shown in figure 2.18, in the EDHS analysis there is also an association between higher meat consumption and an increased likelihood of obesity at a marginally significant level (p = 0.06). There is a strong association between household wealth and the obesity prev- alence of women with no education. Using EDHS 2005 and EDHS 2008 data, Aitsi-Selmi et al. (2014) find a significant interaction effect between wealth index and education level on odds of obesity among Egyptian women. The inter- action is also present in the EDHS 2014 data (p < 0.01 for interaction). As shown in figure 2.19, panel a, there was a strong positive association between household wealth and obesity prevalence among women with no education, primary or sec- ondary education (all p’s < 0.001 for trend), but a slightly decreasing trend among women with higher education levels (p = 0.06 for trend). When the number of total childbirths increases, the increase in maternal obe- sity is slower among women with a high education level than with a low educa- tion level (figure 2.19, panel b). A study by Onubi et al. (2016) indicates that only women with a tertiary education know their pre-pregnancy weights, which could partially explain the role of education in these associations. Another study (Kavle et al. 2018) finds that Egyptian mothers tend to lack knowledge of optimal weight gain during pregnancy, which could be a reason for the increased obesity risk among women who give birth earlier and have multiple childbirths. The trend of decreasing obesity prevalence according to the increasing age of first childbirth is less pronounced among women with higher levels of educa- tion. Specifically, this trend is less pronounced among women with a tertiary education than women with less education (figure 2.19, panel c). Among women with a tertiary education in EDHS 2014, no one gave birth at or before age 15. However, the interactions between education levels and age at first birth or total number of childbirths are not statistically significant (p > 0.05 for both interac- tions), which may be due to the small sample size. Overnutrition of Children Under 5 and Women of Reproductive Age in Egypt | 47 FIGURE 2.19 Interactions between education levels and household wealth, total number of childbirths, and age at first birth and their effects on obesity prevalence in women: Egypt, 2014 a. Wealth index 70 Prevalence of obesity (%) 65 62 61 60 59 56 57 55 52 52 50 50 50 49 47 48 47 45 45 45 46 42 44 40 41 41 35 30 Poorest Poorer Middle Richer Richest Wealth index b. Total children ever born 70 Prevalence of obesity (%) 65 64 63 61 60 60 58 57 57 58 55 56 54 50 50 51 47 45 45 44 44 40 35 30 0 or 1 2 or 3 4 or 5 ≥6 Total children ever born c. Age at first birth 70 69 65 Prevalence of obesity (%) 63 62 60 58 61 58 57 57 57 55 55 53 54 52 50 50 52 53 49 48 45 40 39 35 30 ≤15 years 16–20 years 21–25 years 26–30 years >30 years Age at time of first birth Education level: No education Primary Secondary Higher Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). 48 | Scaling Up Nutrition in the Arab Republic of Egypt Time trends of BMI and obesity The obesity prevalence and BMI of women who have had a child have increased steadily since the early 1990s. In reproductive-age Egyptian women who had a living birth within five years but not within two months preceding the EDHS interview, the prevalence of obesity was 24.1 percent in 1992 and 35.8 percent in 2012. This prevalence increased an average of 1 percent every two years across all age groups (figure 2.20, panel a). Over the last 22 years, the overall BMI ­ distribution has shifted toward higher BMIs; the mean BMI increased from 26.8 kilograms per square meter in 1992 to 29.1 kilograms per square meter in 2014, with an average increasing rate of one BMI unit per decade FIGURE 2.20 Comparison of mean BMI across age groups and BMI distribution among women who had a live birth in the five years preceding EDHS interview: Egypt, 1992 and 2014 a. Mean BMI by age 34 32 30 BMI (kg/m2) 28 26 24 22 20 15 20 25 30 35 40 45 50 Age b. Comparison of BMI distribution 15.0 Prevalence of overweight and obesity (%) 12.5 10.0 7.5 5.0 2.5 0 8.3 11.3 14.3 17.3 20.3 23.3 26.3 29.3 32.3 35.3 38.3 41.3 44.3 47.3 50.3 53.3 BMI (kg/m3) EDHS 1992 EDHS 2014 Distribution curve lines of BMI Sources: EDHS 1992, 2014 (El-Zanaty et al. 1993; MOHP, El-Zanaty and Associates, and ICF International 2015). Note: BMI = body mass index; EDHS = Egypt Demographic and Health Survey; kg/m2 = kilograms per square meter. Overnutrition of Children Under 5 and Women of Reproductive Age in Egypt | 49 (figure 2.20, panel b). Time trend analysis is based on data on women who had a live birth in the five years before the EDHS interview—those were compara- ble across different surveys. After 1992, the prevalence of both overweight and obesity in women had sig- nificantly increased in urban and rural areas (p < 0.0001 for all), although the increasing trend was more pronounced in rural areas (p for interaction < 0.0001— see figure 2.21. A previous study among Egyptian women observed a similar trend and suggested that government subsidies of high-energy, low-nutrient density foods that form a large part of the diet in poor rural populations may have contributed to the trend (Austin, Hill, and Fawzi 2013). In the early 1990s, women with higher education levels were obese, but by 2014 women with lower education levels were obese as well. Indeed, this remarkable change in the obesity pattern among Egyptian women shows that women with higher education levels were more likely to be obese in 1992, but that this trend was reversed in 2014 (figure 2.22). Whereas in the early 1990s obesity was more problematic for richer than for poorer households, by 2014 obesity was largely a problem of both the rich and the poor. As shown in figure 2.23, women from rich households were more likely to be obese in 1995; the prevalence of obesity was only 6.4 percent among the poorest but 38.2 percent among the richest. The large difference in obesity prevalence between the poorest and richest disappeared in 2014 when obesity became an epidemic across all wealth levels. Coexisting undernutrition and overnutrition in Egyptian women A significant proportion of women in Egypt are both obese and anemic. EDHS 2014 reveals an overall obesity prevalence of 48.0 percent and an increasing FIGURE 2.21 Overweight and obesity prevalence among women who had a live birth in the five years preceding EDHS interview: Egypt, 1992–2014 50 45 Prevalence of overweight and obesity (%) 40 35 30 25 20 15 10 5 0 1992 1995 2000 2005 2008 2014 Rural obesity Rural overweight Urban overweight Urban obesity Sources: EDHS 1992, 1995, 2000, 2005, 2008, 2014 El-Zanaty et al. 1993, 1996; El-Zanaty and Way 2001, 2006, 2009; MOHP, El-Zanaty and Associates, and ICF International 2015). Note: EDHS = Egypt Demographic and Health Survey. 50 | Scaling Up Nutrition in the Arab Republic of Egypt FIGURE 2.22 Trends of obesity prevalence across education levels among women who had a live birth in the five years preceding EDHS interview: Egypt, 1992–2014 50 45 40 Prevalence of of obesity (%) 35 30 25 20 15 10 5 0 1992 1995 2000 2005 2008 2014 No education Secondary education Primary education Higher education Sources: EDHS 1992, 1995, 2000, 2005, 2008, 2014 (El-Zanaty et al. 1993, 1996; El-Zanaty and Way 2001, 2006, 2009; MOHP, El-Zanaty and Associates, and ICF International 2015). Note: EDHS = Egypt Demographic and Health Survey. FIGURE 2.23 Obesity prevalence and household wealth among women who had a live birth in the five years preceding the EDHS interview: Egypt, 1995–2014 50 45 40 Prevalence of obesity (%) 35 30 25 20 15 10 5 0 1995 2000 2005 2008 2014 Poorest Poorer Middle Richer Richest Sources: EDHS 1995, 2000, 2005, 2008, 2014 (El-Zanaty et al. 1996; El-Zanaty and Way 2001, 2006, 2009; MOHP, El-Zanaty and Associates, and ICF International 2015). Note: EDHS = Egypt Demographic and Health Survey. Overnutrition of Children Under 5 and Women of Reproductive Age in Egypt | 51 trend with age. The overall prevalence of anemia is 25.6 percent, with no clear difference across age groups (figure 2.24). Anemia is a common sign of malnutrition, whereas obesity is generally indicative of overnutrition. The coexistence of anemia and obesity is observed not only at population level, as shown in figure 2.24, but also within the same individual (figure 2.25). In 2000 more than 10 percent of women Egypt showed signs of both obesity and anemia, which is 16.5 ­percent in 2005 and 11.3 percent in 2014 (figure 2.25). Several studies from Ghana and Mexico have also reported the coexistence of anemia and obesity (Anderson 2017; Samper-Ternent, Michaels-Obregon, and Wong 2011). In 2014 women living in urban areas of Upper Egypt had a significantly higher likelihood of being obese and anemic at the same time compared with women living in other urban governorates. This finding is consistent with the EDHS data for children, indicating a double burden of malnutrition and overnutrition in urban Upper Egypt. These associations are likely due to a combination of the “obesogenic” environment in urban areas that is condu- cive to obesity and an overall low diet quality contributing to malnutrition because Upper Egypt is the poorest region in the country. In low- and middle-income countries, rapid urbanization has been linked to poor diet ­ and reduced physical activity (Angkurawaranon et al. 2014). In Mexico, liv- ing in urban areas has been associated with a higher probability of obesity and anemia within the same individuals (Samper-Ternent, Michaels- Obregon, and Wong 2011). In addition, in EDHS 2014 women who had their first birth before age 20 had a significantly higher likelihood of obesity with or without anemia, compared with women who had their first birth between 21 and 25 years of age. FIGURE 2.24 Coexistence of anemia and obesity by age among women: Egypt, 2014 80 70 60 Prevalence of obesity (%) 50 40 30 20 10 0 15–20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 Age Obesity Anemia Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). 52 | Scaling Up Nutrition in the Arab Republic of Egypt FIGURE 2.25 Coexistence of anemia and obesity among women: Egypt, 2000, 2005, 2014 100 90 30.2 80 37.3 41.3 70 60 22.5 Percent 14.3 50 16.8 11.3 40 16.5 10.4 30 20 37.1 31.5 30.8 10 0 2000 2005 2014 Obesity without anemia Obesity with anemia Anemia without obesity Neither Sources: EDHS 2000, 2005, 2008 (El-Zanaty and Way 2001, 2006, 2009). CONCLUSIONS In addition to malnutrition, both chronic (stunting) and acute (wasting), over- weight remain at elevated levels of public health significance in Egypt, and, like- wise, is at levels higher than those found for most of Egypt’s regional counterparts and the Middle East and North Africa regional average. In Egyptian children under 5, the prevalence of overweight (including obe- sity) and the proportion of overweight children with stunting have increased over the last few decades. The coexistence of undernutrition and overweight poses a challenge for both obesity and undernutrition intervention programs in Egypt. Based on EDHS data and the literature, maternal obesity is a critical fac- tor in the development of childhood obesity. Furthermore, in Egypt diet quality is heavily influenced by long-standing food subsidy policies. The GoE’s subsidy of energy-dense foods may have resulted in the overconsumption of calories among Egyptians, especially in poor and rural populations. The prevalence of obesity and overweight among women is alarmingly high across all wealth groups and education levels in Egypt and has increased signifi- cantly over time. Prevention of obesity and its related chronic diseases should be a top priority for national health policy and the Egyptian health care system. The time period of pregnancy and childbirth is an important window for the preven- tion of maternal obesity. Sedentary lifestyles and a lack of physical activity, highly prevalent in Egypt and other countries in the Middle East (Musaiger, Hassan, and Obeid 2011), are problematic, as is the consumption of energy-dense foods, particularly by poorer and rural populations. 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However, currently in Egypt there are gaps in coverage of many key interventions, resulting in suboptimal nutritional status among infants and young children (Bhutta et al. 2013). • The only nutrition-specific intervention that can be considered at scale is uni- versal salt iodization. • There are also a wide range of interventions across sectors—agriculture, social protection, early childhood development, child education, and water, sanitation, and hygiene (WASH)—which either are or have the potential to be nutrition-sensitive. However, many do not focus on nutrition outcomes, and only WASH interventions have demonstrated nutrition impacts. The recent revisions of the Takaful conditional cash transfer show promise, but further evaluation is required. • Based on the review of the status of key nutrition interventions in Egypt, it is recommended that 16 interventions in the areas of infant and young child feeding (IYCF), micronutrient, disease prevention and management, and WASH are scaled up (see table 3.10). • A number of approaches are identified to scale up the identified interven- tions, including (1) scaling up to full national coverage, (2) scaling up by region, and (3) scaling up by prioritizing interventions. Considerations of the approach taken should include potential nutritional impact, cost, and capac- ity to implement, among others. • Key elements identified for successful scaling up of the identified interven- tions include strengthening the health system (because most of the interven- tions identified are implemented primarily through the health system) and the multisectoral involvement of ministries and partners to support implementation.  57 58 | Scaling Up Nutrition in the Arab Republic of Egypt INTRODUCTION This chapter focuses on the status, challenges, and the responses needed in Egypt to implement or scale up interventions considered most critical to posi- tively affecting the 1,000 days from a child’s conception to second birthday. This includes 10 high-impact interventions that have already proven to be effective in similar settings, along with key WASH interventions. The chapter also reviews any programs in other sectors (agriculture, social protection, early child development, and education) that are currently supporting or have the potential to support nutrition goals and assesses the challenges and next steps. The chapter begins with an overview of the current nutrition-specific and nutrition-sensitive interventions being implemented in Egypt with the aim of identifying critical gaps and opportunities for further investment. Based on these findings, it then discusses the key policy and program options (multisec- toral) that could be considered for scale-up to address the prevailing and emerg- ing problems of malnutrition in the Egyptian context, as well as the potential approaches to scaling up the identified interventions. The government of Egypt (GoE) is committed to improving the health and nutrition status of the people of Egypt, paying special attention to this critical 1,000-day window. Thus this anal- ysis of scale-up options will support the GoE’s commitment to action. Stunting is one of the pressing challenges faced by Egyptians, and the impli- cation of this problem on individuals, families, and the development of the entire nation is well established. However, no “standardized” package of large-scale nutrition interventions has been proven to combat stunting because the causes of stunting are likely to differ from one situation to the next and are also likely to change over time. The 2013 Lancet series on maternal and child nutrition (Lancet 2013) devel- oped a new model intended to point the way to optimum fetal and child growth and development. Within this framework, it introduced two concepts. Nutrition- specific interventions and programs would address the immediate determinants of fetal and child nutrition and development—adequate food and nutrient intake, feeding, caregiving and parenting practices (such as hygiene and psychosocial and emotional support), and low burden of infectious diseases. Nutrition- sensitive interventions and programs would address the underlying determinants of fetal and child nutrition and development—food security; adequate caregiving resources at the maternal, household, and community levels; and access to health services and a safe and hygienic environment—as well as incorporate spe- cific nutrition goals and interventions. Nutrition-sensitive programs can also serve as delivery platforms for nutrition-specific interventions, potentially increasing their scale, coverage, and effectiveness. The same Lancet series identified 10 evidence-based, nutrition-specific interventions that would be the most effective for addressing undernutrition and micronutrient deficiencies in women of reproductive age, pregnant women, neonates, infants, and children (Bhutta et al. 2013). Although less evi- dence is available on the impact of nutrition-sensitive interventions and pro- grams than on nutrition-specific ones, a number of sectors have the potential to contribute to reaching nutrition goals. The Lancet series concludes that nutrition-sensitive programs hold great promise for supporting nutrition improvements and boosting the scale, coverage, and benefits of nutrition-­ specific interventions, including in agriculture, social protection, early child Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 59 BOX 3.1 Why 1,000 days? • Both the 2008 and 2013 Lancet nutrition series • When mothers and children receive the right (Lancet 2008, 2013) called for focusing on nutrition during this period, the foundation pregnancy and the first two years of life—the is laid for a child’s stronger physical growth, crucial 1,000 days—­ recognizing that this period higher learning capacity, improved performance is the most critical for the physical and cognitive in school, lower susceptibility to disease, and development of children. The majority of the higher lifetime earning potential. Thus this linear growth deficits that make up the under-5 period has a positive impact not only on the lives stunting burden are accumulated during of individual children, but also on the health and this time, reflecting nutritional deficiencies prosperity of a nation. (Victora et al. 2010). • Key interventions include integrated • This 1,000-day period offers a unique window maternal and newborn care, implementation of opportunity to ensure that a child has the best of a comprehensive infant and young possible start in life by providing the mother ­ child feeding strategy, prevention and and the child with the right nutrition, thereby treatment of micronutrient deficiencies (iron helping the child to grow, secure development of supplementation, vitamin A supplementation, critical mental and physiological faculties, learn, and salt iodization), prevention and treatment and thrive. A growing body of scientific evidence of severe acute malnutrition, improving water, shows that the foundations of a person’s lifelong sanitation, and hygiene, and expanding access to health are largely set during this 1,000-day and use of health services. window. development, and education (Ruel and Alderman 2013). For example, there is a growing body of evidence on how improving water, sanitation, and hygiene (WASH) can promote healthy environments, reduce the work burden of women, and reduce the prevalence of infectious diseases, thereby having an impact on nutrition status (USAID 2015). The 2008 Lancet maternal and child undernutrition series (Lancet 2008) called for focusing on the 1,000 days from a child’s conception to second birth- day, and the 2013 series on maternal and child nutrition reinforced this approach (box 3.1). This approach is directed at the key nutrition interventions that can ensure the nutritional status of a woman at conception, during pregnancy, and through the first two years of a child’s life so that a child has every opportunity to grow and thrive. However, interventions implemented during other time frames are likely to carry over to this 1,000-day period. Indeed, the positive impact of proper nutrition on other age groups, such as adolescent girls, will likely positively affect their children during these critical 1,000 days. NUTRITION-SPECIFIC INTERVENTIONS Nutrition-specific interventions include treatment of acute forms of malnu- trition and also target the immediate causes of undernutrition: inadequate dietary intake and ill health. The next section discusses the existing nutri- tion-specific interventions and gaps in Egypt in three categories that reflect 60 | Scaling Up Nutrition in the Arab Republic of Egypt the key focus areas and target groups for nutrition-specific interventions: (1) newborn, infant, and young child nutrition interventions; (2) maternal nutrition and adolescent interventions; and (3) cross-cutting interventions: national food fortification. Newborn, infant, and young child nutrition interventions The newborn, infant, and young child nutrition interventions discussed in this section target the immediate factors affecting suboptimal growth and development, with a focus on the 1,000 days from conception to second birthday (Black et al. 2013). Interventions are framed within a life cycle approach, recognizing that nutrition interventions at each life stage can affect the 1,000 days and beyond. Specifically, this section describes (1) infant and young child feeding interventions, (2) growth monitoring and promotion (GMP), (3) micronutrient supplementation in young children, (4) integrated management of acute malnutrition (IMAM), and (5) deworming. Infant and young child feeding (IYCF) Optimal infant and young child feeding (IYCF) interventions have the great- est potential to singlehandedly influence child survival (UNICEF 2011). The Lancet maternal and child undernutrition series estimated that optimal IYCF practices, especially exclusive breastfeeding, could prevent up to 1.4 ­ million deaths a year among children under 5 out of the approximately 10 million deaths a year (Black et al. 2008). Furthermore, optimal IYCF ensures that a child is protected from both under- and overnutrition and their consequences later in life, and breastfed infants have a lower risk of several chronic condi- tions later in life such as diabetes and heart disease (Horta, Loret de Mola, and Victora 2015; Peters et al. 2016). The IYCF practices recommended by the World Health Organization and UNICEF call for early initiation and exclusive breastfeeding for six months and for continued breastfeeding, together with nutritionally adequate, safe, age-appropriate, complementary feeding, from six months to two years (WHO and UNICEF 2003). Adherence to these guidelines can result in optimal nutrition in the first two years of life, and they are crucial to prevent stunting in infancy and early childhood and breaking the intergenerational cycle of undernutrition. Breastfeeding is also an important factor in preventing childhood obesity. A longer duration of breastfeeding is associated with a lower risk of childhood obesity in a dose-­ response manner (Yan et al. 2014). In Egypt, IYCF interventions primarily center on social and behavioral change communication (SBCC) in the primary health care (PHC) system, and the government is committed to strengthening these interventions. Although breastfeeding is common in Egypt, exclusive breastfeeding is not very common; almost a third of infants are bottle-fed or consume complementary foods and liquids before reaching 6 months of age. Timely introduction of complementary foods is relatively high, but the proportion of children fed the minimum number of times and with a nutritionally diverse diet is generally very low (see chapter 1). Thus the GoE and its partners have shown a commitment to updating the messages, tools, and overall communications approaches to strengthen the ­ counseling skills of PHC workers related to breastfeeding and complementary feeding practices. Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 61 In 2014 the Ministry of Health and Population (MOHP) began implementing the National Breastfeeding Program and the Baby Friendly Hospital Initiative (BFHI), based on the 2009 WHO and UNICEF BFHI guidelines (WHO and UNICEF 2009), in both the public and private sector. The MOHP is working with all partners to advocate and scale up the national BFHI program, integrat- ing the BFHI guidelines into national policies and strategies. The goal of the National Breastfeeding Program and the BFHI is to strengthen the implementa- tion of practices that protect, promote, and support breastfeeding (WHO and UNICEF 2009) and improve complementary feeding within the context of the IYCF strategy. In the model introduced by the MOHP, five PHC units and a hos- pital within the same catchment area provide pregnant women and lactating mothers with counseling services, while ensuring that they are referred to a baby-friendly hospital within their reach. Under the umbrella of the BFHI program, the MOHP has developed updated national IYCF counseling guidelines targeting frontline health care workers, including community health workers, as well as nongovernmental organizations (NGOs). This counseling package provides standardized guidelines for nutrition during preconception, pregnancy, lactation, and complementary feeding. The aim is to strengthen the capacity of medical doctors, nurses, and community health workers within PHC facilities to deliver nutrition counseling to pregnant women and mothers of children 0–24 months of age visiting PHC units. A co-branded IYCF and early child- hood development (ECD) audiovisual package was produced by UNICEF, the World Food Programme (WFP), and the MOHP for this purpose. The BFHI faces many challenges, as reported nationally, and through other Eastern Mediterranean country experiences. The successful implementa- tion of the BFHI is contingent on addressing the existing national chal- lenges and evaluating the experiences of these countries (Al-Jawaldeh and Abul-Fadl 2018; WHO 2017a). The National Breastfeeding Program and the BFHI can be strengthened in several ways moving forward. This includes expanding the BFHI within the ongoing social health insurance program where quality services are pro- vided to mothers attending PHC units, as well as continually strengthening the counseling skills of PHC workers. Strengthening the policy framework supporting implementation of the code of marketing of breast milk substi- tutes is key to the sustainability of breastfeeding support at the national level. Target groups should extend beyond mothers and caregivers to include fathers, grandmothers, mothers-in-law, and the community at large. The presence of numerous harmonized delivery channels would be an advantage by reinforcing messages during immunization, treatment of diarrhea, and family planning services, and not solely through pre- and postnatal care visits. In addition, breastfeeding should be promoted through every possible com- munication and education channel in order to encourage mothers to adopt proper breastfeeding practices and reverse the present negative trends. Enforcement of the code of marketing of breast milk substitutes is another critical part of this approach. In addition, for complementary feeding SBCC it is important to include WASH messages, mainly relating to the hygienic preparation of complementary foods and hand washing by mothers and caregivers. 62 | Scaling Up Nutrition in the Arab Republic of Egypt To address the double burden of undernutrition and overweight in children at the community and individual levels, promotion of dietary diversity through reducing the consumption of energy-dense, micronutrient-poor foods and increasing the consumption of fruits, vegetables, and other healthy foods should be encouraged. According to Egypt’s Central Agency for Public Mobilization and Statistics (CAPMAS), households living in poverty represent more than one-quarter of the population (27.8 percent), mostly concentrated in Upper Egypt (and almost 60 percent in the governorates of Asyut and Sohag). In these settings, advice on adequate and proper complementary feeding prac- tices and diverse diets may not be practical or sufficient. These families may need additional assistance to prevent chronic undernutrition as well as over- nutrition in their offspring. Providing nutrient-dense complementary foods for such families to enhance complementary feeding could help ensure that these children receive adequate nutrition. Moreover, because diet quality is heavily influenced by long-standing food subsidy policies, particularly among poorer households, it will be important for nutritionally diverse commodities to be included in the scheme. Ready-to-use foods could be provided as part of the food ration cards for families with children under 5 who are at a high risk of malnutrition. Such approaches, however, could be considered in the design of future social protection programs as they do not seem warranted as a nation- wide intervention. Finally, development of a national IYCF social and behavioral change com- munication strategy would allow more efficient coordination and evaluation of the efficacy of efforts, whether among private, public, and NGO sectors or differ- ent donor agencies. And it would bring together the different stakeholders work- ing particularly on IYCF promotion. Table 3.1 summarizes the proposed breastfeeding and complementary feeding practice interventions. Growth monitoring and promotion Growth monitoring and promotion (GMP) is an important intervention for detecting cases of growth faltering as early as possible and is particularly import- ant to help combat Egypt’s alarming stunting and obesity trends.1 GMP sessions also give parents an opportunity to understand their child’s development and TABLE 3.1  Proposed breastfeeding support and complementary feeding practice interventions INTERVENTION TARGET BENEFICIARY DELIVERY CHANNELS KEY PLAYERSa PARTNERSb Promotion and Mothers of children Health units, health centers, Ministry of Health and UN agencies, national and support of 0–23 months public hospitals, community Population: primary health international NGOs breastfeeding nutrition programs, midwives care and family planning (dayaas), mass mediac departments, National Population Council, Motherhood and Childhood Council Promotion of Mothers of children Health units, health centers, Ministry of Health and UN agencies, national and appropriate 0–23 months public hospitals, community Population: primary health international NGOs complementary nutrition programs, mass care department, feeding practices mediac Motherhood and Childhood Council a. The key players listed are key state players. b. Partners are UN agencies, nongovernmental organizations (NGOs), civil society organizations (CSOs), and the private sector. Such organizations should be involved in each of the interventions, giving appropriate consideration to interventions relevant to their mandate/vision. c. Mass media are included as a delivery channel for interventions that involve behavior change communication. However, all other interventions should have some media outlet to promote awareness. Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 63 can act as an entry point for discussions about changes in behavior to improve child growth, as well as for other nutrition-relevant interventions such as deworming or vitamin A and iron supplementation. In Egypt, GMP is a component of the regular maternal and child health (MCH) well-baby clinic checkup of children during their first years of life. Within health facilities, GMP refers to anthropometric measurement of children to screen malnourished cases, including stunting, wasting, underweight, over- weight, and obesity. Data are then plotted against standardized WHO growth curves, and malnourished cases are identified if there is a significant deviation from the median of the population. Once such cases are identified, a nutrition counselor provides counseling support to mothers, and follow-up visits are scheduled. The routine immunization clinic visits provide a good opportunity to combine health checkups and treatments with nutrition assessments (GMP and hemoglobin screening). It also is an opportunity for the mother to receive nutri- tion counseling suggesting that children receive specific interventions such as vitamin A and iron (prophylactic and treatment) supplementation. The current system is facing a number of challenges. First, GMP is just one of the components of the regular well-baby clinic visits, which means it may not be a priority during such visits. Second, the large number of children at a clinic for other routine purposes and pressing health challenges (often acute medical ­ conditions) require attention, which means less time is available for careful measurements, discussions, and counseling (UNICEF, MOHP, and USAID 2017). Third, there are currently no standardized protocols for refer- ral of severe cases of malnutrition, often referrals are informal and nonsys- tematic, and children are monitored within the PHC units in parallel. This situation arises in part from lack of capacity at the peripheral level to manage severe cases of malnutrition. As a result, many cases of severe acute malnu- trition may either be missed or, if picked up, not be referred for proper treatment. The MOHP is committed, as part of implementing the first 1,000-day model within PHC facilities, to systematically strengthening GMP guidelines and related approaches. These include (1) regular assessments during routine child visits (accurate measurement of birthweight as well as the weight and length/ height of children after birth up to 5 years of age); (2) responding to early signs of under- or overnutrition through education, counseling of individual mothers and fathers, and referrals and other actions in case child growth continues to falter; (3) training health care workers in monitoring the growth and develop- ment of children; and (4) systematic monitoring, feedback, and evaluation of the GMP system at the PHC unit, district, governorate, and central level, including on the quality of anthropometric measurements. The initial focus of these and other selected efforts is within the specially dedicated MOHP “1,000-day trial” to establish the operational procedures and costs for a nationwide scaling up of the improved Standardized Protocol of Action for Nutrition Services (SPANS) to be provided by all government and private PHC/MCH units (see the case study later in this chapter on strengthening the integrated nutrition package at the primary health care level). Recently, the MOHP increased the number of routine well-baby clinic vis- its in the second year of life, thereby providing more opportunities to identify and address cases of malnutrition before the age of 2. Until recently, regular MCH well-baby clinic visits in Egypt normally take place at the scheduled immunization visits at 2, 4, 6, 9, 12, 15, and 18 months of age. However, two 64 | Scaling Up Nutrition in the Arab Republic of Egypt more visits have been added at 21 and 24 months, which altogether provide an excellent opportunity to detect, monitor, and address any malnutrition prob- lems (including overweight) throughout early childhood and to link up the MCH health and nutrition monitoring and interventions with early childhood development such as including psychomotor, psychosocial, and cognitive assessments in these periodic clinic visits (see the section on child protection later in this chapter). The MOHP has updated the GMP and early childhood development capacity building package for health care workers, including the ECD component of child monitoring health cards, to strengthen the capacity of PHC workers to detect any deviation of child growth and development within a child’s first two years. Table 3.2 summarizes the GMP intervention just described. Micronutrient supplementation in young children Micronutrient deficiencies often result in “hidden hunger,” which may occur despite a diet with adequate calories. Micronutrient deficiencies are especially worrisome in infants and children because of the critical role micronutrients play in early growth and development. Vitamin A, iron, iodine, and zinc are the most prominent of these micronutrients and the target of many interventions based on evidence of prevailing deficiencies and the important role they play in health and disease. Vitamin A supplementation. Vitamin A is essential for the functioning of the immune system and the healthy growth and development of children. Vitamin A deficiency could lead to visual impairment, illness, and also death. WHO (2011b) recommends that vitamin A supplements be given every four to six months to children 6–59 months of age in areas where vitamin A deficiency is seen as a public health problem. It is an inexpensive, quick, and effective way to improve vitamin A status and reduce child morbidity and mortality in the long term. Egypt’s vitamin A supplementation program is integrated into the Expanded Program on Immunization in PHC facilities. However, the existing implementa- tion is ineffective and inconsistent. WHO guidelines (WHO 2011b) recommend that children 6–59 months of age be given a first dose of vitamin A of 100,000 international units (IU) between six and 11 months, followed by a dose of 200,000 IU every four to six months between the age of 12 and 59 months. In Egypt, the first dose (100,000 IU) of vitamin A supplementation is received with the mea- sles vaccine at 9 months of age, and the second is given with the activated polio booster at 18 months of age (200,000 IU). Coupling supplementation with the immunization program increases the likelihood of reaching a greater number of children at these times regardless of location, education, wealth quintiles, and other sociodemographic variables that normally determine whether one seeks TABLE 3.2  Proposed growth monitoring and promotion interventions INTERVENTION TARGET BENEFICIARY DELIVERY CHANNELS KEY PLAYERS PARTNERS Growth monitoring Infants and children Health units, health centers, Ministry of Health and UN agencies, national and promotion 0–59 months public hospital outpatient clinics, Population: and international community nutrition programs, Noncommunicable disease nongovernmental preschools and primary health care organizations departments, National Nutrition Institute Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 65 public versus private health care (because a majority complete the child vacci- nation schedule in the free state-run health services). The nine-month gap between doses is not in line with the WHO guidelines, and further opportunities for distribution of vitamin A to children up to the age of 5 are limited at best. These shortcomings are reflected in the 2014 Egypt Demographic and Health Survey (EDHS) data (MOHP, El-Zanaty and Associates, and ICF International 2015), which shows that vitamin A supplementation is only at 16.7 percent for children 6–59 months of age. EDHS 2014 data for the age group 18–23 months, who would have received the second dose of vitamin A at 18 months of age, reveals the coverage to be 81.6 percent. Furthermore, the Nutrition Stakeholder and Action Mapping Report issued in 2017 found coverage to be >75 percent for vitamin A supplementation among children under 2 (MOHP and UNICEF 2017a). The recent addition of well-baby clinic visits at 21 and 24 months of age, cou- pled with the regular MCH clinic visits at 36, 48 and 60 months, creates further opportunities to provide additional doses of 200,000 IU at 24, 36, 48 and 60 months. Even with this new schedule, however, the provision of vitamin A would be too far apart after age 2 according to the current international recom- mendations (WHO 2011b), but it would be a step in the right direction. As a first step, a needs assessment and review of the current recommendations by the Micronutrient Committee of the MOHP, which is coordinated by the National Nutrition Institute (NNI), would be needed to evaluate the best way forward. It would also be beneficial to carry out a full review of procurement, supply, and training needs, as well as costs, in order to assess whether this would be the best use of the resources required. Such a review should include a bottleneck analysis to understand what is currently limiting coverage for the age groups that cur- rently receive vitamin A supplementation. Together, these assessments could inform the planning process moving forward. Table 3.3 summarizes the pro- posed vitamin A intervention for children. Iron supplementation. Iron is an essential nutrient for growth and development. Lack of iron, caused by a low intake of iron-rich foods or an infection with intestinal helminths, can lead to anemia. The economic costs of iron-deficiency anemia from annual physical productivity losses have been calculated to be about $2.32 per capita, or 0.57 percent of the gross domestic product (GDP) in low- and middle-income countries (Horton and Ross 2003). The 2011 WHO Guidelines for Intermittent Iron Supplementation for Preschool and School-Age Children recommend that in settings where the prevalence of anemia in preschool or school-age children is 20 percent or higher, intermittent use of iron supplements be adopted as a public health intervention to improve iron status and reduce the risk of anemia among children (WHO 2011a). TABLE 3.3  Proposed vitamin A intervention for children INTERVENTION TARGET BENEFICIARY DELIVERY CHANNELS KEY PLAYERS PARTNERS Vitamin A Children 6–59 months Health units, health centers during Ministry of Health and UN agencies supplementation immunization days and regular MCH Population: primary health care clinic visits, public hospitals, department, Motherhood and community nutrition programs Childhood Council Note: MCH = maternal and child health. 66 | Scaling Up Nutrition in the Arab Republic of Egypt The PHC system of the MOHP currently has in place an iron supplementa- tion program for children 6–23 months of age, and it follows the WHO 2011 guidelines. These guidelines recommend 25 milligrams of elemental iron syrup or drops every week for three months, followed by a three-month gap, and then repeated until the child is 5 years old (WHO 2011a). WHO released new guide- lines in 2016 that focus on daily iron supplementation in infants and children. These guidelines recommend daily iron supplementation in infants and young children 6–23 months of age and preschool-age children 24–59 months living in settings where anemia prevalence is greater than 40 percent. Because the cur- rent prevalence rate in Egypt is 27 percent among children 6–59 months of age (EDHS 2014), the current protocols can continue, although these protocols may need to be updated if the prevalence rate rises again above 40 percent. Currently, efforts to provide this age group with iron supplementation are insufficient because only 10 percent of infants 6–8 months and 6 percent of chil- dren 48–59 months were given iron supplementation in the week prior to the EDHS 2014 survey. The situation is exacerbated by the suboptimal consumption of iron-rich foods, especially by infants 6–8 months of age (EDHS 2014). A con- tributing factor may also be the increasing cost of animal source foods, recogniz- ing that heme-bound iron has much higher bioavailability than other sources of iron (López and Martos 2004). Increasing the coverage of iron supplementation through the MCH clinic vis- its will be critical to the success of this intervention. However, another mecha- nism would be required to continue supplementation of children 24–59 months of age because the MCH clinic visits are only yearly from 2 years of age and up. Continuation will, however, require investments in retraining, supplies, and monitoring and reporting. In addition, services provided for v ­ ulnerable popula- tions through the social safety net programs by the Ministry of Social Solidarity (MOSS) could present an opportunity to reach vulnerable populations such as through food ration cards and conditional cash transfers. It will also be critical to ensure that iron supplementation is continued as part of an integrated program. This program would include management and preven- tion of anemia during pregnancy, promotion of adequate weight gain, hand washing, SBCC to increase diet diversity and knowledge of food combinations that increase iron absorption, control of parasitic infections, and appropriate for- tification of complementary foods with iron and other micronutrient powders (see box 3.2). The barrier to optimal coverage has sometimes been lack of under- standing of potential benefits, and so education should be emphasized through nationwide campaigns (De-Regil et al. 2011). In addition, a clear referral system for the management of clinically diagnosed anemic children should be put in place. A cheap, fast, “field-friendly” method for measuring hemoglobin in remote and rural health settings could further facilitate diagnosis of anemic children for treatment. Table 3.4 summarizes the proposed iron intervention for children. TABLE 3.4  Proposed iron intervention for children INTERVENTION TARGET BENEFICIARY DELIVERY CHANNELS KEY PLAYERS PARTNERS Iron supplementation Children 6–59 months Health units, health Ministry of Health and Population, UN agencies (weekly) centers, public hospitals, Ministry of Social Solidarity cash transfer programs Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 67 BOX 3.2 Common challenges in micronutrient supplementation programs in Egypt Significant challenges face each of the supplementa- micronutrient deficiency control in Egypt. That said, tion programs in Egypt. A well-defined and updated there is also a need to ensure that the available infor- strategy for micronutrient supplementation does not mation is used as effectively as possible in decision exist in part because of the lack of efforts to review, making. update, and monitor all relevant micronutrient control Although investments are needed in infrastructure strategies (including coordinating actions with food and materials for screening of micronutrient deficien- fortification, public nutrition education, and food sub- cies, particularly for iron deficiency (hemoglobin sidies and regulations). This lack partly stems in turn screening) and in training of key personnel to ensure from a lack of overall awareness of the importance of improved implementation of key micronutrient inter- prioritizing a range of micronutrient interventions. ventions at scale, there is generally a lack of funding Attention should be paid as well to the current available. The MOHP and UNICEF, as part of the first challenges in implementing key micronutrient inter- 1,000 days model, have developed tools to improve the ventions such as vitamin A and iron in order to improve efficiency of the existing micronutrient supply chain coverage and efficiency. The lack of a needs assess- system, including assessment and monitoring tools, ment and monitoring capacity, along with a weak sup- capacity-building packages for health care workers, ply chain and the questionable quality of data captured and data monitoring. However, sufficient funding in the health information system, hinder accurate will be required to fully implement this approach planning, implementation, and monitoring of successfully. Integrated management of acute malnutrition Severe acute malnutrition (SAM) is a major cause of death in children under 5, either directly because their nutritional needs are not being met or indirectly because of the elevated risk of death from common childhood illnesses such as diarrhea, pneumonia, and malaria (WHO, UNICEF, and WFP 2014). The many potential causes could include poverty, lack of food, repeated illnesses, inappro- priate feeding practices, lack of care, and poor hygiene. Children with SAM need urgent life-saving treatment in order to survive. Children with moderate acute malnutrition (MAM) have an increased risk of mortality, and if not treated, they run the risk of progressing toward SAM. Until relatively recently, children diag- nosed with SAM were only treated in hospitals where they received therapeutic feeding along with medical care. Many more were never reached or lacked access to health facilities. However, with the recent availability of ready-to-use therapeutic food (RUTF) much of the treatment can be provided outside of the hospital system. IMAM is an integrated approach to tackling malnutrition that targets chil- dren 6–59 months of age. The approach creates maximum coverage and access by not only relying on inpatient care for treatment (SAM with complications), but also introducing outpatient care (SAM without complications) and decen- tralization of services down to the community level. As a result, a far higher number of children with SAM or MAM can potentially be identified through community outreach, referred, and then treated, with the defaulter rate and number of relapse cases declining because of the continued monitoring in the community. 68 | Scaling Up Nutrition in the Arab Republic of Egypt In Egypt, the MOHP, using the WHO guidelines (WHO 2005) for integrated management of childhood illnesses (IMCI), developed its own integrated IMCI package. However, it currently lacks specific protocols for the effective manage- ment of malnutrition. The IMCI strategy is a simple, effective approach geared toward outpatient clinical settings with limited resources. In these settings, health care providers can deliver appropriate treatments for the major illnesses, counsel caretakers, and refer severer cases that warrant care at a more fully equipped health care facility. Severe acute malnutrition and anemia are an inte- gral part of identifying dangerous conditions requiring urgent care and hospital- ization, follow-up, and nutrition counseling (WHO 2013b). Despite this, the effective treatment of malnutrition—especially in its severer and more complex forms (that is, linked to other forms of infections and medi- cal conditions)—remains inadequate. The treatment of malnourished children at home, and from health staff and community health workers (CHWs) at the PHC unit level, as well as at referral hospitals at the district and governorate level, is currently not taking place at scale. Despite the fact that Egypt has a comparatively well-established system of hospitals with pediatric departments down to district level, very few referred cases of SAM or severe pediatric ane- mia have been recorded. The recent Nutrition Stakeholder and Action Mapping Report concluded that treatment of SAM (and MAM) is simply “not done” (MOHP and UNICEF 2017a). The capacity constraints of facilities and staff and weaknesses in referral sys- tems may help explain the prevailing problems. As was observed for neonatal risk cases in the integrated perinatal health and nutrition (IPHN) review, the links between the health sector hospital and preventive services are not working well, and referrals are thus often left to the individual parents to pursue and with costs they may not be able to meet (UNICEF, MOHP, and USAID 2017). The capacity of pediatric referral departments to provide the SAM/MAM and severe anemia treatment needs to be assessed and the costs for establishing or strengthening these services elucidated. Because of the level of wasting in Egypt (8 percent), it is proposed that an IMAM program be established to develop the capacity needed for effective treatment of malnutrition. This national program should follow the standard WHO guidelines for the treatment of SAM (WHO 2013b) and include inpatient and outpatient therapeutic feeding programs, as well as treatment of MAM in supplementary feeding programs. Community outreach is a further critical com- ponent needed to harness community involvement to support the early detec- tion and referral of cases. Table 3.5 summarizes the proposed treatment of MAM and SAM. Zinc Diarrhea is a leading cause of death globally among children under 5. It contrib- utes to nutritional deficiencies, reduced resistance to infections, and impaired TABLE 3.5  Proposed treatment of moderate acute malnutrition and severe acute malnutrition INTERVENTION TARGET BENEFICIARY DELIVERY CHANNELS KEY PLAYERS PARTNERS Treatment of MAM Children 6–59 months Health units, health centers, Ministry of Health and UN agencies, national and and SAM public hospital outpatient clinics Population: preventive international and hospital services nongovernmental divisions organizations Note: MAM = moderate acute malnutrition; SAM = severe acute malnutrition. Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 69 growth and development. Zinc supplementation has been shown to reduce the duration and severity of diarrhea and to prevent subsequent episodes. It is also important for supporting growth. A systematic review and meta-analysis of available studies globally have shown that among zinc-treated children there is a 26 percent (95 percent confidence interval: 20−32 percent) reduction in the estimated relative risk of diarrhea lasting beyond three days (Lamberti et al. 2013). Since 2004, WHO and UNICEF have recommended adding zinc to the standard oral rehydration solution (ORS) therapy for infants and children with diarrhea. The current treatment protocol for diarrhea is continued feeding, adequate hydration, and 10–14 days of zinc supplementation—that is, 10 milli- ­ grams for infants less than 6  months; 20 milligrams otherwise (WHO and UNICEF 2004). In Egypt, zinc powder is either incorporated into the ORS sachet or given as a separate tablet in a 10- to 14-day course for children. Accurate estimation of zinc supplementation coverage is therefore challenging and remains suboptimal because only 30 percent of children with diarrhea receive some form of ORS therapy and a meager 1.7 percent receive zinc supplementation (EDHS 2014). Increasing the number of cases of diarrhea treated with ORS and zinc will require market-based availability (pharmacies) and education of pharmacists and other health care workers because only a fraction of the population seeks care in state-run facilities beyond vaccination. Furthermore, unifying the prod- uct for delivery of ORS with zinc so that it easier to administer will make it a more attractive option. Finally, ensuring that the general population under- stands the potential benefits of zinc through the efforts of health workers, phar- macists, nurses, and other health personnel will be crucial to creating demand and improving coverage. Table 3.6 summarizes the proposed treatment of diar- rhea with zinc. Deworming When not treated, parasitic infections contribute to suboptimal nutritional status through increased nutrient losses (through blood loss and diarrhea), mal- ­ absorption, decreased intake (due to loss of appetite) and increased need (due to fever). To reduce the worm burden of soil-transmitted helminth infection, WHO guidelines recommend that annual or biannual single-dose albendazole (400 milligrams) or mebendazole (500 milligrams) be given to all preschool children 1–4 years of age and to school-age children 5–12 years of age living in ­ areas where the baseline prevalence of any soil-transmitted infection is percent or more among children (WHO 2017b). 20 ­ For some time, Egypt has had a successful National Bilharziasis Elimination Program (NBEP) in which deworming medication for schistosomiasis and hel- minth infections is provided at the PHC level. This program has reduced infec- tion rates to historic lows, currently at 0.2 percent, partly because of an ongoing program for mass deworming treatment in primary schools targeting children TABLE 3.6  Proposed treatment of diarrhea with zinc INTERVENTION TARGET BENEFICIARY DELIVERY CHANNELS KEY PLAYERS PARTNERS Therapeutic zinc Children 6–59 months Health units, health Ministry of Health and UN agencies supplementation for the centers, general service Population: primary health care management of diarrhea (with hospitals, pharmacies department, Motherhood and oral rehydration solution) Childhood Council 70 | Scaling Up Nutrition in the Arab Republic of Egypt 9–12 years of age and mass deworming in highly infected areas of the country, which are now few. The success of deworming efforts in Egypt highlights the importance of intra- and intersectoral efforts within a comprehensive national scale-up pro- gram that could be used as a model for other national scale-up program efforts. Effective collaboration was established between the primary health care and the endemic disease control departments within the MOHP, and the coopera- tion and coordination of the MOHP, Ministry of Water Resources and Irrigation (MOWRI), Ministry of Agriculture and Land Reclamation (MOALR), and oth- ers were secured to ensure success of the program. In addition, the national media campaigns that accompanied the program in the 1980s and 1990s to increase awareness on modes of disease transmission, methods of prevention, and treatment are considered some of the most successful national public health campaigns to date. Despite its current low prevalence, it is in the national interest to completely eliminate schistosomiasis, while eliminating other types of enteric parasite (­ helminth) infections. Presently, treatment for schistosomiasis is given only when diagnosed, unless prevalence is found to be greater than 3 percent in an identified area. In that case, mass treatment, snail control, and efforts to ensure clean water and sanitation are undertaken. Therefore, it is likely that many cases go unnoticed in areas where prevalence is less than 3 percent without mass screening. Annual or biannual administration of deworming drugs, particularly for preschool children, would help to eliminate cases of infection and its nega- tive impact on nutrition status. These annual/biannual campaigns can make use of existing delivery platforms such as preschools. Cooperation with MOSS could facilitate reaching the most vulnerable populations. Table 3.7 summarizes the proposed deworming interventions. Maternal nutrition and adolescent interventions Two maternal and adolescent nutrition interventions are described in this section: anemia control and prevention and obesity interventions. ­ Anemia control and prevention Pregnant women. Accessible, high-quality care before and during pregnancy, childbirth, and the postnatal period is important for the health of the mother and the development of the unborn baby. Antenatal care (ANC), by linking the expectant mother and her family with the formal health system, helps to ensure this continuum of care. ANC prepares pregnant women for birth and parenthood, manages health issues during pregnancy, and provides the appropriate information and advice needed for a healthy pregnancy, safe childbirth, and postnatal recovery. A key component of ANC is anemia detection, treatment, and control during pregnancy because it is associated with increased maternal and newborn complications, including maternal TABLE 3.7  Proposed deworming interventions INTERVENTION TARGET BENEFICIARY DELIVERY CHANNELS KEY PLAYERS PARTNERS Deworming Children 12–59 months Health units, health Ministry of Health and Population, UN agencies centers, preschools Ministry of Social Solidarity Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 71 mortality, low birthweight, and premature birth. WHO (2016a) recommends daily doses of 30–60 millligrams of iron and 400 micrograms of folic acid supplementation for 90 days during pregnancy to prevent maternal anemia, puerperal sepsis, low birthweight, and preterm birth (MOHP and UNICEF 2017b; Sanghvi, Harvey, and Wainright 2010). In Egypt, the proportion of pregnant women attending antenatal clinics is comparatively high, with over 80 percent attending a minimum of four times during pregnancy and being attended by a trained service provider as recom- mended by WHO (2016b). And yet, despite the high coverage, more than percent of newborn babies register low birthweight (less than 2.5 kilograms), 15 ­ an indicator of early stunting and inadequate nutrition-related support provided during the pregnancy. ANC services in Egypt are provided by the same public PHC/MCH service system that was described for infants and young children. However, a high proportion (80 percent) of pregnant women prefer to have their ANC checkups in private clinics or hospitals (EDHS 2014). Often, they are using a combination of both types of ANC service providers. Iron–folic acid supplementation is part of the ANC package provided for pregnant women as outlined in the WHO 2016 guidelines (WHO 2016a). Anemia treatment, prevention, and control efforts during pregnancy are hampered by challenges related to compliance and, according to EDHS 2014, only 36.1 percent of pregnant women took the full (90-day) supplementation during their last pregnancy. This finding highlights the gap between coverage and compliance, the latter often claimed to be the result of the side-effects of iron supplementa- tion (Milman et al. 2016). Promotion and strengthening of the health care package provided during ANC are key to improving coverage and compliance during pregnancy, and it has already been included in the updated SPANS developed by the MOHP (see case study later in this chapter). Expanding delivery channels to reach pregnant women through community health workers and home visits in remote and rural areas is another potential approach to improving coverage and compliance. This intervention should be viewed as well in the context of an extended package of prenatal care involving appropriate weight gain, behavior change communica- tion, along with a clear referral and management strategy for those clinically diagnosed with anemia. Adolescent girls In adolescent girls, menstrual blood losses, accompanied by rapid growth, make them highly vulnerable to iron deficiency, putting them at greater risk of illness and infection, fatigue, and a reduced capacity for physical work and negative outcomes in pregnancy. The WHO (2016a) recommends that adolescent girls take 30-60 milligrams of elemental iron for three consecutive months in every one-year period. The Ministry of Education (MOE), in collaboration with the School Health Program of the MOHP, has put in place a system to focus on anemia prevention in adolescent girls in secondary schools, although it is not clear how functional it is. This approach aims to initiate iron-folic acid (IFA) supplementation as the adoles- cent girls enter menarche, thereby aiming to prevent maternal anemia altogether (Aguayo, Paintal, and Singh 2013). Growing evidence is attesting to the potential of pre-pregnancy prevention of anemia to greatly improve the control of anemia during pregnancy. EDHS 2014 reports that 10.9 percent of adolescent girls 15–19 years of age have begun childbearing. Thus this potentially critical 72 | Scaling Up Nutrition in the Arab Republic of Egypt TABLE 3.8  Proposed iron–folic acid interventions INTERVENTION TARGET BENEFICIARY DELIVERY CHANNELS KEY PLAYERS PARTNERS Iron–folic acid Pregnant women Health units, Health centers, Ministry of Health and Population, UN agencies supplementation (daily) general service hospitals, Ministry of Education community nutrition programs, secondary schools, pharmacies intervention can be a part of a life cycle strategy that manages and prevents anemia in children and adolescent girls as well as pregnant women. However, it will be important to assess the current status and challenges of this program before con- sidering implementing it at scale. Table 3.8 summarizes the proposed iron–folic acid interventions. Obesity prevention and control interventions for women of reproductive age Dietary habits, food consumption patterns, and lack of physical activity all con- tribute to an increasing prevalence of overweight and obesity, particularly among poorer and rural populations in Egypt. As chapter 2 described, both obesity and overweight in women has increased significantly in Egypt, with more than a third of women overweight and almost half obese. It is a problem not only of the poor but also of the rich and across education levels. Obesity poses a heavy health and economic burden for both individuals and the society (Global BMI Mortality Collaboration 2016) because it is a major con- tributor to chronic diseases such as high cholesterol, diabetes, and heart disease and to premature death (Calle 2008; Hu 2008a, 2008b; Kim and Kawachi 2008). The cost of obesity-related health services, in combination with coexisting ane- mia, can lead to catastrophic spending in poor households or, even worse, may lead individuals to avoid care so they do not become impoverished. Thus the importance of combating obesity cannot be overstated. Combating obesity requires coordinated efforts from all stakeholders, includ- ing the GoE, industry, health care systems, schools, urban planners, the media, communities, and individuals (Hu, Liu, and Willett 2011; Kremers et al. 2010; Malik, Willett, and Hu 2013; Musaiger et al. 2011). Prevention and intervention programs and policies that have been successful in other countries could be tai- lored to the unique characteristics of the food system and culture in Egypt. Population-based intervention studies in high-income countries have demon- strated the efficacy of several preventive strategies to reduce the risk of chronic diseases in obese women and reduce the obesity risk among the general popula- tion (Hutchesson et al. 2015; Kremers et al. 2010; Tobias et al. 2015). However, translating these findings into practice requires changes in health systems and policies (Hu, Liu, and Willett 2011). The period spanning pregnancy and childbirth is an important window for the prevention of maternal obesity. Egyptian mothers have little awareness of the optimal weight gain during pregnancy and its relation to their food choices, with common misconceptions about foods and eating habits. Meanwhile, health care providers do not routinely weigh women during pregnancy or counsel them on weight gain during pregnancy (Kavle et al. 2014) At present, programs and interventions to address obesity in Egypt are inad- equate. There is little in the way of promotion or awareness of healthy diets or an active lifestyle, as well as a lack of access to healthy foods. Because of weak laws Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 73 regulating the food industry and lack of a regulating body to enact laws and pro- visions for the food industry, media advertisements of high sugar and fat content food items continue to target children and adolescents. Currently, there is no oversight mechanism in place to evaluate content or laws enacted banning false health and nutrition messages, prohibiting the targeting of children and adoles- cents, or promoting unhealthy food and nutrition practices. The Ministry of Youth and Sports has a nationwide program that promotes physical activity under the slogan Alreyada lel Gami (Sports for Everyone). Participation in sports, however, is generally low because it traditionally has not been part of the Egyptian culture. The government’s NNI and National Research Centre (NRC) have outpatient clinics for the management of obesity, promoting proper nutri- tion and health messages. However, beyond this there is little capacity within the health system for managing obesity and overweight. That said, in the last few years the GoE has begun to focus more on noncom- municable diseases (NCDs) in general and obesity in particular. Taking its cue from WHO’s development of the Global Action Plan for the Prevention and Control of Noncommunicable Diseases 2013–2020 (WHO 2013a), which aims to achieve the commitments of the UN Political Declaration on Noncommunicable Diseases, the MOHP established an NCD unit in late 2014 and carried out a situational analysis of existing strategies, policies, gaps, and opportunities. Following on from this, the MOHP led a collaborative process in 2017 to develop the Egypt National Multisectoral Action Plan for Prevention and Control of Noncommunicable Diseases 2017–2021. This plan is in line with the Global Action Plan for the Prevention and Control of Noncommunicable Diseases. A key target of this plan is to halt the rise in obesity by 2021. The plan would implement cost-effective, comprehensive prevention strategies, including pro- moting healthy diets through health promotion activities in schools, creating national guidelines for promoting physical activity, providing school physical education as part of the national curriculum, improving the detection and man- agement of NCDs, as well as developing strategies to reduce sugar consumption and salt intake. Each relevant sector is expected to incorporate activities to reach the targets set within their sector plans under the guidance of a national NCD committee. Moving forward, it will be important to ensure that the National Multisectoral Action Plan for the Prevention and Control of Noncommunicable Diseases 2017–2021 is implemented. For this to happen, the national coordi- nation mechanism needs to be fully functional down to the provincial and local level with all identified sectors playing their part. Also, a strong account- ability framework should be in place with a national monitoring framework that is in line with the global WHO framework. In the health sector in par- ticular, sufficient numbers of trained and competent professionals are needed to combat obesity, complemented by protocols at the institutional level for the prevention and early detection of overweight and obesity. During and after pregnancy, there is an opportunity through antenatal and postnatal care to improve the practices surrounding pregnancy and childbirth to prevent maternal obesity in Egypt. Another important step in the right direction would be developing national nutrition guidelines to promote healthy eating and promote active living, while enacting legislation banning the promotion of unhealthy food and nutrition practices and prohibiting the targeting of children and adolescents. 74 | Scaling Up Nutrition in the Arab Republic of Egypt Cross-cutting programs: National food fortification Egypt’s mandatory National Wheat Flour Fortification Program to fortify bread with iron and folic acid has the potential to address anemia in women and chil- dren. The program was included for national scaling up in the National Food and Nutrition Policy and Strategy (NFNPS) 2007–2017. It was implemented in partnership with the Global Alliance for Improved Nutrition (GAIN) and World Food Programme under the overall leadership of the Ministry of Supply and Internal Trade (MOSIT) in coordination with the MOHP. Under the program, iron (ferrous sulphate) and folic acid were added to all subsidized wheat flour produced of 82 percent extraction rate, providing a daily intake of approxi- mately 12 milligrams of iron and 600 micrograms of folic acid through the con- sumption of subsidized baladi bread.2 Significant investments were made in infrastructure and capacity building at the institutional level. However, unfor- tunately the program was interrupted in 2014, and, although no major evalua- tions were carried out, smaller studies suggested that up to 50 million Egyptians were consuming quality-assured fortified baladi bread on a daily basis. In 2011, 6.5 million metric tons of fortified wheat flour were produced by 143 participat- ing public and private sector mills (Elhakim et al. 2012). However, the iron com- pound and dosage used for fortification do not conform to WHO’s current guidelines (WHO, FAO, UNICEF, GAIN, MI, and FFI 2009). The country con- text also needs to be considered, as many Egyptians consume black tea, a potent inhibitor of iron absorption by 79–94 percent (El-Sahn, El-Masry, and El-Sahn 2003; Hurrell, Reddy, and Cook 1999). Reestablishing a national iron fortifica- tion program would have to be preceded by an evaluation study to evaluate the effectiveness of the program and also to follow updated specifications for the iron compound used, dosage, and so forth, as outlined in the WHO guidelines. Egypt also had a voluntary project that fortifies cooking oil with vitamin A through the National Vegetable Oil Fortification program. This project, imple- mented with the assistance of GAIN and the WFP, added vitamin A (retinol pal- mitate) and vitamin D to sunflower oil. The fortified oil was initially sold at a subsidized price to ration card holders. As part of the process, NNI helped to develop national fortification standards of 60 IU of vitamin A and 3 IU of vitamin D per gram of oil, which would deliver approximately 1,000 IU of vitamin A (that is, 35–50 percent of the recommended daily amount for adults and children). Globally, fortification of cooking oil with vitamin A (and vitamin D) has been found to be a very effective approach to controlling these micronutrient defi- ciencies (Allen et al. 2006). However, like the national wheat flour fortification program, this program was interrupted in 2014. Also, evidence revealed some decay of the vitamin A fortificant from oxidation of the oil (Laillou et al. 2012). Therefore, reinvigorating this program may require further attention to quality control issues at the industry level, as well as storage and light exposure at both the industry and household level. Finally, to combat iodine-deficiency disorders, the MOHP established a national program of universal salt iodization (USI) in the early 1990s. It part- nered with the following stakeholders: the NNI (Secretariat), MOSIT, Ministry of Industry, MOHP, Salt Producers Alliance, Chamber of Food Industries, Salt Alliance Group, Salt Industry Chamber, UNICEF, and WFP. According to EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015) and the national iodine survey (MOHP, GAIN, and UNICEF 2016), over 90 per- cent of households in Egypt now use iodized salt, which can be considered at Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 75 scale. Thus this program can be considered a great achievement. However, the quality assurance and quality control component of the ­ program should be strengthened, particularly at the level of the small- and intermediate-scale pro- ducers, to ensure that the level of salt iodization is adequately maintained and that the population is regularly reminded of the need to use iodized salt. NUTRITION-SENSITIVE INTERVENTIONS Nutrition-sensitive interventions address the key underlying determinants of nutrition and enhance the coverage and effectiveness of nutrition-specific inter- ventions. Nutrition-sensitive programs draw on committed and accountable collaboration and contributions from sectors such as agriculture, social protec- ­ tion, early child development, education, and water and sanitation to affect the underlying determinants of nutrition, including poverty, food insecurity, and scarcity of access to adequate care resources and health, water, and sanitation services. This section describes nutrition-sensitive interventions related to five areas in Egypt: (1) nutrition-sensitive agriculture and food security; (2) social protection and safety nets; (3) early childhood development; (4) child education; and (5) water, sanitation, and hygiene. Specifically, it describes how these inter- ventions can potentially affect nutrition status, the approach currently being taken, the challenges inherent in making them more nutrition-sensitive, and the potential way forward to ensure that each sector maximizes its impact on nutri- tion from the relevant programs. Nutrition-sensitive agriculture and food security Agricultural interventions have the potential to improve the nutritional status of households through four key pathways: (1) reductions in food prices from greater productivity of nutritious foods, leading to higher consumption; (2) higher incomes from selling the products produced; (3) consumption of one’s own pro- duction as a result of market imperfections or a focus on home production, including home gardens; and (4) factors linked to gender such as women’s social status and empowerment in agriculture, their time, and their health and nutri- tional status (Ruel and Alderman 2013). A number of studies have found positive relationships between agriculture and nutrition, particularly in terms of greater diet diversity, but less so in terms of nutritional status (Gillespie and van den Bold 2017). However, it is an area in which further research—context-specific— is required. Whether agricultural interventions increase household income or purchas- ing power or support household food consumption, agricultural development and food security programs need to focus on improving household food security in terms of both quantity and quality/diversity to achieve the intended nutri- tional benefits.3 Various agricultural investment strategies in Egypt are focusing on large-scale production, small-scale farming, as well as the participation of women in agriculture. Programs to increase agricultural production and productivity The GoE is investing heavily in national agricultural production and logistics. However, these investments do not have explicit nutrition outcome objectives. Egypt’s agriculture sector, largely dependent on the availability of water from the 76 | Scaling Up Nutrition in the Arab Republic of Egypt Nile, is one of the key sources of national income, contributing 19 percent of national merchandise exports, employing 25 percent of the labor force, and rep- resenting almost 15 percent of the country’s GDP.4 One of Egypt’s major new agri- business initiatives is the Global Logistics Centre Egypt project, which aims to improves the storage and handling of grains and food commodities and the man- ufacture and packaging of oilseed crops, unrefined oils, raw sugar, and grains. The initiative will serve a logistics hub that seeks to secure local and regional food markets with a total storage capacity of 20–25 million tons a year. The initiative should consider integrating household food security for vulnerable families as one of the project’s secondary outcomes. Aside from such larger initiatives, programs are seeking to increase the income of small farmers. However, none has been evaluated from a nutrition outcome perspective. Two such programs are supported by the U.S. Agency for International Development (USAID). Food Security and Agribusiness Support is one of the principal activities supported by USAID’s Feed the Future initiative. Since 2015, this project has sought to increase the income of 14,000 Egyptian farmers through strengthening the different stages of the agricultural process (value chain). Examples are integrating state-of-the-art technologies into small-scale cold storage infrastructure and irrigation, devel- oping farmers’ skills in postharvest processes, and enhancing production and marketing to build the capacity of the fruit and vegetable value chain produc- tion for domestic and export markets. Another USAID initiative, Premium Project for Egyptian Small Growers, is also working toward sustainably improving the socioeconomic conditions of farmers by making them interna- tionally competitive. Both approaches have yet to be evaluated from a nutri- tion perspective, and yet they have the potential to improve nutritional intake and diet diversity by increasing farmers’ incomes and enhancing fruit and vegetable production. Several initiatives in Egypt specifically aim to improve the participation of women (and youth) in agricultural development, but again none has been evalu- ated from a nutrition perspective. The prevalence of poverty in rural Upper Egypt, compounded by poor infrastructure, illiteracy, and rapid population growth, disproportionately makes women more economically vulnerable, and appears to have a disproportionate impact on nutrition outcomes (see chapter 1). Despite the fact that the share of women in the agriculture labor force has mark- edly increased since the 1990s, their contributions often remain unpaid and con- stitute informal “family labor.” Customs and gender disparities are at the core of many of the challenges disproportionately faced by women in agriculture. Several USAID-supported projects in Egypt are trying to improve women’s par- ticipation in agricultural development, and yet none of these programs is used as a “model” for nutrition-sensitive agriculture or intended for national scale-up. Such programs rest on evidence (primarily from elsewhere) that women farmers with access to finance are likely to have more leverage in household decision making, and they are more likely than men to spend their incomes on their fam- ilies’ food, education, and health. It is important to investigate the effectiveness of the potential linkages between agriculture and nutritional status in the Egyptian context before scaling up the existing programs. Some tentative steps are being taken in this direction by USAID through its Feed the Future approach (2015–20). This approach employs an evaluation component to determine the effects of USAID’s agricul- tural interventions and generate new evidence to inform policy and program Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 77 design and implementation. This includes examining how to better leverage the links between agriculture and health and nutrition, particularly addressing the challenges of stunting and malnutrition (USAID 2017). In addition to the lessons learned from this evaluation, lessons could be learned for employing similar nutrition evaluation components for other large agricultural programs in Egypt. Social protection and safety nets Social protection and safety net programs cover a range of prevention and pro- tection measures that reduce the insecurities arising from income loss, unem- ployment, illness, and old age. At its core, the provision of social protection should ultimately enhance the capacity of poor and vulnerable groups to address poverty in times of need and uncertainty and promote well-being. By doing so, they can also indirectly affect the immediate and underlying causes of malnutri- tion through, for example, improving diets via food transfers and school feeding programs and providing access to more diverse and safer sources of food. They also may improve access to and encourage the use of health services or enable households to access safe drinking water and better sanitation. Social protection programs can enhance the ability of household to provide care to young children through, for example, targeted transfers or labor regulations that enable women to breastfeed while working (FAO 2015). In Egypt, the most widely accessed forms of social protection are employ- ment-based social insurance, health insurance, and noncontributory public social assistance programs (such as the food subsidy program and the Social Fund for Development). A reform process was launched in 2011 to revise the social protection policy put forward in 2010, and there is an urgent need to reform the sector because the main traditional approach of GoE subsidies is rapidly becoming unaffordable and, as is increasingly apparent, ineffective or ­ even counterproductive in terms of nutrition outcomes. The current GoE reform process offers an interesting opportunity to integrate nutrition outcomes as a priority in the different steps of the reform process, along with the necessary monitoring and evaluation tools. Social and health insurance schemes Although Egypt has a social insurance program in place, it does not adequately cover women and the poor because of their low labor market participation. The program offers insurance (employment-based) in cases of maternity, retirement, sickness, and disability through the contributions of employers and employees (salary deductions). Under Egyptian labor law, employed women are entitled to three-month paid maternity leave per child (for up to three children) on the con- dition that these women have paid their social insurance contributions for at least 10 months prior to the maternity leave. All women are also permitted to take a one-hour nursing break (or two half-hours) per day. In large institutions (those with more than 50 employees), women have the right to two years of unpaid childrearing leave per child (for up to two children). However, the low formal labor force participation of women results in truncated social protection coverage, with less than 25 percent of women in any age group of employees. Informal labor markets are also biased against the poorest poor, who lack cover- age under the formal social insurance umbrella. Egypt also has a national health insurance scheme. However, it does not ade- quately target those most in need. Coverage is highest among public sector 78 | Scaling Up Nutrition in the Arab Republic of Egypt workers, with lower levels of coverage found particularly in rural areas and among women because relatively few are working in formal employment (Ameta and Shafie 2015). In addition, women outside the labor force are in general not covered as dependents of beneficiaries. Reforms in 2012 extended health insur- ance coverage to women heads of households without a source of income or with an income that does not exceed 150 percent of the ma’ash al daman al-igtima`i social solidarity pension (see section on conditional and unconditional cash transfers later in this chapter). It was hoped these reforms would reach an esti- mated 5 million beneficiaries (Sieverding and Selwaness 2012). However, in January 2018 Egypt approved a new social health insurance law that aims to cover the entire population. The founding principles are based on need rather than ability to pay. The two main pillars of this new approach are compulsory enrollment and subsidization of the poor. To ensure that the reforms will be effective and successful, the approach will also focus on health financing, as well as improving the efficiency, quality, accountability, and responsiveness of the health system to meet an individual’s needs. Food subsidy interventions Food subsidy interventions have existed for decades in Egypt, but in the past they may have actually contributed to the level of malnutrition in the country rather than preventing it. Created in 1941, the Tamween Food Subsidy System has long consisted of two components: (1) subsidized prices for baladi bread, the most consumed staple (and flour), and (2) ration card–based subsidies. In the original program, baladi bread was provided at a fixed price, and other GoE regulations ensured quality. Household rations, with fixed monthly quotas dependent on family size, allowed families to buy basic subsidized food items such as cooking calorie-dense and oil, sugar, rice, and black tea. However, the lower prices of the ­ nutrient-poor food items provided through the subsidy program may have encouraged greater consumption at the expense of other, more nutritious food groups, notably in urban Egypt. A recent study suggests that, although these food subsidies have played an important role in protecting the poor from the impact of high food prices in recent crises, they have also contributed to an overreliance on cheap and calorie-dense foods with limited nutrient content. The study finds that when compared with nonbeneficiaries, the probability of mothers being overweight is higher among beneficiary families. Subsidized baladi bread also seems to contribute to maternal overweight (Breisinger et al. 2013). Reforms to the program in 2014 due to budgetary constraints expanded the number of foods that were subsidized but may have increased the potential bur- den on the poor. The program was reformed into a voucher-like system that replaces subsidized commodity quotas with a monthly cash allotment. The pro- gram now combines baladi bread with the original subsidized commodities (rice, oil, and sugar) to which many items were added such as pasta, lentils, beans, milk, white cheeses, frozen beef, chicken, and fish. Beneficiaries are, how- ever, now required to make an out-of-pocket co-payment upon purchase of the subsidized commodities, which still limits the poorest families from taking full advantage of the system. Substituting food subsidies for cash transfers (dis- cussed in the sections that follow) has been proposed as an alternative development-oriented strategy for tackling food insecurity and the impacts of ­ poverty on nutrition. Overall, the food subsidy system is not explicitly built to combat malnutrition but to alleviate the burden of poverty and food insecurity. Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 79 Thus the consequences for food consumption patterns and therefore nutritional status are not explicitly recognized. Conditional and unconditional cash transfers Cash transfers are intended to increase the resilience of poor and vulnerable households to poverty, economic shocks, and social vulnerability. Such resilience can improve a household’s ability to obtain food and health care, which are key to ensuring proper nutrition for children. Social protection is therefore recog- nized as an important strategy for accelerating progress in improving maternal and child nutrition (Ruel and Alderman 2013). Bhutta et al. (2008) estimate that if interventions, including cash transfers, targeted pregnant women and young infants, malnutrition and disease burden could be reduced by 25 percent in the short term. An increasingly popular tool to achieve this is cash transfer programs that target poor and vulnerable groups. Programs may take the form of uncondi- tional cash transfers, in which the cash can be spent as desired, or conditional cash transfers (CCTs), in which funds are given to households on the condition that they comply with certain predefined requirements. Conditions could include regular visits to a health care facility, regular school attendance by chil- dren, and compliance with health and nutrition promotion activities. Although there is evidence that cash transfer programs increase the resources available for food and health care, the evidence is mixed on whether cash trans- fers have a direct impact on nutrition outcomes, and so further research is required. A study of five CCTs in Latin America found a positive impact on child height but not on micronutrient status (Leroy, Ruel, and Verhofstadt 2009). A second study of CCTs had more mixed results, with programs having a positive impact on child height in Mexico and Nicaragua but not in Brazil and Honduras (Bassett 2008). A World Bank pilot of a CCT in Bangladesh was able to boost household consumption of protein and other nutrition-rich foods and reduce wasting (Ferré and Sharif 2014). The picture elsewhere is decidedly more mixed when it comes to nonconditional cash transfers. A recent study in Kenya finds cash transfers have no impact on nutritional status (Oxford Policy Management 2017), whereas a study in Zambia finds that, although cash transfers improve household consumption, food consumption, diet diversity, and food security, they have no significant impact on nutritional status (Seidenfeld et al. 2014). The lack of consensus in the literature emphasizes the importance of evaluating the effectiveness of the program in the country context. The GoE runs conditional and unconditional cash assistance programs that could positively affect nutrition outcomes because of the specific conditionali- ties attached (CCT) and also increase the incomes of the poor. The Takaful (Solidarity) and Karama (Dignity) cash transfer program—eventually split into two subprograms—was developed to offer nationally targeted social safety net- work subprograms aimed at protecting the poor through income support. In 2015 the program was implemented in nine governorates with poverty rates exceeding 60 percent. Within three years, Takaful and Karama (to September 2018) managed to reach over 2.247 million households and to expand to all dis- tricts and governorates nationwide. Takaful (Solidarity) is a family income support subprogram for poor house- holds with children (0–18 years of age). It was introduced in 2015 under the man- date of MOSS. The amount of the Takaful cash transfer to households depends on the number of children and their school level. Takaful transfers start at LE 325 per household per month, which increases according to the number of 80 | Scaling Up Nutrition in the Arab Republic of Egypt children in the household and their education level. Households receive LE 60 for each child under 6 years old, LE 80 per child in primary education, LE 100 per child in preparatory education, and LE 140 per child in secondary education. As of 2019, households can receive benefits for only two children. The recipients of payments, which are made electronically each quarter, are mainly the women caregivers. At the outset of 2018, conditions were added to the program. They include requiring households in the program to ensure that mothers and children 0–6 years of age participate in MCH clinic visits twice a year, children 6–18 years of age attend school (at least 80 percent attendance), and pregnant women attend antenatal and postnatal care. The introduction of the conditionalities is expected to have significant impacts on both nutrition and children’s health in general. In fact, a recent impact evaluation of the program by the International Food Policy Research Institute (IFPRI) found it improves the quality of diets and results in rates of stunting and wasting that are considerably lower than the esti- mates from EDHS 2014 (Breisinger et al. 2018). It recommended that this finding be further explored. MOSS is currently piloting, together with the WFP, MOHP, and MOSIT, the first 1,000 days program model in three governorates in Upper Egypt. The program is targeting Takaful beneficiaries, including pregnant women and children 0–24 months of age. Recipients receive a food voucher for nutritious foods upon fulfilling the conditionality of receiving regular nutrition services from the PHC units. In addition, women receive nutrition counseling support. This pilot has the potential to affect the key nutrition indicators, but it will be important for partners to evaluate the pilot over a long period to assess the nutritional impact before expanding coverage across the Takaful program with the 1,000 days program model. Karama (Dignity) is an unconditional income support and social inclusion subprogram that provides unconditional cash payments. Recipients are the elderly and people with disabilities who cannot work and orphans under 18 years of age who are living outside of institutions and are caretakers of extended family members. Elderly persons over 65 years of age and people with disabilities cur- rently receive LE 450 per month, and orphans receive LE 350 per month. Currently, about 306,016 households benefit from the program—82 percent of recipients are elderly and 17 percent are disabled (World Bank 2018b). Egypt also has a social assistance program designed for households with no male provider. This long-running social safety net program, known as ma’ash al daman al-igtima`i (social solidarity pension), was established in 1980 and is administered by the Ministry of Social Affairs (MOSA) and MOSS. It targets households with no male provider capable of earning an income and therefore includes some of the most vulnerable groups in society, including divorced, wid- owed, and abandoned women, women with no male provider, as well as orphans, the disabled, and households in which the male head is unable to work. New applicants to this program falling into target categories also covered by Karama (such as the elderly, people with disabilities, and orphans) are now directed toward Karama, and the social solidarity pension is closed to such new applicants. However, the pension continues to cover some 1.5 million house- holds, although issues with targeting result in a substantial amount of funds going to the nonpoor. Recent new regulations call for updating beneficiaries’ information and reviewing their eligibility to ensure the program reaches only those most in need. And yet a review has found that even for the beneficiaries who manage to get into the program, the amount received (ranging from LE 215 Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 81 for a one-person household to LE 300 for a four-person household) is insuffi- cient to cover the minimum cost of living for the lowest income groups in Egypt (Ameta and Shafie 2015; Korayem 2013; Sieverding and Selwaness 2012 ). Early childhood development Early childhood development is the ongoing process of acquiring the skills and abilities during the early years of life that help a person to think, solve problems, communicate, express emotions, and form relationships. It is also considered the foundation of health, learning, productivity, and well-being and is the building block for future human capital formation. The early childhood period encom- passes several quite distinct phases: from conception to birth and from birth to 3 years, with an emphasis on the first 1,000 days (from conception to 24 months), followed by the preschool and preprimary years (from 3 to 5 or 6 years, or the age of school entry) and from 6 to 8 years of age, when the child is transitioning into primary school. The developing brain needs stimulation, nutrition, and protection. Stimulation sparks connections between brain cells—connections that are also fueled by ade- quate nutrition. Early brain development also depends on nurturing a protective and healthy environment in which children can grow. However, according to the key indicators, Egypt ranks 88th among the 172 countries ordered from most to least successful in nurturing a healthy environment for their most vulnerable young. These indicators include under-5 mortality, malnutrition that stunts growth, out-of-school children, child labor, early marriage, adolescent births, displacement by conflict. and child homicide (Save the Children 2017). When children’s brains do not reach their potential—in particular, those of the poorest and most disadvantaged children—it perpetuates an intergenera- tional cycle of disadvantage and inequity. Investing in early childhood develop- ment is a challenge, but it is also an opportunity to make substantial, cost-effective progress by investing in relatively simple solutions. Investments in early child- hood programs, starting with the youngest, yield more than a 13 percent return in reduced poverty and income gaps and increased prosperity and economic competitiveness. ECD programs are affordable: on average, they cost $0.50 per capita per year when added to the existing health and nutrition service delivery programs (Richter et al. 2017). It has also been found that several existing mater- nal health and nutrition interventions themselves promote physical and cogni- tive development during a child’s first 1,000 days, such as promotion of optimal infant and young child feeding (Britto et al. 2017). ECD, a national priority in Egypt, is an integral part of its National Development Plan: Vision 2030. The current legislation is supportive of scaling up early learning opportunities. However, only 8 percent of young children have access to nurseries, and, despite the upward trend in the net enrollment rate for preschool education (from 21 percent to 28 percent between 2010/11 and 2015/16), it is not likely that Egypt will meet the very ambitious target of 80 percent enrollment by 2030. Current national policies also do not allow parents and caregivers to have enough time and resources to care for their children (policies allow only four months of paid maternity leave and no paternity leave). Although there is a long way to go toward ensuring that Egyptian children have a safe and nurturing environment in which to grow up and thrive, progress is being made in some areas. 82 | Scaling Up Nutrition in the Arab Republic of Egypt A countrywide initiative was recently launched to reorganize, revamp, and scale up a comprehensive early childhood development program. Key actors in this process are MOSS, MOE, and MOHP, with overall coordination provided by the National Council for Childhood and Motherhood and support from UNICEF and other partners. The program establishes an institutional support system that will systematically monitor and respond to children’s development challenges and opportunities, starting from motherhood through birth and infancy up to preschool and early primary school. This institutional support system is created by linking birth registration and MCH well-baby clinics with the estimated 14,000 nurseries registered under MOSS providing preschool children with day- care and the kindergartens enrolling some 30 percent of children 5–6 years of age. It will take some time to fully develop and scale up this emerging ECD model, and it will be important to ensure that the required capacity and linkages with key sectors, including health and nutrition, are established at an early stage to support the rollout. Furthermore, UNICEF has begun a new public–private sector initiative on family-friendly policies. This initiative calls on governments and private sector partners to redesign the workplaces of the future to enable parents to give the best start in life to their children while boosting productivity and female empow- erment. Specifically, it calls for the introduction of (1) six months of paid parental leave; (2) breastfeeding facilities and remunerated breastfeeding breaks for the first six months; (3) affordable, accessible, and quality child care services; and (4) child grants that support all families with children. This initiative, together with the revamping of the ECD program, have the potential to give children a better start in life, and both programs will be important to ensure that links are established and maintained with key existing nutrition interventions (such as the promotion of optimal infant and young child feeding) and to ensure any new nutrition initiatives implemented through the primary health care system care- fully relate to these ECD approaches. Child education School-age children are an extremely important group in the population. They are not only soon-to-be-parents but also very important conduits of knowledge and best practice. Nutrition-sensitive education requires gaining a proper under- standing of nutrition and the consequences of malnutrition through school health education programs, as well as ensuring that a well-nourished body of students is engaging in their studies and shaping their social values. In addition to other benefits, girls that continue their education through secondary educa- tion and beyond are much less likely to undergo teenage pregnancies (related to higher risk of stunting) and have malnourished children in general. Until now, this avenue for nutrition interventions has largely been overlooked in Egypt. A precondition for reaping the benefits of a nutrition-sensitive education system is to ensure that all children are enrolled and are able to complete both their primary and secondary education, and that such an education will benefit them in terms of nutrition. General access to and quality of education Although access to basic education in Egypt is substantial, enrollment of the poor is still subpar, and the quality of education in Egypt as well as the nutrition content of the curriculum remain problematic. Overall access to education is Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 83 substantial—96 percent gross enrollment for primary education and 69 percent for secondary education (CAPMAS and UNICEF 2017). Especially for girls, enrollment in all four levels of education has reached equality. However, the most deprived children from poor families and remote areas are still out of school. The number of children out of school is currently estimated at 0.65 mil- lion, with 0.32 million children of primary school age and 0.33 million children of preparatory school age.5 The quality of education, however, is problematic. Half of the students in school do not learn foundational skills in mathematics and science. In mathe- matics, 53 percent of students did not reach the low benchmark in the 2015 Trends in Mathematics and Science Study (TIMSS), and in science 58 percent of students failed to do so (IEA and Boston College 2015). Current school curricula and textbooks do not contain the important nutrition facts that Egyptians in gen- eral and Egyptian parents in particular need to know because health education is considered weak overall in the public school curriculum. Physical education is often given low priority by schools and parents alike. It would be particularly beneficial to carry out a review of health education in public primary and sec- ondary schools to ensure that nutrition and healthy lifestyles are being taught. School feeding programs Egypt has an effective long-standing National School Feeding Program (NSFP), but its coverage is limited to primary schools. The ministries involved include MOSS, MOE, and MOHP. The program, which currently covers 18 million stu- dents, aims to not only provide students with basic nourishment, but also help change behavior and develop the skills children need to choose a healthy meal. It also helps prevent children from entering the labor market too early and encourages school attendance. The meal type differs by school. For daily public schools, a premade or dry meal is supplied, whereas for schools for students with special needs and for boarding and community schools a cooked meal is offered. In public schools, subcontractors are responsible for the distribution of meals under the supervision of MOE and MOSIT. These meals are restricted to pri- mary school students. Although the program is generally considered a success at the primary school level, similar programs do not exist at the kindergarten and secondary level. The World Food Programme supports components of the NSFP to fill some of the existing gaps. The WFP supports community schools in 16 governorates, with the primary aim of encouraging the enrollment and attendance of children in schools, especially girls. However, the snacks provided (fortified date bars) also help to meet nutritional requirements by providing 25 percent of a child’s daily nutritional needs and teachers are trained on adequate nutrition. According to the WFP, it was able to support 636,000 students in 2016, with the majority of beneficiaries being girls (77 percent). In addition, conditional take-home rations were distributed to students with a minimum of 80 percent monthly attendance (WFP 2016). Recently, the Ministry of Education asked to adopt the WFP’s for- tified date bars for all national schools. The WFP is also providing support for nutrition social and behavioral change in schools and in local communities through community hubs. It is represented on the national school feeding com- mittee, providing strategic support to the GoE on the national school feeding strategy along with MOSS and partners. The Egyptian Food Bank, according to its website,6 covers community schools in 10 governorates, establishes kitchens in the schools, and trains mothers in adequate nutrition and healthy cooking. 84 | Scaling Up Nutrition in the Arab Republic of Egypt It also provides financial support, covering 21,000 students in 10 governorates in 2014. All meal supplies are contingent upon the availability of funds. Although the primary aim of school feeding is to encourage enrollment and attendance at schools and support learning by alleviating short-term hunger, it also has the potential to provide nutritional benefits. There is currently little evi- dence on the cost-benefits of school feeding programs, and the available evi- dence shows that, although such programs can affect the micronutrient level of targeted children, they have modest effects on health and nutrition outcomes as evaluated by anthropometric measurements (Jomaa, McDonnell, and Probart 2011). Therefore, in the medium term it will be important to ensure that school feeding programs in Egypt are having the desired impact on enrollment, atten- dance, and nutrition outcomes and can be implemented sustainably before look- ing to scale up further. Water, sanitation, and hygiene (WASH) There is a wealth of evidence linking the lack of sanitation and hygiene with the prevalence of diarrheal diseases among children. It has been estimated that 25 percent of undernourishment in developing countries stems from infectious diseases such as diarrhea, ascariasis, trichuriasis, protozoa, other helminths, and enteric diseases, which are very prevalent in unhealthy environments coupled with unhygienic practices (Caulfield et al. 2004; Humphery 2009; Prüss-Üstün and Corvalán 2006). In Egypt, the lack of proper toilet facilities and open defe- cation practices are a fertile setting (soil contaminated with feces and wastewa- ter) in which parasitic eggs and larvae can survive and in which these infectious agents can then be easily transmitted back to humans walking through these areas or from the foods grown there. Eventually, the transmission of infectious parasitic diseases affects the intestinal tract of infected individuals and severely undermines digestive health, causing loss of appetite, malabsorption of nutri- ents, and growth faltering. The scholarly evidence on the relationship between gastrointestinal infec- tions and malnutrition is overwhelming. Humphery (2009), for example, associ- ates 25 percent of all stunting cases with having five or more repeated episodes of diarrhea in the first 24 months of a child’s life. Likewise, based on an analysis of 140 demographic and health surveys, Spears (2013) attributes 50 percent of the variation in children’s height across 65 countries to the frequency of open defecation practices. In line with the World Health Organization, Prüss-Üstün and Corvalán (2006) similarly argue that 50 percent of undernourishment in the developing world could be explained by intestinal worm infections. On that point, Fischer Walker et al. (2012) argue that children under 5 in low-income countries tend to experience on average 2.9 episodes of diarrhea a year because of lack of proper water and sanitation facilities. However, systematic reviews of the evidence have demonstrated only marginal improvement in stunting as a result of WASH interventions (Dangour et al. 2013), and more recent efficacy trials have found no benefit of improved household-level  WASH  on linear growth (Pickering 2019). In Egypt, similar correlational patterns have been evident. In a study con- ducted by Ashour and Ahmed (1994) in Dakahliya governorate, the probability of diarrheal infection among children was higher in areas where families disposed of refuse close to dwellings or into nearby water streams. According to WHO, improving access to safe drinking water and sanitation services in Egypt can Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 85 reduce the total burden of disease by 25.1 percent (Prüss-Üstün et al. 2008). The Second International Conference on Nutrition (ICN2), organized by the Food and Agriculture Organization (FAO) and WHO in November 2014, pinpointed the need to integrate WASH-focused activities into the global nutrition agenda. Clean water Access to clean drinking water may have improved for many in Egypt, but it con- tinues to be problematic, particularly for poor communities and some rural gov- ernorates. Over the past decades, Egypt has made significant improvements in connecting residential buildings to the water supply. For about 91 percent of buildings, water is piped onto the premises (EDHS 2014). Overall, the access to improved sources of drinking water is very high at 98 percent (EDHS 2014), with little variation between urban and rural areas. However, pockets of the country have poorer access, particularly the frontier governorates (85 percent) and those in the lower wealth quintiles. In addition to the public organizations responsible for clean water, organizations such as UNICEF are working to ensure that the most deprived households have access to clean water. Although access to improved water sources is high, quality is still a concern. Uninterrupted access to potable water is of paramount importance for the achievement of better nutrition outcomes, and yet many of Upper and Lower Egypt’s rural dwellings commonly report stoppages in the supply of water ser- vices for several hours a week. The stoppages in turn increase the risk of gastro- intestinal infections. On that point, Roushdy, Sieverding, and Radwan (2012), based on the EDHS 2008 results (El-Zanaty and Way 2009), report a statistically significant negative correlation between access to an improved continuous source of drinking water and diarrhea prevalence among children in areas where mothers have little formal education. Therefore, the major issues requiring attention are improving the continuous supply and, linked to this, carrying out regular maintenance of supply systems to ensure safe water is accessible to all. Improved sanitation Access to improved sanitation in Egypt remains largely subpar, particularly in rural and remote areas. At the national level, only 49 percent of households have access to public sanitation services, whereas 19 percent are connected to septic tanks, and 23 percent have to dispose of wastewater through pit latrines. Most of the underserved households (74 percent) are located in rural Upper Egypt (EDHS 2014). According to GoE statistics, sewerage coverage in rural areas was a low 12 percent in 2014. Thus some 42 million village dwellers remain underserved. Children in rural areas are also the most deprived. They are 8.5 times more likely to lack toilet facilities, compared with their urban counterparts (UNICEF and WHO 2011). Of greater significance, about percent of Egypt’s households, mostly in the rural Nile Delta, still discharge 5 ­ untreated wastewater into nearby canals that feed into the agriculture irriga- tion system. This situation exacerbates the risk of becoming infected with parasitic and waterborne diseases, even for families who have proper access ­ to public sewer networks because they live close to unsanitary waterways or consume dietary products that have been farmed on polluted land. The GoE has made improving sanitation a priority and so embarked on a $14 billion National Rural Sanitation Program (NRSP) in 2014, supported by the World Bank and other donors. The NRSP has adopted an investment priority approach that gives priority to areas where the degree of soil contamination and 86 | Scaling Up Nutrition in the Arab Republic of Egypt the expected environmental return on investment are the greatest. In doing so, the program initially facilitates the access of more than 800,000 poor Egyptians living in 769 villages in seven governorates7 to improved sanitation services as well as greater hygiene awareness (World Bank 2018a). Similar efforts have been replicated by other development partners. USAID, for example, has invested more than $3.4 billion since 1978 in bottom-up partic- ipatory sanitation projects to extend access to more than 25 million Egyptians, largely in Cairo, Alexandria, and Suez. Likewise, the German Development Agency (GIZ) has invested since 2004 in decentralized, community-based wastewater treatment facilities, mostly in isolated villages in Lower Egypt. Under the European Union (EU) Neighborhood Investment Facility (NIF), other European donors, such as the Agence Française de Développement (AFD), European Investment Bank (EIB), Swiss Confederation through the State Secretariat for Economic Affairs (SECO), and German Financial Cooperation (KfW), have provided finance and technical assistance for the Improved Water and Wastewater Services Program (IWSP) in eight of Upper and Lower Egypt’s governorates: Gharbia, Sharqia, Damietta, Beheira, Qena, Sohag, Asyut, and Minya. Key challenges and opportunities in the water and sanitation sector The high cost of providing conventional water and sanitation systems is a key challenge facing the realization of improved coverage. The high cost of construc- tion is further exacerbated by the high operating and maintenance costs and the low tariff fees imposed on water and wastewater treatment services. To that end, the GoE recently announced a new tariff structure that will enable the Holding Company for Water and Waste Water (HCWW) to recover operation and main- tenance costs, ration consumption, and ultimately increase the efficiency of ser- vice operators. These steps may encourage further investment in water and sanitation services. The complex institutional arrangement of Egypt’s water and sanitation sys- tem also poses significant impediments to the improvement of service provision. Strong coordination is needed among the four key ministries responsible for set- ting the standards and monitoring the quality of delivered services: Ministry of Water Resources and Irrigation (MOWRI), Ministry of Health and Population, Ministry of Environment, and Ministry of Housing, Utilities and Urban Communities (MOHUUC). In addition, the division of responsibilities between the two main operators, the HCWW and the National Organization for Potable Water and Sanitary Drainage (NOPWASD), should be set out more clearly to ensure no duplication in implementation of key projects in the sector. To this end, an overarching integrated strategy should be developed that clearly sets out the main tasks assigned to each player and priorities of the sector. This strategy should in turn foster better intersectoral communication among different actors and enable decision makers to identify in an orderly fashion the real priorities of the sector. Although WASH interventions in the context of nutrition, particularly water supply and sanitation infrastructure, can positively affect nutrition outcomes by addressing both the immediate and underlying causes of malnutrition, they are usually considered outside of the remit and scope of nutrition scale-up plans because of the large investments required. Moreover, WASH interventions, like all nutrition-sensitive interventions, do not automatically lead to improvements in nutrition, but they are likely to do so in the situations in which WASH factors Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 87 are indeed the main causes of nutrition problems. Therefore, investments made need to be carefully directed towards the most effective WASH interventions and target those in most need (e.g. deprived households with poor living condi- tions) with particular WASH interventions part of a multisectoral approach to improving nutritional status. Although the intention may not be building infra- structure from a nutrition perspective, working with the key players in the water and sanitation sector to advocate for improved coverage of water and sanitation services for shared benefits is still important. At the same time, the focus should be on the causal linkages (for example, diarrheal disease and parasitic infections) and extending advocacy to key target groups linked to the critical nutrition life cycle periods, such as 1,000 days). Developing links with the health and educa- tion sectors can also help to ensure that the nutrition outcomes of the infrastruc- ture programs are maximized. Health and hygiene practices Carried out in parallel with the large-scale interventions just described, the pro- motion of good hygiene practices can also contribute to the prevention of gastro- intestinal infections. Many simple, effective, and cost-efficient practices actually fall under this umbrella, including effective handwashing with soap, proper dis- posal of young children’s feces, safe water conservation and preservation, and good food hygiene behavior. It is argued that seeking behavioral change in this direction is effective in improving nutritional status. On that point, Freeman et al. (2017) claim that health education and hand washing with soap can poten- tially reduce diarrheal infections by 40 percent. Likewise, in Bangladesh wash- ing at least one hand after defecation and before food preparation was associated with less diarrheal infection (Luby et al. 2011). Prüss-Üstün et al. (2014) also sug- gest a direct relationship between the unsafe disposal of young children’s feces and diarrhea prevalence—children under 5 tend to experience the highest rate of diarrhea, and thus their feces harbor high loads of pathogens that can easily spread into surrounding environments. In fact, EDHS 2014 reveals that the 24 percent of families in Egypt that reported throwing a child’s stool into garbage make up about 40.5 percent of those who had diarrhea in the family in the month preceding the EDHS survey. Even more, around 19 percent of them experienced at least three episodes of infection. This finding reflects a real need for raising awareness of the desirability of good hygiene practices to prevent diarrhea prev- alence, especially in communities where there is a lack of conviction about the health benefits of these desirable small, doable actions if integrated into every- day activities. Schools and health clinics can play central roles in improving health and hygiene practices. Between 2007 and 2014, UNICEF Egypt disseminated health information on hygiene, sanitation, and environment-friendly practices to 12,811 families and 200,000 schoolchildren in more than 370 primary schools in Asyut, Sohag, and Qena. In addition, it worked on strengthening the capacity of 2,000 educators to carry out awareness activities. The wide replication of this inter- vention could enable Egypt to maximize the impact of other nutrition-sensitive programs. This experience suggests that there are numerous opportunities within schools and health clinics to integrate approaches to improving hygiene. For example, teachers could give brief hygiene talks on fecal contamination and how effective hand washing before food preparation and eating and after the use of toilets can prevent gastrointestinal infections. Schools could also set up hand 88 | Scaling Up Nutrition in the Arab Republic of Egypt TABLE 3.9  Proposed WASH interventions INTERVENTION TARGET BENEFICIARY DELIVERY CHANNELS KEY PLAYERS PARTNERS Use of Households Public and private water and Ministry of Health and Population Private water and improved water sanitation companies (MOHP), Ministry of Water sanitation companies, source Resources and Irrigation (MOWRI), UN agencies Ministry of Housing, Utilities and Urban Communities (MOHUUC), Ministry of Agriculture and Land Reclamation, local planning authorities, public water companies Use of water Households Public and private water and MOHP, MOWRI, MOHUUC, local Private water and connection in sanitation companies planning authorities, public water sanitation companies, home companies UN agencies Improved Households Health units, health centers, MOHP, MOWRI, MOHUUC, Private water and excreta disposal schools, public and private Ministry of Environment sanitation companies, (latrine/toilet) water and sanitation companies UN agencies Hand washing Households Health units, health centers, MOHP, MOWRI, MOHUUC, Private water and with soap schools, public and private Ministry of Environment sanitation companies, water and sanitation companies UN agencies Hygienic Households Health units, health centers, MOHP, MOWRI, MOHUUC, Private water and disposal of schools, public and private Ministry of Environment sanitation companies, children’s stools water and sanitation companies UN agencies Note: WASH = water, sanitation, and hygiene. washing stations in playgrounds and near food stations as a reminder for stu- dents to wash their hands. Written messages could also be placed on corridor walls and school fences. Similarly, health care providers could explain to moth- ers the importance of the safe disposal of diapers and animal feces, and why they should be kept away of areas where food is prepared and served. In fact, atten- dance at regular health checkups, a conditionality of the Takaful conditional cash transfer program, could serve as a platform for health professionals to rein- force these hygiene messages. Table 3.9 summarizes the proposed WASH interventions. RECOMMENDATIONS: POTENTIAL HIGH-IMPACT NUTRITION POLICY AND PROGRAM OPTIONS TO CONSIDER FOR EGYPT The following briefly summarizes the nutrition-specific and nutrition-sensitive interventions and programs to be considered for scale-up in Egypt in the context of 1,000 days, the Lancet high-impact interventions, and the Egyptian context as outlined and discussed in chapter 1 and the earlier parts of this chapter. Which key focus areas and why? Focusing on interventions during the 1,000-day period from a child’s conception until second birthday to ensure the nutritional status of a woman at conception and during pregnancy and of the child through the first two years of life so that the child has every opportunity to grow and thrive is critical. Malnutrition starts in utero and thus adequate maternal nutrition is critical for the growth of the fetus in utero and, later on, the nutrient content of breast milk, thereby ensuring the proper growth and development of the newborn. Later, proper Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 89 complementary feeding of the child (from the age of 6 months) along with micronutrient supplementation are also important to support the growth of the child. However, currently in Egypt there are gaps in coverage of the relevant interventions, resulting in suboptimal IYCF practices and reduced micronutri- ent status. Fully implementing SBCC for expectant and lactating mothers through antenatal care and growth monitoring and promotion, as well as scaling up the provision of key micronutrient supplements for pregnant women (IFA) and children (vitamin A and iron) will help to ensure that the child advances into childhood adequately nourished. Currently, the IMCI strategy in Egypt lacks specific protocols for the effective management of malnutrition, which is a major cause of mortality in children under 5. The treatment of malnourished children at home and by health staff and CHWs at the PHC unit level, as well as at referral hospitals at the district and governorate level, is currently not taking place at scale. Because of the level of wasting (8 percent), it is proposed that the capacity to enable effective treatment of malnutrition be developed by establishing an IMAM program for the treat- ment of SAM and MAM cases. A whole range of childhood disease prevention and treatment activities are needed to safeguard the continued healthy growth and development of chil- dren. During childhood, the vicious cycle of repeated infections and malnutri- tion hinders growth, resulting in both acute and chronic malnutrition. Many childhood prevention and treatment activities are included in the well-­ established IMCI strategy used at the PHC level in Egypt, but a few comple- mentary and critical nutrition interventions need to be more systematically implemented as part of this IMCI protocol—namely, therapeutic zinc supple- mentation in cases of diarrhea, deworming (if indicated), and ensuring proper sanitation and hygiene practices to control intestinal infections during infancy and childhood. Finally, ensuring a safe and clean environment by scaling up WASH interven- tions, particularly in rural areas where coverage is lower, can reduce the number of cases of infectious diseases such as diarrhea, reducing the prevalence of mal- nutrition among pregnant women and children in Egypt. Table 3.10 summarizes the 16 interventions recommended for scale-up. Nutrition-relevant interventions and programs not included for scale-up Some interventions discussed in this chapter in the context of Egypt are not included in the suggested list for scale-up. These include some of the ­ evidence-based, high-impact nutrition-specific interventions from the Lancet and other interventions and programs that are currently, or have the potential to be, nutrition-sensitive. A summary of the rationale for these decisions, discussed more extensively in the previous section, is outlined in this section. Provision of complementary foods. The provision of nutrient-dense comple- mentary foods for children has not been implemented in Egypt. Although it could be an option for children living in impoverished conditions to ensure that their nutritional needs are met, it would have to be tested as part of the wider IYCF strategy and evaluated before being considered for scale-up. Flour fortification with iron and folic acid and oil fortification with vitamin A. If the national flour fortification program is to be reestablished, it would be necessary to use the WHO– recommended iron compound, NaFeEDTA 90 | Scaling Up Nutrition in the Arab Republic of Egypt TABLE 3.10  Nutrition interventions recommended for scale-up in Egypt INTERVENTION DESCRIPTION TARGET POPULATION Infant and young child feeding (IYCF) and micronutrients 1. Promotion and support of Communication of optimal breastfeeding practices Pregnant women and breastfeeding mothers of children 0–6 months 2. Complementary feeding promotion Communication of complementary feeding practices (excluding Mothers of children provision of food) 6–23 months 3. Growth monitoring and promotion Systematic strengthening of GMP guidelines and operational Children 0–59 months (GMP) procedures, training, and scale-up 4. Vitamin A supplementation Biannual supplementation of vitamin A capsules Children 6–59 months 5. Iron supplementation Weekly supplementation for three months with iron drops, Children 6–59 months followed by three months of no supplementation, and repeated until child is 5 years of age Curative interventions (SAM/MAM) 6. Treatment of moderate acute Treatment of MAM in supplementary feeding programs Children 6–59 months malnutrition (MAM) 7. Management of severe acute Admission of severely malnourished children to either inpatient Children 6–59 months malnutrition (SAM) or outpatient therapeutic feeding programs Disease prevention and management 8. Treatment of diarrhea (ORS) Management of mild and moderate diarrhea with oral Children 6–59 months rehydration solution (ORS) 9. Therapeutic zinc supplementation As part of diarrhea management with ORS Children 6–59 months 10. Deworming Annual or biannual single-dose albendazole (400 milligrams) or Children 12–59 months mebendazole (500 milligrams) to reduce the worm burden of soil-transmitted helminth infection Maternal nutrition 11. Iron–folic acid supplementation Three months supplementation of iron–folic acid during Pregnant women pregnancy Water, sanitation, and hygiene (WASH) 12. Use of improved water source Regulation and advocacy activities to ensure access to water All households supply services from an “improved” source within 1 kilometer of the user’s dwelling. An improved source is one that is likely to provide “safe” water. 13. Use of water connection in home Regulation and advocacy activities to ensure access to safe water All households from a household connection 14. Improved excreta disposal (latrine/ Promotional activities to ensure access to improved/hygienic All households toilet) excreta disposal (access to improved latrine or flush toilet) 15. Hand washing with soap Promotional activities for “appropriate” hand washing behavior All households 16. Hygienic disposal of children’s stools Promotional activities for the proper disposal of children’s stools All households Note: GMP = growth monitoring and promotion; MAM = moderate acute malnutrition; ORS = oral rehydration solution; SAM = severe acute malnutrition; WASH = water, sanitation, and hygiene. (Aaron et al. 2012), in the most commonly consumed staples among the target age groups, with consideration of the higher premix price. In addition, a pilot study is needed to collect data on coverage and clinical outcomes at the base- line and endline (at least) before taking this intervention to scale. If deemed cost-effective, flour fortification should be incorporated into a multi-­ intervention strategy for the treatment, prevention, and awareness of iron defi- ciency anemia among the targeted age groups. Similarly, for the national oil fortification program, evaluation of the following is necessary prior to Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 91 considering scale-up: verification of the amount of vitamin in the oil, stability of vitamin A at the point of consumption, and coverage and clinical outcomes among target populations. Before scaling up, it will be necessary to address the gaps and challenges that existed in those programs. Moving forward, public education campaigns and advocacy efforts would have to be incorporated in future plans to reinstate these programs. Salt iodization. For the scale-up and costing of nutrition interventions, the common assumption is 90 percent coverage rather than 100 percent coverage because the marginal cost rises substantially for the remaining 10 percent (SUN Movement 2010). National coverage of iodized salt is 91 percent, and thus the intervention could be considered at scale. Obesity prevention and control. Obesity and overweight are critical issues in Egypt, particularly among women of reproductive age. More than a third are overweight, and close to half are obese. Dietary habits, food consumption pat- terns, and lack of physical activity all contribute to the increasing prevalence of overweight and obesity in both the adolescent and the adult population. The GoE recognized the potential consequences of this phenomenon by developing the Egypt National Multisectoral Action Plan for Prevention and Control of Noncommunicable Diseases 2017–21, whose target is to halt the rise in obesity by 2021. With the focus currently on ensuring that the necessary structures and processes are in place to implement the action plan, it will be important to estab- lish at this stage that nutrition is maintained as a key focal area of the plan and that the key interventions are implemented. Nutrition-sensitive agriculture and food security. None of the current pro- grams has been evaluated from a nutrition perspective. Therefore, it will be important to investigate the potential linkages between agriculture and improved nutritional status in the Egyptian context before seeking to scale up the existing programs. Social protection and safety nets. A large number of social protection schemes and safety nets are in place in Egypt, covering a large proportion of the popu- lation. However, only the conditional cash transfer program, Takaful, focuses on improving the health and nutrition outcomes (along with education) of poor households. A recent evaluation by Breisinger et al. (2018) suggests that the program is already having some impact on nutrition outcomes, and the current pilot in three governorates in Upper Egypt aims to improve nutrition outcomes further. Once the pilot is finalized and the program further evalu- ated, the scope to scale up nationwide can be assessed. Early childhood development. A countrywide initiative was recently launched to reorganize, revamp, and scale up a comprehensive early child- hood development program, starting from motherhood through birth and infancy and up to preschool and early primary school. However, because it will take some time to fully develop, assess, and scale up this emerging ECD model, it is too early to understand whether it will have an impact on nutri- tion outcomes. Child education. Evidence suggests that health education in public schools in Egypt currently does not focus on nutrition and healthy lifestyles and therefore is unlikely to have any impact on nutrition outcomes. School feeding is primarily aimed at encouraging enrollment and attendance at school and supporting learning by alleviating short-term hunger. Thus it is likely having only modest effects on health and nutrition outcomes. There is also the question of cost-­ effectiveness in relation to other alternatives. 92 | Scaling Up Nutrition in the Arab Republic of Egypt APPROACHES TO SCALING UP THE IDENTIFIED INTERVENTIONS The interventions identified in this chapter could be scaled up in various ways. This section considers the alternative options of (1) scale-up by intervention to full national coverage, (2) scale-up by region, and (3) scale-up by prioritizing interventions. Scale-up by intervention to full national coverage A full scale-up of the complete intervention package outlined in this chapter would take time, depending on when the capacities and resources needed to expand the whole package nationwide are made available. However, they would also result in the most comprehensive coverage and, based on the evi- dence in the Lancet series (Lancet 2008 and 2013) and the current Egyptian context, the would have the greatest impact on stunting through the existing delivery platforms. The advantages and disadvantages of this approach are outlined in table 3.11. Scale-up by region First tackling the nutrition issues in regions with a higher prevalence of mal- nutrition (for example, where stunting rates are higher) and then extending efforts to other regions with lesser prevalence are often considered desirable for equity and to have the biggest impact in the shortest time. This report has shown that certain geographic areas in Egypt see a higher prevalence of many nutrition problems. And many of these areas, but not all of them, are pockets of poverty. The advantages and disadvantages of this method are summarized in table 3.12. Scale-up by prioritizing interventions For several reasons, policy makers may be inclined to prioritize the scale-up of certain interventions in a nutrition package. For example, when a single effective intervention is available for the control of a particular disorder, such ­ as salt iodization for iodine deficiency. This intervention has been imple- mented as a stand-alone and effective intervention in many countries. However, TABLE 3.11  Advantages and disadvantages of scaling up by intervention to full national coverage ADVANTAGES DISADVANTAGES • Targets the most vulnerable populations across the whole country for the key • Not suited to dealing with all of the current interventions. nutritional priorities in Egypt (such as obesity). • Likely to have the largest impact on stunting. • Determinants for certain nutritional issues can vary by region. • National media promotion and awareness campaigns can be carried out concurrently as the corresponding services and activities become available • The highest cost of all three approaches to nationwide. scale-up and sufficient funding may not be forthcoming in the short term. • Scaling up to full national coverage (rather than by region or intervention) may facilitate speedier legislative and policy action. • Need for rapid scale-up in implementation capacity. • This approach could benefit from cross fertilization and synergy of interventions. Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 93 TABLE 3.12  Advantages and disadvantages of scaling up package of interventions by region ADVANTAGES DISADVANTAGES • Targets the most vulnerable populations. • Not suitable when nutrition issues have widespread prevalence. • A (minimum) package of essential nutrition • Not suitable if the data available are not representative of regions interventions can demonstrate important synergies (for example, data are nationally representative, but not representative at and the need for a multisectoral approach. governorate level). • Could serve as its own pilot and facilitate • National media promotion and awareness campaigns usually not suitable subsequent scaling up. if corresponding services and activities are only available in limited areas. • Highest return on investment can be used to • Can create political problems if resources for scaling up are not forthcoming. showcase the importance of nutrition investment. • Difficult to champion for speedy legislative and policy action. • May be possible to spread out investment costs and • Determinants of certain nutrition issues can vary by region. to focus on oversight and management capacity. TABLE 3.13  Advantages and disadvantages of scaling up by intervention ADVANTAGES DISADVANTAGES • Draws national attention and efforts toward a unified goal (such as the schistosomiasis • Not suited to dealing with all of campaigns in the 1980s). the current nutrition priorities in Egypt (stunting, anemia, and • Can potentially demonstrate efficacy and effectiveness, thereby facilitating funding for obesity). additional interventions. • Takes a longer time to achieve • Efficacy will help gain the support of stakeholders involved in other nutrition-sensitive complete scale-up of a national interventions. nutrition package. • Can adopt a life cycle sequence, starting with interventions targeting pregnant women, • Other nutrition problems may then infants, etc. worsen. • Government can continue building capacity as resources become available. • Undermines the multidimensional • Lessons learned for future interventions can benefit from the different regional contexts nature of nutrition. across Egypt. • Does not benefit from cross- • Mass media campaigns for promotion and awareness can be more focused. fertilization and synergy of • Quicker legislative and policy action. interventions. in most developing nations a sole nutrition problem seldom exists. The fact that nutrients are delivered to bodies through foods in different variations and combinations makes a sole nutrient deficiency fairly uncommon. The different determinants of anemia and the vicious cycle of malnutrition and infection are other examples of how different interventions are often needed to combat a single problem. Thus the decision of what should be prioritized warrants care- ful consideration. Another approach is to prioritize scale-up of interventions in the package by their perceived cost-effectiveness—that is, which ones will potentially have the biggest impact on reducing stunting, for example, for the lowest cost. This may be an appropriate approach in resource-constrained settings. Several criteria could be used to determine which interventions should be given priority such as (1) the severity of the public health problem at hand; (2) the estimated costs and benefits; (3) the duration and complexity of the intervention; (4) the infrastructure and human capacity needed; and (5) the speed and feasibility by which a program can be scaled up. The advantages and disadvantages of scale-up by intervention are summarized in table 3.13. 94 | Scaling Up Nutrition in the Arab Republic of Egypt ELEMENTS CRITICAL TO SCALE-UP SUCCESS Strengthening the health system Because the majority of the nutrition interventions proposed are delivered through the health system, strengthening of this system is fundamental to the success of a nutrition scale-up plan. The most prominent health platforms in Egypt that deliver the majority of nutrition interventions are antenatal care, well-baby clinic visits, community-based nutrition programs (presently usually child-oriented but can be extended to women), and child health days. Egypt is set to undergo major health care system reform and health sector restructuring, which is expected to improve public health care dramatically in terms of quality and equity. All the goals associated with improving and strength- ening the health system directly affect nutrition, and thus this reform is yet another opportunity to integrate the plan to improve, scale up, and strengthen nutrition programs and interventions (WHO 2007). For example, the health workforce should be trained regularly to conduct routine nutrition screening, documentation of nutrition service delivery, and education and counseling of patients and families. Similarly, the information system should incorporate nutri- tion indicators and outcomes in routine health services. The WHO health systems framework outlines the necessary health system building blocks and the path to achieving overall goals through quality and safe services. Coverage and access are not sufficient for achieving the outcomes of the WHO strategy if Egyptians do not use the available services and programs. The beneficiary is a key participant in the access/coverage/utilization triangle, and thus advocacy and the sensitization of the community to these services are fundamental. Multisectoral involvement of ministries and partners The MOHP is intricately involved in all the interventions selected and particu- larly the nutrition-specific interventions. However, other ministries will be closely involved and even lead when the health sector is not the main partner. The critical roles and contributions of nonhealth ministries should not be ignored. For example, adequate complementary feeding practices, including the consumption of diverse diets rich in iron and vitamin A, are not translatable into practices if the targeted populations are food-insecure. This demonstrates the role that ministries such as MOALR and MOSS can play. Complementary feed- ing practices, WASH, and deworming interventions would not be effective with- out the involvement of MOE, MOALR, and MOWRI. These are only a few examples that illustrate the need for an interministerial nutrition coordinating committee at the national level and multisectoral management committees at the lower administrative levels. Positioning a multisectoral coordinating committee under the MOHP, as in many African countries, will usually lead to difficulties in convening with other line ministries. This should be avoided, but it is likewise not advisable to margin- alize the role of the health sector while health-based nutrition services are still serving as the frontline in preventing and treating the most severe forms of mal- nutrition. However, they also do not address the whole life cycle of malnutrition nor the underlying and basic causes. This factor demonstrates the need to give the health sector strong support and recognition, while establishing strong leader- ship across ministries by, for example, having the prime minister serve as the Undernutrition Interventions in Egypt: Status, Gaps, and Opportunities | 95 chair of the National Nutrition Coordinating Committee. Work is presently ongo- ing to update the national nutrition policy and programming frameworks, and it is anticipated that multisectoral and multistakeholder nutrition coordination and management structures and mechanisms will be reviewed and defined as part of this process. The integration of nutrition indicators across sectors will be critical to developing a common results framework and granting a sense of ownership, responsibility, and eventual accountability. This effort calls for the involve- ment of the various ministries early in the planning phase and will help ­identify resource and capacity gaps and prevent shortcomings in the implementation phase. In addition, a broader interagency committee should involve stakehold- ers from the private sector, civil society organizations (CSOs), international agencies, and NGOs. NOTES 1. Growth monitoring and promotion is normally not considered a highly effective nutrition intervention, but growth monitoring—if done properly—is normally a good tool to enhance the effectiveness of IYCF and other growth promotion efforts because it will allow the child caretaker and the nurse or nutrition counsellor to jointly see the success of their efforts to safeguard the healthy growth of the child. In Egypt, GMP is still the term pre- ferred for this combined monitoring and promotion activity. 2. Baladi bread is the most consumed staple in Egypt and is part of its long-standing food subsidy program. However, it is nontargeted and so operates on a first-come, first- served basis. According to the WFP Analysis of Consumer Profiles and Behaviour Patterns, 80 percent of urban households and 65 percent of rural households consume this bread. 3. The Egypt Strategy Support Program (Egypt SSP) of the International Food Policy Research Institute (IFPRI) is a policy research, capacity strengthening, and communication program that seeks raise the incomes of the rural poor and improve food and nutrition security in Egypt.  4. World Bank, Country Data—Egypt. https://data.worldbank.org/country/egypt-arab-rep. 5. UNICEF Middle East and North Africa Out-of-School Children Initiative, http://www​ .oosci-mena.org. 6. https://www.egyptianfoodbank.com/en/program/school-feeding-program. 7. 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Wang. 2014. “The Association Between Breastfeeding and Childhood Obesity: A Meta-analysis.” BMC Public Health 14: 1267. 4 Cost-Effectiveness of Potential Scale-Up Scenarios in Egypt DAVIDE DE BENI KEY MESSAGES • This chapter analyzes the three scale-up scenarios outlined in chapter 3, calculating the cost, expected cost-benefits, and cost-effectiveness to deter- ­ mine which will bring the greatest returns. • Because of the methodology used (LiST Model), only 13 of the 16 chosen interventions could be modeled against the three scale-up scenarios (full national coverage, interventions by region, prioritization of interventions). • To reach the highest number of stunted children, Egypt should prioritize funding the most cost-effective interventions, which achieves the same result as full coverage: infant and young child feeding (especially promoting com- plementary feeding), iron–folic acid supplementation, vitamin A supplemen- tation of children, and promotion of hygienic disposal of children’s stools (421,360 cases of stunting averted). • When comparing costs and benefits, if the main priority is the reduction of stunting, delivering only the most cost-effective interventions to reduce stunting provides better value for the money (cost per death prevented, $19,412; cost per stunting case prevented, $196). • Giving priority to implementation of the most cost-effective interventions for stunting reduction is estimated to translate into and return the highest eco- nomic benefits over the productive lives of children who receive the interven- tions (a return of $17.87 in economic benefits for each dollar invested). • However, focusing only on those interventions that are most effective in reducing stunting will not have any impact on the current levels of wasting and will only prevent 4,249 additional deaths (30 percent of the full national coverage scenario). INTRODUCTION This chapter analyzes the three scenarios for scaling up selected nutrition inter- ventions described in chapter 3 and calculates the cost, expected cost-benefits  101 102 | Scaling Up Nutrition in the Arab Republic of Egypt (including possibly the social returns on investments), and cost-effectiveness. The objectives of this analysis are as follows: • To estimate the costs of a set of nutrition interventions that have the potential to be scaled up through tested delivery mechanisms in Egypt • To conduct a basic economic analysis to calculate the potential benefits and cost effectiveness associated with the proposed scale-up • To estimate the economic benefits of scaling up nutrition interventions in Egypt • To propose a series of scenarios for a costed scale-up plan that rolls out this package of nutrition interventions in phases, based on considerations of impact, geography, implementation capacity, and costs. METHODOLOGY Scope of the analysis and description of the interventions The following estimates of the costs and benefits of scaling up a set of selected nutrition-specific and nutrition-sensitive interventions are based on those dis- cussed in chapter 3. Table 3.10 in chapter 3 outlines the 16 elected interventions, which are mostly supported by scientific evidence on their potential impact on stunting, particularly from the 2008 and 2013 Lancet series on maternal and child nutrition, and which have the potential to be scaled up rapidly in Egypt using the existing mechanisms and infrastructure. As for other interventions dis- cussed in chapter 3, either evidence is lacking on their effectiveness to reduce child malnutrition, or in some cases potentially effective programs are still being developed, such as those targeting overweight, or are being evaluated, such as the Takaful conditional cash transfer (CCT) program. Furthermore, of the 16 interventions that could effectively be scaled up, not all can be modeled using the impact tool adopted for this study. The Lives Saved Tool (LiST) estimates the global health impacts of scaling up key interventions by modeling outcomes around neonatal, child, and maternal mortality and birth outcomes and nutrition outcomes, among others. Its wide range of interventions include periconceptual, pregnancy, childbirth, breastfeeding, preventive, vac- cines, and curative. Of the 16 selected interventions, 13 are modeled in LiST as shown in table 4.1 with the associated target groups. These interventions are grouped into four sep- arate packages that are in line with the groups of key interventions in the LiST model that can have an impact on specific outcomes: (1) infant and young child feeding (IYCF) and micronutrients; (2) curative interventions; (3) disease pre- vention and management; and (4) water, sanitation, and hygiene (WASH). The three interventions not modeled in LiST are growth monitoring and promotion, iron supplementation for children 6–59 months of age, and deworming. The associated drawbacks of this methodological limitation are discussed later in this chapter. The expenditures estimated in this model are the financial costs of the goods and services required to deliver each of the interventions from a supply-side pro- spective.1 They do not reflect the full economic and social value of how resources could be used differently, such as the opportunity costs (for example, lost wages) of the time spent by beneficiaries seeking and accessing health services. Cost-Effectiveness of Potential Scale-Up Scenarios in Egypt | 103 TABLE 4.1  Nutrition-specific and nutrition-sensitive interventions included in the analysis INTERVENTION DESCRIPTION TARGET POPULATION Infant and young child feeding (IYCF) and micronutrients Promotion and support of 1.  Communication of optimal breastfeeding practices Pregnant women and mothers breastfeeding of children 0-6 months Promotion of complementary 2.  Communication of complementary feeding practices (excluding Mothers of children 6–23 feeding provision of food) months Iron–folic acid 3.  Three months supplementation of iron–folic acid during Pregnant women supplementation pregnancy Vitamin A supplementation 4.  Biannual supplementation of vitamin A capsulesa Children 6–59 months (children) Curative interventions (MAM/SAM) Treatment of moderate acute 5.  Treatment of MAM in supplementary feeding programs Children 6–59 months malnutrition (MAM) Management of severe acute 6.  Severely malnourished children admitted to either inpatient or Children 6–59 months malnutrition (SAM) outpatient therapeutic feeding programs Disease prevention and management Treatment of diarrhea (ORS) 7.  Management of mild and moderate diarrhea with oral Children 6–59 months rehydration solution (ORS) Therapeutic zinc 8.  As part of diarrhea management with ORS Children 6–59 months supplementation Water, sanitation, and hygiene (WASH) 9. Use of improved water source Regulation and advocacy activities to ensure access to water All households supply services from an “improved” source within 1 kilometer of the user’s dwelling. An improved source is one that is likely to provide “safe” water Use of water connection in 10.  Regulation and advocacy activities to ensure access to safe All households home water from a household connection Improved excreta disposal 11.  Promotional activities to ensure access to improved/hygienic All households (latrine/toilet) excreta disposal (access to improved latrine or flush toilet) 12. Hand washing with soap Promotional activities for “appropriate” hand washing behavior All households Hygienic disposal of children’s Promotional activities for the proper disposal of children’s stools 13.  All households stools a. The cost-effectiveness analysis of vitamin A supplementation is based on optimal implementation of the biannual protocol as recommended by World Health Organization (WHO) guidelines: one-time vitamin A (100,000 international units, IU) for infants 6–11 months (one dose) per first year and one-time vitamin A (200,000 IU) for children 12–59 months every four to six months. At the time of writing this report, the 200,000 IU dose is given in Egypt only once, at 18 months, instead of two times as per the WHO recommendations. Scale-up scenarios and coverage levels This economic analysis of the three scale-up scenarios for increasing coverage of selected nutrition interventions uses 2017 as a baseline year and considers the five-year time frame 2018–22. The three scenarios are defined as follows: 1. Scale up by intervention to full national coverage: 90 percent of currently implemented interventions—80 percent for moderate acute malnutrition (MAM)/severe acute malnutrition (SAM) interventions, (scenario 1) 2. Scale up by region: prioritize full package only in region group with highest burden of stunting (scenario 2) 3. Scale up by prioritizing interventions: scale up to full national coverage the most cost-effective interventions to reduce stunting (scenario 3). 104 | Scaling Up Nutrition in the Arab Republic of Egypt An additional scenario would consist of simply maintaining the current cov- erage of the existing interventions. The analysis assumes that coverage for each intervention increases linearly at a constant rate from the baseline year (2017) to the target coverage rates over the five-year period to 2022, as described in table 4.2. The current baseline coverage levels were obtained from different sources. In the absence of most recent data, the 2014 Egypt Demographic and Health Survey (EDHS 2014) was maintained as the primary official reference (MOHP, El-Zanaty and Associates, and ICF International 2015), and the Nutrition Stakeholder and Action Mapping Report was used as an additional resource where necessary (MOHP and UNICEF 2017). Methodology for calculating unit costs for each intervention The default treatment inputs and prices used in this analysis are global standards not specific to Egypt. Unit costs for each intervention were obtained from the OneHealth Tool2 costing module, which provides a way to estimate the financial and human resources required to deliver nutrition services to beneficiaries. Intervention unit costs include the required drugs and consumable supplies (such as gloves and syringes), direct staff time, and number of inpatient days and outpatient visits needed to effectively provide an intervention. These factors are drawn from the intervention assumptions developed for the OneHealth Tool, TABLE 4.2  Baseline and target coverage rates per intervention BASELINE FULL NATIONAL INTERVENTION COVERAGE (2017) SOURCE COVERAGE Infant and young child feeding (IYCF) and micronutrients 1. Breastfeeding promotion and support 62.0% Nutrition Stakeholder and Action Mapping 90.0% Report, 2017 2. Complementary feeding promotion 62.0% Nutrition Stakeholder and Action Mapping 90.0% Report, 2017 3. Iron-folic acid supplementation (pregnant 36.1% Egypt Demographic and Health Survey (EDHS) 90.0% women) 2014 4. Vitamin A supplementation (children) 75.0% Nutrition Stakeholder and Action Mapping 90.0% Report, 2017 Curative interventions (SAM/MAM) 5. Treatment of moderate acute malnutrition 0.0% New intervention 80.0% (MAM) 6. Management of severe acute malnutrition 0.0% New intervention 80.0% (SAM) Disease prevention and management 7. Treatment of diarrhea (ORS) 28.4% EDHS 2014 90.0% 8. Therapeutic zinc supplementation 0.3% UNICEF, Egypt 90.0% Water, sanitation, and hygiene (WASH) 9. Use of improved water source 97.8% EDHS 2014 97.7% 10. Use of water connection in home 90.9% EDHS 2014 90.9% 11. Improved excreta disposal 90.1% EDHS 2014 90.1% 12. Hand washing with soap 96.1% UNICEF, Egypt 96.1% 13. Hygienic disposal of children’s stools 60.8% EDHS 2014 90.0% Sources: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015); Nutrition Stakeholder and Action Mapping Report (MOHP and UNICEF 2017). Note: ORS = oral rehydration solution. Cost-Effectiveness of Potential Scale-Up Scenarios in Egypt | 105 based on the World Health Organization (WHO) norms and guidelines where available, and from expert input where explicit guidance was not available. Drugs and consumable supply prices are extracted from international sources such as the MSH Drug Price Indicator Guide, UNICEF supply catalogue, and the Global Price Reporting Mechanism. Staff cost data are based on assumptions for salaries, benefits, and time utilization drawn from WHO-CHOICE (Choosing Interventions that Are Cost-Effective).3 These data points are used to estimate a cost per minute for delivering the various interventions. Program costs are added to unit costs as a percentage of direct costs (such as for drugs and supplies and staff time), and they are intended to capture the service delivery costs associated with the interventions. These costs include those for training, supervision, monitoring and evaluation, equipment, advocacy and communication, and media and outreach. Default program cost categories and percentages have been provided based on the Scaling Up Nutrition (SUN) nutrition plan costing exercises, the Education Program for Immunization Competencies (EPIC) immunization studies, and WHO (see details in table 4.3). The unit costs for the 13 interventions analyzed in this study appear in table 4.4. Methodology for calculating total and annual scale-up costs The analysis estimates the costs of increasing coverage of a set of nutrition inter- ventions in Egypt from the current coverage rates to target rates defined for each scale-up scenario. The total scale-up costs per intervention (or set of interven- tions) over the five-year period are obtained by the product of the unit costs and the number of cases (beneficiaries) per intervention per year total scale-up costs = UC * NC TABLE 4.3  Default program cost categories and percentages CATEGORY PERCENTAGE SOURCE Program-specific human 1 Lives Saved Tool (LiST) resources Training 1 EPIC studies Supervision 2 EPIC studies Monitoring and evaluation 2 EPIC studies Infrastructure 2 NASA Transport 2 Comprehensive vaccine planning (WHO) Communication, media, 1 SUN-costed nutrition plans and outreach Advocacy 1 EPIC studies General program 2 EPIC studies management Community health worker 1 Expert estimates (no data) training Total 15 Note: EPIC = Education Program for Immunization Competencies; NASA = National AIDS Spending Assessment; SUN = Scaling Up Nutrition; WHO = World Health Organization. 106 | Scaling Up Nutrition in the Arab Republic of Egypt TABLE 4.4  Unit costs per average case by intervention INTERVENTION TARGET POPULATION UNIT COST (US$) Promotion and support of breastfeeding Pregnant women and mothers of children 0–6 months 8.47 Promotion of complementary feeding Mothers of children 6–23 months 3.45 Iron–folic acid supplementation Pregnant women 3.36 Vitamin A supplementation (children) Children 6–59 months 1.68 Treatment of moderate acute malnutrition (MAM) Children 6–59 months 53.89 Management of severe acute malnutrition (SAM) Children 6–59 months 201.47 Treatment of diarrhea (oral rehydration solution) Children 6–59 months 1.43 Therapeutic zinc supplementation Children 6–59 months 4.26 Use of improved water source All households 0.51 Use of water connection in home All households 0.51 Improved excreta disposal (latrine/toilet) All households 0.51 Hand washing with soap All households 0.51 Hygienic disposal of children’s stools All households 0.51 Source: Unit costs: WHO OneHealth Tool, http://www.who.int/choice/onehealthtool/en/. where UC is the unit cost of the intervention, and NC is the number of cases per intervention each year. The number of cases per intervention each year is based on the size of the tar- get population, population in need, and coverage rates as expressed by number of cases = size of target population * population in need (%) * coverage (%) where target population is defined as the population that could possibly receive the intervention. Examples of target populations include pregnant women and children 6–59 months of age. Population in need (%) is the share of the target population requiring the intervention per year. For most preventive care interventions, the share will be 100 percent. For example, daily iron and folic acid supplementation will be required for all pregnant women. The population in need can be interpreted as the incidence and prevalence of conditions for interventions such as treatment of MAM or SAM. Coverage (%) refers to how many people in the population in need are receiving the intervention. It  ­ indicates the baseline intervention coverage of the population in need and ­ targeted scale-up over the selected five-year period. Estimating benefits and cost-effectiveness LiST (version 5.61) is used to calculate the expected effects of each scale-up sce- nario on the under-5 mortality rate, number of lives saved, prevalence of stunting and wasting among children under 5, prevalence of exclusive breastfeeding, prevalence of anemia in pregnant women, and disability-adjusted life years (DALYs) saved. LiST is an epidemiological model created as part of the work undertaken for the 2003 Lancet child survival series. It estimates the impact of expanding coverage of maternal and child health and nutrition interventions on the mortality, morbidity, and nutritional status of children under 5. The estima- tion of DALYs averted for each intervention and scale-up scenario is based on Bhutta et al. (2008): one life saved equals 33 DALYs averted; one case of stunting averted equals 0.23 DALYs averted. Cost-Effectiveness of Potential Scale-Up Scenarios in Egypt | 107 Cost-effectiveness analysis is used to identify the interventions and scale-up scenarios that produce the most impact for the least cost. Ratios of costs to esti- mates of impact are calculated for (1) deaths prevented in children under 5 (Lives Saved), (2) cases of stunting averted, and (3) number of DALYs averted. The scale-up scenario with the lowest cost per benefit is considered to be the most cost-effective among the alternatives under analysis. The evaluation of the cost-effectiveness ratio in absolute terms is based on the categorization used by WHO-CHOICE.4 Estimating economic benefits The cost-benefit analysis is based on the estimated economic value of the ben- efits attributable to the reductions in under-5 mortality and stunting preva- lence, which in turn are attributable to scaling up the nutrition interventions contained in each scenario. LiST is used to estimate the number of lives saved and the reduction in stunting prevalence. Following established practice, a life year saved is valuated as equivalent to gross domestic product (GDP) per capita (current U.S. dollars, 2015). This is a conservative measure because it ­ accounts only for the economic and not the social value of a year of life. To estimate the economic benefits generated from the reductions in stunting prevalence, the methodology used in Hoddinott et al. (2013) is applied, which valuates a year of life lived without stunting as a 21 percent increase in wage earnings. Limitations of the methodology used The cost estimates presented in this study are highly dependent on the assumptions made in terms of health status, nutrition indicators, and current coverage of the interventions. In the absence of more recent data, EDHS 2014 is maintained as the primary official reference even though it does not reflect the latest nutrition programs in Egypt (MOHP, El-Zanaty and Associates, and ICF International 2015). The Nutrition Stakeholder and Action Mapping Report of 2016 is used for coverage data not available in EDHS 2014 (MOHP and UNICEF 2017). Unit costs for each intervention are obtained from the OneHealth Tool cost- ing module and are not specific to the Egyptian context. These costs are drawn from intervention assumptions developed for the OneHealth Tool, adopting the so-called ingredient approach, and based on WHO norms and guidelines. This methodology has the disadvantage of potentially underestimating the real cost of implementing the programs in Egypt and potentially omitting wastages or inef- ficiencies. Furthermore, the study team added program costs as a fixed percent- age of direct costs. It is then not possible to account for the potential economy of scale or the need to expand capital costs to account for significant scaling up of program activities over a relatively short period. As described in the introduction to this chapter, this analysis only estimates the costs and benefits of those interventions currently modeled in LiST, which includes only 13 of the 16 interventions outlined in chapter 3 as having the most potential to be scaled up in the short to medium term to substantially improve the nutrition situation in Egypt. Therefore, because of data and methodological shortcomings, this analysis cannot produce the full scale of the potential benefits of scaling up the packages of nutrition interventions described and discussed in this report. 108 | Scaling Up Nutrition in the Arab Republic of Egypt FINDINGS Cost of scaling up nutrition in Egypt Estimation of spending at current coverage level (2017) The total estimated resources required for maintaining current coverage of the existing interventions for the period 2018–22 is $561 million, or an average of $112 million a year (table 4.5). The high cost required to implement the WASH package ($54 million a year) is driven by the high coverage assumptions used for this set of interventions. IYCF and micronutrients cost $39 million a year, of which $16 million is required to maintain the current coverage of vitamin A sup- plementation for children—estimated at 75 percent in the Nutrition Stakeholder and Action Mapping Report (MOHP and UNICEF 2017). Despite the relatively low coverage of therapeutic zinc supplementation (0.3 percent, according to UNICEF Egypt) because of its relatively high unit cost ($4.26 to treat one child a year), $14 million a year is required to maintain the current coverage. The man- agement of acute malnutrition (MAM/SAM) is currently not implemented at scale in Egypt, and therefore no costs are included in the table. Figure 4.1 shows the breakdown of the current annual requirements by gov- ernorate. About 50 percent of the estimated annual resources are allocated to seven governorates (Giza, Cairo, Beheira, Sharqia, Dakahlia, Asyut, and Qalyubia) because of the large size of their populations of children under 5 and pregnant women and their high burden of stunting and coverage of interven- tions. The significant allocation of resources for Beheira and Asyut is driven by high coverage of disease prevention and management interventions, particu- larly those for the treatment of diarrhea. TABLE 4.5  Total and annual costs for current coverage scenario TOTAL COST ANNUAL COST TOTAL COST ANNUAL COST CURRENT COVERAGE SCENARIO (LE, MILLIONS) (LE, MILLIONS) (US$, MILLIONS) (US$, MILLIONS) Infant and young child feeding (IYCF) and micronutrients 3,550 710 197 39 Promotion and support of breastfeeding 857 171 48 10 Promotion of complementary feeding 1,077 215 60 12 Iron–folic acid supplementation 219 44 12 2 Vitamin A supplementation (children) 1,397 279 78 16 Management of acute malnutrition — — — — Treatment of moderate acute malnutrition (MAM) — — — — Management of severe acute malnutrition (SAM) — — — — Disease prevention and management 1,679 336 93 19 Treatment of diarrhea (oral rehydration solution) 422 84 23 5 Therapeutic zinc supplementation 1,257 251 70 14 Water, sanitation, and hygiene (WASH) 4,867 973 270 54 Use of improved water source 1,092 218 61 12 Use of water connection in home 1,016 203 56 11 Improved excreta disposal (latrine/toilet) 1,007 201 56 11 Hand washing with soap 1,074 215 60 12 Hygienic disposal of children’s stools 679 136 38 8 Total current coverage scenario 10,096 2,019 561 112 Source: Based on unit costs from the WHO OneHealth Tool, http://www.who.int/choice/onehealthtool/en/. Note: Because the management of acute malnutrition (MAM/SAM) is currently not implemented at scale in Egypt, no costs are included in the table. LE = Egyption pound. Cost-Effectiveness of Potential Scale-Up Scenarios in Egypt | 109 FIGURE 4.1 Estimated annual expenditure by governorate of maintaining interventions at current coverage 10 9 12 8 Estimated annual expenditure (US$, millions) 9 8 7 7 10 8 6 6 7 Population (millions) 6 6 8 6 5 5 5 5 4 4 6 4 3 3 4 3 2 2 2 1 1 2 1 1 1 1 1 0 0 0 0 0 C a Ism etta Be airo M ia Al o ia Be Qe h a lia ha a on ia D i Su a As ilia ak ia fr Fa fia -S m L n h So V ea al ut a g No Ma ez h y rt or i Ne ed nai Suid i f iz na Sh eir G iny n n ik a rth tru ut alle am e ex ha b rb M ndr D rq el iyu ah Q Asy w S Po ux w u Sa G a he yu Si R Si h a S Ka WASH Disease prevention and management IYCF and micronutrients Population Source: Estimated annual expenditures based on unit costs obtained from the WHO OneHealth Tool, http://www​ .who.int/choice/onehealthtool/en/. Population: UN 2017. Note: Percentage of annual expenditures by governorate appears above bars. IYCF = infant and young child feeding; WASH = water, sanitation, and hygiene. Estimation of costs for full coverage (scenario 1) Scaling up the existing package of nutrition interventions to full national cover- age (90 percent) and implementing the treatment of MAM and SAM nationwide to 80 percent coverage will require an additional $1,132 million over the period 2018–22 (figure 4.2). For this scenario, disease prevention and management and the treatment of acute malnutrition would account for the biggest expenditure increase (table 4.6). The cost rise for the disease prevention and management category is explained by the scaling up of zinc supplementation, from 0.3 percent to 90 percent coverage, because of the high number of beneficiaries to reach and the relatively high unit cost of this intervention ($4.26). For the same reasons, MAM/SAM treatment would require significant financial resources ($61 ­million a year). WASH’s financial requirement will not change substantially over current coverage because it is already implemented at scale throughout the nation (according to current coverage rates). Reaching 90 percent coverage nation- wide for IYCF and micronutrient interventions would require an additional $52 million per year. Ensuring full national coverage is based on the anticipated increases in capac- ity levels as the interventions are implemented. To ensure that adequate capacity is developed, 15 percent of the additional cost of interventions ($30 million a year) is added to invest in strengthening the health system to address malnutri- tion across sectors. 110 | Scaling Up Nutrition in the Arab Republic of Egypt FIGURE 4.2 Annual financing requirements of maintaining current interventions and expanding to full national coverage by 2022 500 Financing requirements (US$, millions) 450 400 350 US$1,132 million in additional 300 expenditures required 250 to reach full national coverage 200 150 US$561 million in 100 expenditures required 50 to maintain current coverage level 0 (2018–22) 2018 2019 2020 2021 2022 Expenditures at current coverage level Management of severe and acute malnutrition System strengthening for program delivery Disease prevention and management IYCF and micronutrients WASH Source: Financing requirements based on unit costs obtained from the WHO OneHealth Tool, http://www.who​ int/choice/onehealthtool/en/, and population projections from UN 2017. .­ Note: IYCF = infant and young child feeding; WASH = water, sanitation, and hygiene. TABLE 4.6  Total and annual costs for full national coverage scenario TOTAL COST ANNUAL COST TOTAL COST ANNUAL COST FULL NATIONAL COVERAGE SCENARIO (LE, MILLIONS) (LE, MILLIONS) (US$, MILLIONS) (US$, MILLIONS) Infant young child feeding and micronutrients 4,643 929 258 52 Promotion and support of breastfeeding 1,176 235 65 13 Promotion of complementary feeding 1,489 298 83 17 Iron–folic acid supplementation 419 84 23 5 Vitamin A supplementation (children) 1,559 312 87 17 Management of acute malnutrition 5,527 1,105 307 61 Treatment of moderate acute malnutrition (MAM) 701 140 39 8 Management of severe acute malnutrition (SAM) 4,826 965 268 54 Disease prevention and management 12,587 2,517 699 140 Treatment of diarrhea (oral rehydration solution) 3,163 633 176 35 Therapeutic zinc supplementation 9,424 1,885 524 105 Water, sanitation, and hygiene (WASH) 5,065 1,013 281 56 Use of improved water source 1,092 218 61 12 Use of water connection in home 1,016 203 56 11 Improved excreta disposal (latrine/toilet) 1,007 201 56 11 Hand washing with soap 1,074 215 60 12 Hygienic disposal of children’s stools 877 175 49 10 System strengthening for program delivery 2,659 532 148 30 Total, full national coverage scenario 30,481 6,096 1,693 339 Source: Based on unit costs from the WHO OneHealth Tool, http://www.who.int/choice/onehealthtool/en/. Note: LE = Egyptian pound. Cost-Effectiveness of Potential Scale-Up Scenarios in Egypt | 111 Benefits of scaling up nutrition in Egypt Estimating health and nutrition impacts using the Lives Saved Tool (LiST) Using LiST, the expected benefits of the nutrition interventions contained in each scale-up scenario are assessed in terms of the (1) under-5 mortality rate; (2) number of lives saved; (3) cases and prevalence of stunting; (4) prevalence of wasting among children under 5; (5) prevalence of anemia in pregnant women; and (6) exclusive breastfeeding prevalence. LiST predicts changes for each of these rates and prevalence using changes in coverage of each intervention for the period considered in the analysis, 2018–22. Expected benefits are computed using a deterministic mathematical model based on the best available scientific evidence of the cause-specific effectiveness estimates for each intervention. For each of the packages of interventions modeled in this analysis, the specific path- ways and the relationships between interventions and outcomes used in LiST are shown in figures 4.3, 4.4, 4.5, and 4.6. FIGURE 4.3 LiST underlying model for estimating impacts of nutrition preventive interventions: IYCF and micronutrients Interventions Risk factors Causes of death Stillbirth intrapartum Multiple micronutrient supplementation (iron and multiple micronutrients) Stillbirth antepartum in pregnancy Maternal mortality: postpartum hemorrhage Maternal anemia Maternal mortality: intrapartum hemorrhage Iron supplementation in pregnancy Maternal mortality: antepartum hemorrhage Subjective global assessment (SGA) Neonatal mortality: asphyxia Neonatal mortality: sepsis Neonatal mortality: pneumonia KMC (kangaroo mother care) Neonatal mortality: diarrhea Exclusive and continued breastfeeding Breastfeeding promotion Child (1–59 months) mortality: pertussis Diarrhea incidence Child (1–59 months) Complementary feeding: mortality: meningitis education only Stunting Child (1–59 months) Vitamin A supplementation mortality: pneumonia Complementary feeding: supplementary feeding and education Wasting Child (1–59 months) mortality: measles Child (1–59 months) mortality: diarrhea Child (1–59 months) mortality: other causes Source: https://listvisualizer.org/, © Lives Saved Tool (LiST). Reproduced with permission from Lives Saved Tool (LiST); further permission required for reuse. Note: IYCF = infant and young child feeding. 112 | Scaling Up Nutrition in the Arab Republic of Egypt FIGURE 4.4 LiST underlying model for estimating impacts of nutrition curative interventions: MAM and SAM Interventions Risk factors Causes of death Child (1–59 months) mortality: pneumonia Treatment for severe acute Child (1–59 months) malnutrition (SAM) mortality: measles Complementary feeding: Child (1–59 months) Wasting supplementary feeding and education mortality: diarrhea Treatment for moderate acute Child (1–59 months) malnutrition (MAM) mortality: other causes Child (1–59 months) mortality: meningitis Source: https://listvisualizer.org/, © Lives Saved Tool (LiST). Reproduced with permission from Lives Saved Tool (LiST); further permission required for reuse. Note: MAM = moderate acute malnutrition; SAM = severe acute malnutrition. FIGURE 4.5 LiST underlying model for estimating impacts of maternal, neonatal, and child health interventions Interventions Causes of death Child (1–59 months) mortality: Zinc for treatment of diarrhea diarrhea Oral rehydration solution (ORS) Neonatal mortality: diarrhea Source: https://listvisualizer.org/, © Lives Saved Tool (LiST). Reproduced with permission from Lives Saved Tool (LiST); further permission required for reuse. FIGURE 4.6 LiST underlying model for estimating impacts of water, sanitation, and hygiene interventions Interventions Risk factors Causes of death Handwashing Use of piped water in the home Neonatal mortality: diarrhea Hygienic disposal of children’s stool Diarrhea incidence Child (1–59 months) mortality: diarrhea Use of improved sanitation Use of improved water source Child (1–59 months) mortality: meningitis Stunting Child (1–59 months) mortality: measles Child (1–59 months) mortality: pneumonia Child (1–59 months) mortality: other causes Source: https://listvisualizer.org/, © Lives Saved Tool (LiST). Reproduced with permission from Lives Saved Tool (LiST); further permission required for reuse. Cost-Effectiveness of Potential Scale-Up Scenarios in Egypt | 113 In LiST, the nutrition preventive interventions (including IYCF and micronu- trients) have an impact on child and neonatal mortality through their effect on stunting, diarrhea incidence, and maternal anemia. The following risk factors are thought to have a direct impact on several child (1–59 months) and neonatal causes of morbidity and mortality: measles, meningitis, pneumonia, diarrhea, sepsis, congenital anomalies, and other causes5 (figure 4.3). As mentioned earlier in this chapter, GMP, salt iodization, and deworming are not currently modeled in LiST. Thus estimates of the real impacts of implementing the full preventive package on nutritional status and child mortality may be underestimated. The package of curative interventions includes the treatment of moderate and severe acute malnutrition (MAM/SAM). According to the LiST model, these interventions have an indirect positive effect on reduction of child mortality through wasting (Bhutta et al. 2013; Lenters et al. 2013). Complementary feeding (supplementation of food and education), which is included in the package of nutrition preventive interventions, also appears in figure 4.3 because of its impact on wasting. In the LiST model, wasting increases a child’s risk of dying from five specific causes of mortality: pneumonia, meningitis, measles, diarrhea, and other causes (figure 4.4). This also means that children wasted will be much more likely to die in a country or region where the incidence of diarrhea, pneumonia, and mea- sles is high than in an area where the prevalence of those diseases is low. The maternal, neonatal, and child health (MNCH) interventions consid- ered in this analysis—oral rehydration solution (ORS) and zinc for the treat- ment of diarrhea—have a direct impact on the reduction of diarrhea as a cause-specific mortality condition for children 0–59 months of age. In Egypt, diarrhea is one of the leading causes of death in children under 5 (11 percent of child deaths are from diarrhea).6 Therefore, in this model the treatment of diarrhea with ORS and zinc is particularly effective in the reduction of child mortality (figure 4.5). The two leading causes of mortality among children under 5 in Egypt, pneumo- nia and diarrhea, are closely linked to poor water, sanitation, and hygiene. For the WASH interventions, the LiST model assumes an indirect effect on stunting through a direct reduction of diarrhea incidence for the five interventions included in this analysis: use of improved water source, use of water connection in home, improved excreta disposal, handwashing with soap, and hygienic disposal of chil- dren’s stools (Cairncross et al. 2010; Cairncross and Valdmanis 2006). In the model, as for the package of curative nutrition interventions, stunting and diarrhea incidence increase a child’s risk of dying from five specific causes of mortality: pneumonia, meningitis, measles, diarrhea, and other causes (figure 4.6). Current evidence suggests that WASH can also bring significant gains in tack- ling childhood undernutrition (Cumming and Cairncross 2016). Studies that specifically address maternal and child environmental exposures are currently under way, and they will permit the quantification of both the independent effect of WASH interventions on stunting and the combined effect of WASH and food supplementation interventions—the so-called Sanitation, Hygiene, Infant Nutrition Efficacy (SHINE) and WASH Benefits (Humphrey 2013). Benefits of scaling up to full national coverage (scenario 1) Under-5 mortality Using LiST to project scaling up the package of interventions to full national coverage shows a reduction of under-5 mortality rate from 30.0 per 1,000 live births in 2017 to 28.1 per 1,000 live births by 2022 (figure 4.7). 114 | Scaling Up Nutrition in the Arab Republic of Egypt FIGURE 4.7 Under-5 mortality rates: current and full national coverage, 2017–22 30.5 Number of deaths (per 1,000 live births) 30 30 30.0 29.5 29.0 28.5 28.1 28.0 27.5 27.0 2017 2018 2019 2020 2021 2022 Current coverage Full national coverage Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). Projections performed using Lives Saved Tool (LiST), https://listvisualizer.org/. FIGURE 4.8 Additional deaths of children 0–59 months of age prevented by scaling up interventions to full national coverage Therapeutic zinc supplementation 1,591 Treatment of diarrhea (ORS) 5,642 Management of severe acute malnutrition 1,611 (SAM) Treatment of moderate acute malnutrition 865 (MAM) Hygienic disposal of children's stools 738 Promotion and support of breastfeeding 1,643 Vitamin A supplementation (children) 410 Iron–folic acid supplementation 1,013 Promotion of complementary feeding 442 0 0 0 0 0 0 0 00 00 00 00 00 00 2, 5, 3, 4, 6, 1, Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). Estimations performed using Lives Saved Tool (LiST), https://listvisualizer.org/. Note: ORS = oral rehydration solution. Figure 4.8 depicts the additional number of lives saved by scaling up the pack- age of interventions to full national coverage. Over the period 2018–22, 13,955 more deaths would be prevented than in the current coverage scenario (assum- ing the same level of coverage for all interventions throughout the period). Cost-Effectiveness of Potential Scale-Up Scenarios in Egypt | 115 Almost half of deaths prevented would result from scaling up the treatment of diarrhea with ORS from 28 percent to 90 percent coverage nationwide (5,642 lives saved). The reasons are the direct effect of this intervention on reduction of diarrhea as a cause-specific mortality condition, and in the  ­ Egypt  diarrhea is one of the leading causes of death in children under 5 (as noted, 11 percent of child deaths are due to diarrhea).7 Stunting Experience has shown that stunting in Sub-Saharan Africa can be reduced at an average annual rate of 1.5 percent (Teller and Alva 2008).8 Bhutta et al. (2013) estimated that scaling up 10 highly effective nutrition interventions to 90 per- cent coverage over a period of 10 years would reduce stunting in 34 countries by 20 percent. Furthermore, a recent study by the World Bank estimates that scal- ing up some essential nutrition-specific and -sensitive interventions to 90 per- cent coverage over a 10-year period would lead to about a 40 percent decline in the number of stunted children in 37 high-burden countries by 2025 (Shekar et al. 2017). The Bank’s finding is in line with the target for stunting endorsed by the Sixty-fifth World Health Assembly (WHA).9 This analysis shows that the current level of stunting can be reduced by only 1.5 percentage points over five years by scaling up all interventions to full national coverage (figure 4.9). However, because stunting in previous age cohorts affects the future level of stunting, assuming that the same level of coverage will be maintained beyond 2022, the prevalence will drop, reaching 18.9 percent by 2026 from the current baseline level of 21.2 percent. If stunting is analyzed in terms of the number of stunted children in absolute terms, the full national coverage scenario would ensure a 15 percent decline in the number of children under 5 stunted by 2030 compared with 2017 (­figure 4.10). This reduction in stunting will not ensure the 40 percent decline in the number of stunted children endorsed as a target for stunting by the Sixty-fifth WHA. Figure 4.10 also shows the initial increase in the number of stunted children from 2017 to 2018. The increase was driven by two main factors: (1) because being stunted while in the previous age cohort is itself a risk factor for stunting, stunting rates take time to drop; and (2) the reduction in the under-5 mortality FIGURE 4.9 Prevalence of stunting of children 0–59 months of age: current and full national coverage, 2017–30 21.5 21.2 21.1 21.2 21.0 20.5 Stunting rate (%) 20.0 19.7 19.5 18.9 18.9 19.0 18.5 18.0 17.5 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 2030 Current coverage Full national coverage Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). Projections performed using Lives Saved Tool (LiST), https://listvisualizer.org/. 116 | Scaling Up Nutrition in the Arab Republic of Egypt FIGURE 4.10 Number of stunted children 0–59 months of age: current and full national coverage, 2017–30 2.6 Number of stunted children (millions) 2.5 2.4 2.3 2.2 2.1 2.0 1.9 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 2030 Current coverage Full national coverage Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). Projections performed using Lives Saved Tool (LiST), https://listvisualizer.org/. FIGURE 4.11 Additional cases of stunting averted for children 0–59 months of age Hygienic disposal of children’s stools 49,420 Promotion and support of breastfeeding 14,126 Vitamin A supplementation (children) 17,100 Iron–folic acid supplementation 27,503 Promotion of complementary feeding 313,211 0 0 0 0 0 0 0 00 00 00 00 00 00 00 ,0 0, 0, 0, 0, 0, 0, 50 10 30 20 35 25 15 Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). Estimations performed using Lives Saved Tool (LiST), https://listvisualizer.org/. rate spurred by this package of interventions partially outweighs the stunting reduction effect as more children 0–59 months remain alive and can potentially become stunted. Figure 4.11 shows that 421,360 additional cases of stunting would be prevented by scaling up to full national coverage by 2022. Much of this stunting reduction (74 percent) is explained by one intervention, complemen- tary feeding promotion, which would have a direct and powerful effect in stunt- ing reduction in the model (LiST) used to develop these projections. Wasting Shekar et al. (2016) estimate that the scale-up of treatment of severe acute mal- nutrition alone in low- and middle-income countries can prevent up to 860,000 deaths in children under 5. The national wasting rate in Egypt is moderate at around 8 percent. However, four governorates are above critical values (greater than 20 percent),10 with the prevalence of wasting in Damietta found to be 63 percent in EDHS 2014. This analysis estimates the reduction of wasting based on the LiST model by scaling up both treatment of MAM/SAM and promotion of complementary feeding. The combined effect of scaling up promotion of complementary feeding Cost-Effectiveness of Potential Scale-Up Scenarios in Egypt | 117 from 62 percent in 2017 to 90 percent in 2022 and MAM/SAM from 0 to 80 ­percent over the same period nationwide will reduce the wasting rate from 8.7 percent in 2017 to 6 percent in 2022 (figure 4.12). Although this projection is conducted using national averages, the critical high values of wasting reported by EDHS 2014 for Damietta (63 percent), Monufia (22.6 percent); Asyut percent), and New Valley (35.4 percent) suggest that these governorates (32.5 ­ should be given priority in the implementation of treatment of MAM/SAM and promotion of complementary feeding. Anemia in pregnant women In the LiST model, iron–folic acid supplementation, the intervention that pre- vents anemia in pregnant women, is considered in the full national package. Remarkably, this analysis shows that scaling up this intervention from 36 per- cent to 90 percent coverage would reduce anemia in pregnant women by almost 50 percent, from 18 percent in 2017 to 9.5 percent by 2022 (figure 4.13). Exclusive breastfeeding prevalence In this analysis, the promotion and support of exclusive breastfeeding are included in the first package of nutrition-specific preventive interventions (IYCF and micronutrients). Promotion of breastfeeding requires providing FIGURE 4.12 Prevalence of wasting in children 0–59 months of age: current and full national coverage, 2017–22 9 9 9 8 Wasting rate (%) 7 6 6 5 4 2017 2018 2019 2020 2021 2022 Current coverage Full national coverage Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). Projections performed using Lives Saved Tool (LiST), https://listvisualizer.org/. FIGURE 4.13 Percentage of pregnant women with iron-deficiency anemia: current and full national coverage, 2017–22 20 18 18 15 Percent 9 10 5 2017 2018 2019 2020 2021 2022 Current coverage Full national coverage Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). Projections performed using Lives Saved Tool (LiST), https://listvisualizer.org/. 118 | Scaling Up Nutrition in the Arab Republic of Egypt mothers with education and counseling, campaigns to promote optimal breast- feeding practices, as well as development of the appropriate policies and legisla- tion to protect exclusive breastfeeding. The World Health Assembly set the target for increasing exclusive breastfeeding for infants up to 6 months of age from 37 percent in 2012 to 50 percent in 2025 (Shekar et al. 2017). Figure 4.14 shows that scaling up the promotion of exclusive breastfeeding to full national coverage from 62 percent in 201711 to 90 percent coverage in 2022 would ensure an increase of exclusive breastfeeding prevalence of 9 percentage points (from 41 percent in 2017 to 50 percent in 2022). This result would comply with the 50 percent target set by the World Health Assembly for 2025. Cost-effectiveness analysis of full national coverage (scenario 1) The cost per benefit is based on three key indicators: lives saved, number of cases of stunting averted, and disability-adjusted life years averted. DALYs averted is a key measure used in health economics to evaluate and compare the cost-­ effectiveness of health programs and interventions. DALY combines mortality and morbidity in a single metric. It captures the number of years of a person’s life saved by a given intervention and adjusts it by the health status that person is expected to have during those years. For example, if an intervention saves a person’s life and that person is expected to live in perfect health for next 30 years, ­ the intervention would avert 30 DALYs. In this analysis, the number of DALYs averted is calculated using Bhutta et al. (2008) as a reference: one life saved equals 33 DALYs averted; one case of stunting averted equals 0.23 DALYs. Thus because of the way this metric is computed, interventions that affect mortality generate the greatest impact in terms of DALYs (that is, avert the greatest number of DALYs). Preventing stunting has benefits that go beyond health (mortality and mor- bidity); it has an impact on a child’s cognitive development, educational attain- ment, and economic productivity. Thus, in addition to the number of DALYs averted, which is strictly a health measure, the cost per benefit is also based on the number of cases of stunting averted (calculated using the LiST model). This analysis suggests that scaling up all the interventions to full national cov- erage would prevent over 13,955 child deaths and 421,360 cases of stunting in children under 5 over the course of five years and avert 55,743 DALYs (table 4.7). Using the package of interventions, preventing one death would cost about $81,154; preventing one case of stunting would cost about $2,688; and averting one DALY would cost about $20,317. FIGURE 4.14 Percentage of children under 6 months of age exclusively breastfed: current and full national coverage, 2017–22 65 50 65 60 Percent 55 50 45 41 41 40 2017 2018 2019 2020 2021 2022 Current coverage Full national coverage Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). Projections .org/. performed using Lives Saved Tool (LiST), https://listvisualizer​ Cost-Effectiveness of Potential Scale-Up Scenarios in Egypt | 119 TABLE 4.7  Costs and benefits for full national coverage scenario EXPECTED BENEFITS COST PER BENEFITS (US$) COST PER ADDITIONAL COST PER ADDITIONAL ADDITIONAL CASES OF ADDITIONAL CASE OF COST PER DEATHS STUNTING DALYS DEATH STUNTING DALY INTERVENTIONS FOR FULL NATIONAL COVERAGE PREVENTED AVERTEDa AVERTED AVERTED AVERTED AVERTED IYCF and micronutrients 3,508 371,940 20,131 17,312 163 3,017 Promotion and support of breastfeeding 1,643 14,126 5,747 10,772 1,253 3,080 Promotion of complementary feeding 442 313,211 8,662 51,819 73 2,644 Iron–folic acid supplementation 1,013 27,503 3,975 10,968 404 2,795 Vitamin A supplementation (children) 410 17,100 1,746 21,992 527 5,163 Management of acute malnutrition 2,476 — 8,171 124,020 — 37,582 Treatment of moderate acute malnutrition 865 — 2,855 45,033 — 13,646 Management of severe acute malnutrition 1,611 — 5,316 166,431 — 50,434 Disease prevention and management 7,233 — 23,869 83,781 — 25,388 Treatment of diarrhea (oral rehydration solution) 5,642 — 18,619 26,993 — 8,180 Therapeutic zinc supplementation 1,591 — 5,250 285,160 — 86,412 Water, sanitation, and hygiene (WASH) b 738 49,420 3,572 14,897 222 3,078 Hygienic disposal of children’s stools 738 49,420 3,572 14,897 222 3,078 Total 13,955 421,360 55,743 81,154 2,688 20,317 Source: Expected benefits estimated using the Lives Saved Tool (LiST), https://listvisualizer.org/. Estimated costs based on unit costs obtained from the WHO OneHealth Tool, http://www.who.int/choice/onehealthtool/en/. Note: DALY = disability-adjusted life year; IYCF = infant and young child feeding; — = zero. a. IYCF and micronutrients and WASH interventions are the only interventions that have an impact on the risk of stunting, according to the LiST model. b. Hygienic disposal of children’s stools is the only WASH intervention with baseline coverage in 2017 below full coverage (60 percent). No scale-up was modeled for the remaining WASH interventions because they are already at over 90 percent coverage. To reduce child mortality, the most cost-effective interventions in terms of cost per life saved are promotion and support of breastfeeding ($10,772), iron– folic acid supplementation ($10,968), vitamin A supplementation for children ($21,992), and hygienic disposal of children’s stools ($14,987). In terms of stunting, the most cost-effective interventions are promotion of complementary ­ feeding ($73), iron–folic acid supplementation ($404), vitamin A supplementa- tion for children ($527), and hygienic disposal of children’s stools ($222). The most cost-effective interventions to avert DALYs are promotion of com- plementary feeding ($2,644), iron–folic acid supplementation ($2,795), promo- tion and support of breastfeeding ($3,080), and hygienic disposal of children’s stools ($3,078), and vitamin A supplementation for children ($5,163). All these interventions are considered cost-effective according to the categorization used by World Health Organization–Choosing Interventions That Are Cost-Effective (WHO-CHOICE).12 The treatment of severe acute malnutrition and therapeutic zinc supplemen- tation for the treatment of diarrhea are overall the least cost-effective interven- tions in the package in terms of lives saved and DALYs averted. The reason is that high additional costs are required to scale up these interventions to full national coverage ($307 million for MAM/SAM; $453 million for zinc over five years). Prioritized scale-up options Chapter 3 describes the options for scaling up nutrition programs in Egypt. The financing resources needed to expand to full national coverage by 2022 are 120 | Scaling Up Nutrition in the Arab Republic of Egypt significant, and fiscal and capacity constraints render this option not viable in the short term. Furthermore, expanding the complete package of interventions nationwide will take time, and it does not take into consideration the geo- graphical disparities between governorates in terms of nutrition and poverty indicators. This section analyzes two additional scale-up scenarios that consider the bur- den of stunting, geography, and implementation capacity: • Scale up by region (scenario 2): prioritize the full package only in region groups with the highest burden of stunting Scale up by prioritizing interventions (scenario 3): scale up to full national cov- • erage the most cost-effective interventions aimed at reducing stunting. Scale up by region (scenario 2) Scenario 2 targets resources by geography and demography, focusing on gover- norates with the highest prevalence of stunting and number of stunted children. Using these criteria, eight governorates with the highest stunting prevalence in Egypt account for 50 percent of all stunted children: Giza, Sharqia, Cairo, Sohag, Minya, Gharbia, Beni Suef, and Faiyum (figure 4.15). For this scenario, it is projected that all nutrition interventions will be scaled up to full national coverage in the eight priority governorates, and current cov- erage throughout the five-year period is assumed for the remaining governorates. Scale up by intervention (scenario 3) This scenario scales up to full national coverage only those interventions that have the highest impact on stunting. Analysis of the cost-effectiveness of the nutrition interventions performed for the full national coverage scenario demon- strated that the most cost-effective interventions measured based on cases of stunting and DALYs averted are IYCF13 and micronutrients and hygienic disposal of children’s stools. FIGURE 4.15 Prevalence of stunting and population by governorate 45 Beni Suef 40 Sharqia Stunting rates (percent) 35 Sohag Giza 30 Faiyum Gharbia Minya 25 Red Sea Cairo Qena 20 Luxor Suez Damietta Kafr el-Sheikh 15 Alexandria Matruh Aswan Qalyubia Ismailia Asyut 10 Port Said Dakahlia Monufia Beheira 5 New Valley 0 2 4 6 8 10 12 Population (millions) Source: EDHS 2014 (MOHP, El-Zanaty and Associates, and ICF International 2015). Note: Size of bubble is indicative of number of stunted children. Cost-Effectiveness of Potential Scale-Up Scenarios in Egypt | 121 These interventions are also those that can be scaled up quickly either with existing capacity or with relatively small investments. Therefore, this scale-up scenario excludes treatment of acute malnutrition (MAM/SAM) for children and pregnant women. These interventions are given lowest priority in the con- text of this analysis because (1) their impact on the prevalence of wasting but not on stunting is known; (2) their unit costs are significantly higher than those of other interventions, and they are linked to supply chain and logistics challenges associated with the large-scale distribution of food; and (3) their cost-­ effectiveness is low compared with that of other nutrition preventive interven- tions (Shekar et al. 2017). Cost-effectiveness analysis of prioritized scale-up options versus full coverage Figure 4.16 shows the total additional costs by scenario to scale up the package of nutrition interventions over the period 2018–22. The expected resources requirement for scaling up the existing package of nutrition interventions to full national coverage (90 percent) and implementing the treatment of MAM and SAM nationwide to 80 percent coverage will be an additional $1,132 million over the period. The additional cost of scaling up to 90 percent coverage only in the region group with the highest burden of stunting between 2018 and 2022 will be $556 million. By focusing on the eight governorates with the highest stunting rates and number of stunted children, the financial requirement will generally decrease proportionally compared with that for the full national coverage sce- nario. WASH interventions will remain close to full scale, with the exception of FIGURE 4.16 Total and additional costs by scenario, 2018–22 1,800 11 1,600 1,400 606 1,200 Cost (US$, millions) 6 1,132 1,000 307 310 800 556 61 134 148 34 11 600 72 61 82 11 400 561 561 561 200 0 Full national coverage Prioritize by region group Prioritize by intervention WASH Disease prevention and management (ORS + zinc) Management of severe and acute malnutrition IYCF and micronutrients (IFAS + vitamin A) System strengthening for program delivery Current coverage Source: Estimated costs based on unit costs obtained from the WHO OneHealth Tool, http://www.who.int/choice​/­onehealthtool​/­en/. Note: IFAS = iron–folic acid supplementation; IYCF infant and young child feeding; ORS = oral rehydration solution; WASH = water, sanitation, and hygiene. 122 | Scaling Up Nutrition in the Arab Republic of Egypt hygienic disposal of children’s stools (which will rise from 60 percent to percent coverage in the eight governorates only). 90 ­ Delivery of only the most cost-effective interventions in stunting reduction (IYCF and micronutrients and hygienic disposal of children’s stools) will require an additional $82 million over the period 2018–22: $61 million for IYCF and micronutrients, $11 million for hygienic disposal of children’s stools, and $11 ­million for system strengthening. The savings gained by adopting this strat- egy stems from prioritizing those interventions having the highest impact on stunting reduction and therefore not considering MAM/SAM and maintaining ORS and zinc at the current coverage levels. When comparing the costs and benefits of all three scenarios included in this analysis (table 4.8), prioritizing by intervention (scenario 3) is the most cost-­ effective strategy of implementation by all parameters: cost per additional life saved ($19,412), cost per additional case of stunting averted ($196), and cost per DALY averted ($3,478). For stunting, this scenario would prevent the same num- ber of stunted children as ensured by scaling up to full national coverage (421,360), but at a significantly lower additional cost ($82 million) because it delivers those interventions that are the most cost-effective in stunting reduc- tion. Treatment of acute malnutrition and maintaining implementation of ORS and zinc at current coverage levels throughout the country would therefore be excluded. Scenario 3 would also allow setting aside some strategic funding for scaling up implementation in vulnerable areas and populations of the country. Focusing only on those interventions that are most effective in reducing stunting will not have any impact on the current levels of wasting and will pre- vent only 4,249 additional deaths (30 percent of the full national coverage scenario). Cost-benefit analysis Socioeconomic benefits of investing in nutrition Current estimates suggest that all forms of malnutrition (undernutrition, micro- nutrient deficiencies, and overweight) cost the global economy an estimated $3.5 trillion a year, or $500 a person, compromising productivity and undermin- ing any attempt to reduce poverty (Global Panel 2016). Over 2 billion people are estimated to be malnourished worldwide, including 159 million children who are stunted, which affects not only their physical development but also their cog- nitive development (IFPRI 2016). Stunted children suffer severe effects throughout their life cycle, and stunting is associated with long-term costs. The consequences of stunting are not only TABLE 4.8  Costs and benefits for all scenarios EXPECTED BENEFITS COST PER BENEFIT (US$) COST PER ADDITIONAL ADDITIONAL COST PER ADDITIONAL SCALE-UP ADDITIONAL CASES OF ADDITIONAL CASE OF COST PER COSTS (US$, DEATHS STUNTING DALYS DEATH STUNTING DALY SCALE-UP SCENARIO MILLIONS) PREVENTED AVERTED AVERTED AVERTED AVERTED AVERTED 1. Full national coverage 1,132 13,955 421,360 55,743 81,154 2,688 20,317 2. Prioritize by region group 556 6,935 185,211 27,145 80,148 3,001 20,476 3. Prioritize by intervention 82 4,249 421,360 23,713 19,412 196 3,478 Source: Expected benefits estimated using the Lives Saved Tool (LiST), https://listvisualizer.org/. Estimated costs based on unit costs obtained from the WHO OneHealth Tool, http://www.who.int/choice/onehealthtool/en/. Note: DALY = disability-adjusted life year. Cost-Effectiveness of Potential Scale-Up Scenarios in Egypt | 123 FIGURE 4.17 Investments in nutrition build human capital and boost shared prosperity SCHOOLING EARNINGS POVERTY ECONOMY Early nutrition Early nutrition Children who Reduction in programs can programs can escape stunting stunting can increase school raise adult are 33% more increase GDP completion by wages by 5–50% likely to escape by 4–11% one year poverty as adults in Asia and Africa Source: Shekar et al. 2017, based on Hoddinott et al. 2008, 2011; Horton and Steckel 2013; Martorell et al. 2010. higher risk of death and disability, but also loss of creative and intellectual energy (Lye 2016). Stunting is the root cause of adverse outcomes in youth and adult- hood, such as delayed schooling, poorer performance in school, fewer years of education, lower incomes, greater risk of poverty, and higher costs for the econ- omy. The costs of stunting are mainly associated with two factors: (1) reduced cognitive capacity and educational attainment and (2) higher health care costs. Widespread evidence indicates that being stunted in early childhood is asso- ciated with a delayed start at school (Daniels and Adair 2004), reduced school- ing attainment (Fink et al. 2016; Martorell et al. 2010), and substantially lower adult wages when measured at both the individual and country level (Fink et al. 2016). One study found that young children who were stunted were 33 percent less likely to escape poverty as adults (Shekar et al. 2017). As described in figure 4.17, these consequences add up to overall GDP losses of 4–11 percent in Africa and Asia (Horton and Steckel 2013). Nutrition interventions that can mitigate the burden of stunting are consis- tently identified as being among the most cost-effective development and global health actions (Horton and Hoddinott 2014). Benefit-cost ratios across nutrition interventions and programs reveal very high economic returns to investing in nutrition (Alderman, Behrman, and Puett 2016; Copenhagen Consensus Center 2015; Hoddinott et al. 2013). Several economic analyses have calculated ­benefit-cost ratios well above 1, the break-even point, with the benefits of invest- ments aimed at reducing stunting as high as $15 in return for every $1 invested (Shekar et al. 2017; Galasso et al. 2017). Cost-benefit analysis of scale-up priorities Scaling up the interventions to full national coverage (scenario 1) would result in total net benefits from increases in economic productivity of about $547 million over the productive lives of the children who benefited from the interventions. Under this scenario, the benefit-cost ratio would be 0.54, which means that every dollar invested in nutrition would bring $0.54 in economic benefits. The estimated internal rate of return (IRR) for this investment would be 1.09 percent. The benefit-cost ratio for scaling up to full national coverage in eight gover- norates only (scenario 2) would be 0.40, with economic benefits of about $201  million and an estimated rate of return of 0.85 percent (table 4.9). 124 | Scaling Up Nutrition in the Arab Republic of Egypt TABLE 4.9  Cost, benefits, and benefit-cost ratios TOTAL NET INTERNAL RATE OF RETURN DISCOUNT ADDITIONAL COST NET BENEFITS BENEFIT-COST (DISCOUNTED COSTS AND SCALE-UP SCENARIO RATE (%) (US$, MILLIONS) (US$, MILLIONS) RATIO BENEFITS, %) 1. Full national coverage 3 1,017 547 0.54 1.09 2. Prioritize by region group 3 499 201 0.40 0.85 3. Prioritize by intervention 3 74 1,326 17.87 9.80 Source: Expected benefits estimated using LiST Lives Saved Tool (LiST), https://listvisualizer.org/. Estimated costs based on unit costs obtained from the WHO OneHealth Tool, http://www.who.int/choice/onehealthtool/en/. The highest benefit-cost ratio would be ensured by scenario 3, which priori- tizes implementation of the most cost-effective interventions in stunting reduction. Adopting this strategy in Egypt would return $17.87 in economic benefits for each dollar invested, and $1,326 million in productivity gains, indi- cating that the benefits of adopting this strategy significantly outweigh the costs. The rate of return from investing in this scenario is 9.80 percent, well above the IRR for scenarios 1 and 2. CONCLUSIONS The case for investing in child and maternal nutrition globally and in Egypt is strong. The analytical approach used in this economic analysis combines costs with estimates of impact and makes a case for investing in nutrition in Egypt even stronger, helping policy makers to identify and prioritize the most cost-­ effective packages of interventions in a context in which financing is constrained. To maximize the number of nonstunted children, Egypt should prioritize funding the most cost-effective interventions: IYCF (especially promotion of complementary feeding), iron–folic acid supplementation, vitamin A supple- mentation for children, and promotion of hygienic disposal of children’s stools. When comparing the costs and benefits, if the main priority is reduction of stunt- ing, focusing on delivering only the most cost-effective interventions in stunting reduction (scenario 3) provides better value for the money. The expected additional resources required for implementing scenario 3 over the five-year period from 2018 to 2022 is $82 million. Compared with current coverage levels, the estimates presented in this economic analysis indicate that this investment would prevent 4,249 additional deaths and 421,360 additional cases of stunting and save 23,713 DALYs. The significant cost savings for scenario 3 stem from prioritizing those inter- ventions that are better able to reduce stunting. This means maintaining only supplementation of ORS and zinc for the treatment of diarrhea at current cover- age levels and not considering treatment of acute malnutrition (MAM/SAM). By doing so, however, scenario 3 will not have any impact on the current level of wasting, and it will only prevent 30 percent of additional deaths (4,249), com- pared with the full national coverage scenario. This analysis shows that adopting the strategy described for scenario 3 would result in substantial economic benefits and the best value for the money for Egypt. Scenario 3, which prioritizes implementation of the most cost-effective interventions for stunting reduction, is estimated to translate into and return the highest economic benefits over the productive lives of the children who receive Cost-Effectiveness of Potential Scale-Up Scenarios in Egypt | 125 the interventions. The estimated benefit-cost ratio for implementing this sce- nario in Egypt is 17.87 and suggests that every dollar invested would result in about $18 in economic returns and $1,326 million in productivity gains, indicat- ing that the benefits of investing in nutrition significantly outweigh the costs. NOTES  1. A supply-side analysis means that demand has not been explicitly addressed in terms of accessibility and quality of care for those with poor health care–seeking behavior.  2. http://www.who.int/choice/onehealthtool/en/.  3. http://www.who.int/choice/.  4. http://www.who.int/choice/costs/CER_levels/en/.it.  5. In the LiST model, “other causes” indicates a specific category of mortality.  6. LiST: WHO estimates (2000–2015); http://www.who.int/healthinfo/global_burden​ _­disease/estimates_child_cod_2015/en/.  7. LiST: WHO estimates (2000–15), http://www.who.int/healthinfo/global_burden_disease​ /­estimates_child_cod_2015/en/.  8. Six countries in Sub-Saharan Africa—Senegal, Namibia, Togo, Uganda, Eritrea, and Tanzania—reduced stunting among children under 3 with declines of at least 2 percentage points a year.  9. In 2012 the Sixty-fifth World Health Assembly endorsed a target for stunting: reduce the number of stunted children under 5 by 40 percent by 2025. This target has been adopted for Sustainable Development Goal 2: end hunger, achieve food security and improved nutrition, and promote sustainable agriculture. 10. Monufia 22.6 percent; Asyut, 32.5 percent; New Valley, 35.4 percent; Damietta, 63 percent (EDHS 2014). 11. Based on data from the Nutrition Stakeholder and Action Mapping Report (MOHP and UNICEF 2017). 12. http://www.who.int/choice/costs/CER_levels/en/. Threshold values for intervention cost-effectiveness: less than GDP per capita, very cost-effective; 1–3 times GDP per capita, cost-effective; less than 3 times GDP per capita, not cost-effective. For Egypt: very cost​ -­effective: cost per DALY is less than GDP per capita ($3,548); cost-effective: cost per DALY is less than 1–3 times GDP per capita ($3,548–$10,644); not cost-effective: cost per DALY is greater than 3 times GDP per capita ($10,644). 13. Within IYCF, promotion and support of breastfeeding is the intervention less cost-effective in terms of reduction of stunting. However, because it is normally implemented during IYCF sessions together with the promotion of complementary feeding, it is advisable to consider the two interventions to be practically indistinguishable. REFERENCES Alderman, H., J. R. Behrman, and C. Puett. 2016. “Big Numbers about Small Children: Estimating the Economic Benefits of Addressing Undernutrition.” World Bank Research Observer 31 (2). Bhutta, Z. A., T. Ahmed, R. E. Black, S. Cousens, K. Dewey, E. Gugliani, B. A. Haider, B. Kirkwood, S. S. Morris, H. P. S. Sachdev, and M. Shekar. 2008. “What Works? Interventions for Maternal and Child Undernutrition and Survival.” Lancet 371 (9610): 417–40. Bhutta, Z. A., J. K. Das, A. Rizvi, M. F. Gaffey, N. Walker, S. Horton, P. Webb, A. Lartey, and R. E. Black. 2013. “Evidence-Based Interventions for Improvement of Maternal and Child Nutrition: What Can Be Done and at What Cost?” Lancet 382 (9890): 452–77. Cairncross, S., C. Hunt, S. Boisson, K. Bostoen, V. Curtis, I. C. Fung, and W. P. Schmidt. 2010. “Water, Sanitation and Hygiene for the Prevention of Diarrhoea.” International Journal of Epidemiology 39 (Suppl. 1): i93–i205. http://www.ncbi.nlm.nih.gov/pubmed/20348121. Cairncross, S., and V. Valdmanis. 2006. “Water Supply, Sanitation, and Hygiene Promotion.” In  Disease Control Priorities in Developing Countries, 2nd ed., edited by D. T. Jamison, 126 | Scaling Up Nutrition in the Arab Republic of Egypt J. G. Breman, A. R. Measham, G. Alleyne, M. Claeson, D. B. Evans, P. Jha, A. Mills, and P. Musgrove, 771–92. Washington, DC: World Bank; New York: Oxford University Press. http:// www.ncbi.nlm.nih.gov/books​/­NBK11728/. Copenhagen Consensus Center. 2015. Smart Development Goals: The Post-2015 Consensus. http://www.copenhagenconsensus.com/sites/default/files/ outcomedocument_col.pdf. Cumming, O., and S. Cairncross. 2016. “Can Water, Sanitation and Hygiene Help Eliminate Stunting? Current Evidence and Policy Implications.” Maternal and Child Nutrition 12 (Suppl. 1): 91–105. doi: 10.1111/mcn.12258. Daniels, M. C., and L. S. Adair. 2004. “Growth in Young Filipino Children Predicts Schooling Trajectories through High School.” Journal of Nutrition 134(6): 1439–46. Fink, G., E. Peet, G. Danaei, K. Andrews, D. C. McCoy, C. R. Sudfeld, M. C. Smith Fawzi, M. Ezzati, and W. W. Fawzi. 2016. “Schooling and Wage Income Losses Due to Early-Childhood Growth Faltering in Developing Countries: National, Regional, and Global Estimates.” American Journal of Clinical Nutrition 104 (1): 104–12. Galasso, E., A. Wagstaff, S. Naudeau, and M. Shekar. 2017. “The Economic Costs of Stunting and How to Reduce Them.” Policy Research Note, World Bank, Washington, DC. http://pubdocs​ .worldbank.org/en/536661487971403516/PRN05-March2017-Economic-Costs-of​ -Stunting.pdf. Global Panel (Global Panel on Agriculture and Food Systems for Nutrition). 2016. The Cost of Malnutrition: Why Policy Action Is Urgent. Technical Brief No. 3. London, UK: Global Panel on Agriculture and Food Systems for Nutrition. https://glopan.org/cost-of-malnutrition. Hoddinott, J., H. Alderman, J. R. Behrman, L. Haddad, and S. Horton. 2013. “The Economic Rationale for Investing in Stunting Reduction.” Maternal and Child Nutrition 9 (Suppl. 2): 69–82. Horton, S., and J. Hoddinott. 2014. “Benefits and Costs of the Food and Nutrition Targets for the Post-2015 Development Agenda: Post-2015 Consensus.” Food Security and Nutrition Perspective Paper, Copenhagen Consensus Center. Horton, S., and R. Steckel. 2013. “Malnutrition: Global Economic Losses Attributable to Malnutrition 1900–2000 and Projections to 2050.” In The Economics of Human Challenges, edited by B. Lomborg, 247–72. Cambridge, UK: Cambridge University Press. Humphrey, J. 2013. “SHINE Sanitation, Hygiene, Infant Nutrition Efficacy Project.” https:// clinicaltrials. gov/ct2/show/ NCT01824940. IFPRI (International Food Policy Research Institute). 2016. “Global Nutrition Report 2016: From Promise to Impact: Ending Malnutrition by 2030.” Washington, DC. Lenters, L. M., K. Wazny, P. Webb, T. Ahmed, and Z. A. Bhutta. 2013. “Treatment of Severe and Moderate Acute Malnutrition in Low- and Middle-Income Settings: A Systematic Review, Meta-analysis and Delphi Process.” BMC Public Health 13 (Suppl 3): S23. http:// www.ncbi​ .nlm.nih.gov/pmc/articles/PMC3847503/. Lye, S. J. 2016. “The Science of Early Development: Investing in the First 2000 Days of Life to Enable All Children, Everywhere to Reach Their Full Potential.” Presentation at World Bank Early Childhood Development Meeting, Washington, DC, April 2016. Martorell, R., B. L. Horta, L. S. Adair, A. D. Stein, L. Richter, C. H. D. Fall, S. K. Bhargava, S. K. Dey Biswas, L. Perez, F. C. Barros, C. G. Victora, and Consortium on Health Orientated Research in Transitional Societies Group. 2010. “Weight Gain in the First Two Years of Life Is an Important Predictor of Schooling Outcomes in Pooled Analysis from 5 Birth Cohorts from Low- and Middle-Income Countries.” Journal of Nutrition 140: 348–54. MOHP (Ministry of Health and Population), El-Zanaty and Associates, and ICF International. 2015. Egypt Demographic and Health Survey 2014. Cairo, Egypt and Rockville, MD: Ministry of Health and Population and ICF International. https://dhsprogram.com/pubs/pdf​ /FR302/FR302.pdf. MOHP (Ministry of Health and Population) and UNICEF (United Nations Children’s Fund). 2017. Nutrition Stakeholder and Action Mapping Report. Cairo: UNICEF. https://www​ .unnetworkforsun.org/sites/default/files/2018-08/Nutrition%20Stakeholder%20%26%20 Action%20Mapping%20Report-Egypt.pdf. Shekar, M., J. Kakietek, J. Dayton Eberwein, and D. Walters. 2017. An Investment Framework for Nutrition: Reaching the Global Targets for Stunting, Anemia, Breastfeeding, and Wasting. Cost-Effectiveness of Potential Scale-Up Scenarios in Egypt | 127 openknowledge​ Directions in Development. Washington, DC: World Bank.  https://­ .­worldbank.org/handle/10986/26069. Teller, C. H., and S. Alva. 2008. “Reducing Child Malnutrition in Sub-Saharan Africa: Surveys Find Mixed Progress.” Population Reference Bureau, Washington, DC. https://www.prb​ .org/stuntingssa/. UN (United Nations). 2017. World Population Prospects 2017—Data Booklet. New York: United .un​ Nations, Department of Economic and Social Affairs, Population Division. https://www​ .org/development/desa/publications/world-population-prospects-the-2017-revision.html. 5 Fiscal Space to Scale Up Nutrition in Egypt HELEN C. CONNOLLY KEY MESSAGES • This chapter examines the extent to which the existing and projected fiscal space will be conducive to absorbing the additional costs of implementing the scale-up scenarios discussed in chapter 4. • According to World Bank estimates, total nutrition expenditures are a little over $150 million a year in Egypt, which is 0.33 percent of the total govern- ment expenditure and 0.81 percent of the total health expenditure. However, according to the National Health Accounts for 2012, the proportion specifi- cally spent on nutritional deficiencies is only $11 million. • Egypt relies little on foreign assistance for funding nutrition programs. The reported overseas development assistance funding for nutrition represents only 2.33 percent of the estimated $152.6 million total expenditure on domes- tic nutrition. • This analysis found that out of the five pillars of fiscal space, improved mac- roeconomic conditions in the long run as well as medium-run efficiency gains are two areas with good prospects of generating significant additional resources for nutrition. • Other potential sources are more limited in opportunity. Increased funding through the health budget is not likely because of the competing priorities for finite resources and the highly centralized decision making in Egypt. Raising further funds in the health sector through, for example, taxes earmarked for health (or nutrition) face difficulties because of the evolving and multisec- toral nature of nutrition and the potential negative impacts of such taxes. And foreign assistance is not likely as well because Egypt does not rely on external funding for nutrition. • In the long run, it is reasonable to expect significant economic growth from the higher productivity of Egypt’s workforce stemming from a reduction in stunting. Lower levels of stunting and consequent improved health will also reduce the reliance on social programs and cut stunting-related health costs. • Aside from economic growth, government revenue could also increase if tax revenue increases through an expanded tax base, new taxes, or more efficient tax collection.  129 130 | Scaling Up Nutrition in the Arab Republic of Egypt • This discussion relies heavily on public information available for the health sector in Egypt. A more in-depth analysis of fiscal space for nutrition that includes both health and other key sectors would depend on expanding the specifics in the pillars discussed here to include information from all of these sectors. This chapter examines the extent to which the existing and projected fiscal space in Egypt will be conducive to absorbing the additional costs of implement- ing the scale-up scenarios discussed in chapter 4. ESTIMATING THE CURRENT LEVEL OF SPENDING ON NUTRITION IN EGYPT This section describes the methods and sources used for estimating the current level of spending on nutrition in Egypt through domestic financing from the gov- ernment of Egypt (GoE), official development assistance (ODA), and other sources. Current estimates are identified where they are available. Domestic government financing In Egypt, information is available from the Ministry of Finance (MOF) for fiscal year 2016 on the actual expenditure of each central administration (ministry) for all sectors. The expenditures for the eight (of the 34) ministries1 with the most nutrition-related programming totaled $46.5 billion in 2016. Little information is available on the current level of GoE spending on nutrition because there are no clear budget lines for nutrition in ministry budgets, making it difficult to quantify the actual expenditures. However, estimates provided by the World Bank and shown in table 5.1 show that the total nutrition expenditure (TNE) for 2016 was $152.6 million, or 0.33 percent of the total government expenditure (TGE) and 0.81 percent of the total health expenditure (THE). A full estimate of nutrition spending requires a broader look at all ministries contributing to the nutrition agenda. TABLE 5.1  Estimated fiscal space indicators: Egypt, 2016 INDICATOR ANNUAL General Population (2017, millions) 94.8 Gross domestic product (GDP) (2016; US$, millions) 336,300 Total government expenditure (TGE) (2016; US$, millions) 46,251.3 Health Total health expenditure (THE) (2016; US$, millions) 18,832.8   THE as % of GDP 5.6%   THE as % of TGE 40.7%   THE per capita (US$) 198.7 Nutrition Total nutrition expenditure (TNE), estimated (2016; US$, millions) 152.6   TNE as % of GDP 0.05%   TNE as % of TGE 0.33%   TNE as % of THE 0.81%   TNE per capita (US$) 1.61   Private nutrition spending per capita 0.77 Source: World Development Indicators (database) , World Bank, Washington, DC, http://datatopics​ .worldbank.org/world-development-indicators/. Fiscal Space to Scale Up Nutrition in Egypt | 131 The cost analysis in chapter 4 finds that the costs of current coverage using unit costs established in the OneHealth tool for the 13 (primarily nutrition-­ specific) interventions prioritized for scale-up total $112 million a year. Although this calculation is broadly in line with the TNE estimate (which includes the 13 prioritized interventions), this analysis would be better informed by a broader understanding of the Egypt-specific costs associated with nutrition programming. Key sources for understanding government expenditures on nutrition Budget analysis. A full budget analysis of nutrition programming across all ministries is a relatively quick and easy method for identifying where current funding (public and external funding included in the budget) is supporting nutrition programming of all kinds. By 2018, 47 Scaling Up Nutrition (SUN) movement countries had conducted an analysis of their government budgets for nutrition, with 26 countries having done it for a second time.2 A nutrition budget analysis, framed in the country context using the relevant policy documents to define nutrition and identify nutrition interventions, would help to identify Egypt-specific (and potentially governorate-specific) unit costs for the 13 prior- itized interventions. This would give a more accurate reflection of the actual costs of scale-up in the Egyptian context. Public expenditure review. A more detailed source of information on spending is a public expenditure review (PER). A PER assesses the level and composition of actual public expenditures against a predetermined set of policy goals and outputs in the relevant national strategy or plan (as well as elements of the effi- ciency and effectiveness of those expenditures). Existing reporting and data monitoring systems are used, including budgets, National Health Accounts, or the OECD/DAC (Development Assistance Committee) CRS (Creditor Reporting System) database.3 Like budget analyses, PERs are usually restricted to govern- ment expenditure and external funding that is in the budget. PERs provide a snapshot in time (repeated only every three to five years) and so does not allow a dynamic assessment of changes over time. As with budget analyses, a meaning- ful, efficient PER for nutrition would need to be framed in the country context using the relevant policy documents to define nutrition and identify nutrition interventions. The World Bank is currently undertaking a PER for health in Egypt, which may help clarify nutrition-related health expenditures. This review could be enhanced to ensure that nutrition expenditures are identified separately within health expenditures. Alternatively (or in addition), a PER for nutrition (outside of the health sector) could also be undertaken that specifically examines pro- grams with nutrition outcomes across all relevant ministries. Health accounts. The globally standardized National Health Accounts (NHAs) are used to track health spending. The result is a standard set of tables summa- rizing health expenditures. NHAs track actual expenditures across sources (public, private, and external) through the perspective of function, providers, and financing mechanisms. However, they apply only to the health sector and so provide little information on nutrition-sensitive spending. The System of Health Accounts (SHA)4 is the framework used to implement the NHA method. Implementation of the SHA framework is country-driven and not always produced on a regular basis. The framework allows for the identifica- tion of expenditures by disease and condition (OECD, Eurostat, and WHO 2011), including public domestic and external sources of spending on treatment of 132 | Scaling Up Nutrition in the Arab Republic of Egypt ­ eficiencies. Although the classification for diseases and conditions is nutrition d only recently available and not used in all implementing countries, by using SHA  2011 one could potentially identify nutrition-related expenditures by matching interventions to the relevant NHA codes. However, this analysis is still limited to the health sector. Table 5.2 provides the latest available information on GoE and external fund- ing for health in Egypt in 2012 and 2015 (2012 is the only year in which data are TABLE 5.2  National Health Accounts indicators of health expenditure: Egypt, 2012 and 2015 INDICATOR 2012 2015 General Population (millions)  Total 87.81 93.78   Less than 5 years of age 91.39   Females, 15–49 years of age 31.35 32.86 Gross domestic product (GDP) (US$, millions) 254,671 352,127 General government expenditure (GGE) (US$, millions) 84,964 105,672 Health Current health expenditure (CHE) 12,591 14,689   CHE as % of GDP 4.9% 4.2%   CHE as % of GGE 14.8% 13.9%   CHE per capita (US$) 143.38 156.64 Domestic health expenditure (DHE) (US$, millions) 12,542 14,652   DHE as % of GDP 4.9% 4.2%   DHE as % of GGE 14.8% 13.9%   DHE as % of CHE 99.6% 99.7%   CHE per capita (US$) 142.82 156.24 Domestic general government health expenditure (GGHE-D) 3,740 4,419   GGHE-D as % of DHE 29.8% 30.2%   GGHE-D per capita (US$) 42.59 47.12 Domestic private health expenditure (PVT-D) 8,802 10,233   PVT-D as % of DHE 70.2% 69.8%   PVT-D per capita (US$) 100.24 109.12 Out-of-pocket (OOP) 7,930 9,101   OOP as % of PVT-D 90.1% 88.9%   OOP per capita (US$) 90.31 97.05 External health expenditure (EHE) 49 37   EHE as % of CHE 0.4% 0.3%   EHE per capita (US$) 0.56 0.40 External health expenditure channeled through government (EHE-G) 36 24   EHE-G as % of EHE 73% 64% Nutrition Public domestic sources of spending on nutrition deficiencies (NUT-D) 11     NUT-D as % of GDP 0.00%     NUT-D as % of GGE 0.01%     NUT-D as % of CHE 0.09%     NUT-D as % of DHE 0.09%     NUT-D as % of GGHE-D 0.30%     NUT-D per capita (US$) 0.13   Source: Global Health Expenditure Database (GHED), World Health Organization, Geneva, http://apps.who.int/nha/database​ /Select/Indicators/en. Fiscal Space to Scale Up Nutrition in Egypt | 133 available on nutrition deficiencies). Public spending on treatment of nutrition deficiencies in Egypt was reported to be $11 million in 2012, as compared with the 2016 cost of coverage for micronutrient deficiencies (iron–folic acid and vita- min A) of $18 million calculated in chapter 4. This estimate is limited to the treat- ment of specific nutrition deficiencies and so does not include the prevention of poor nutrition outcomes as a whole. A major drawback of NHAs is that they require specialized expertise, and the exercise is extremely resource-intensive. Reported public spending on nutrition deficiencies captures only 10 percent of the calculated costs of cur- rent coverage for the 13 priority interventions. Better use of the detailed func- tion, provider, and funding mechanism data available in the NHAs to examine fiscal space for nutrition requires a number of assumptions to estimate health sector spending on nutrition programs that do not focus on treatment of nutri- tion deficiencies. Nongovernmental expenditures Official development assistance and other flows The Creditor Reporting System5 (CRS) of the Organisation for Economic Co-operation and Development (OECD) includes data on the value of commit- ments and disbursements for all official development assistance (ODA) and other official flows (including nonconcessional loans) recorded from participat- ing Development Assistance Committee (DAC) members as well as multilateral and non-DAC donors.6 These data can be accessed through the OECD website.7 The CRS includes “purpose codes” that make it possible to identify the amounts each contributor assigns to funding streams associated with the spe- cific purpose code. The “basic nutrition” code (12240) is often used to identify nutrition-specific funding.8 In Egypt in 2016, total committed ODA was $2,891 million, whereas $3,553 million was actually disbursed. Of that, only $2.07 million (0.07 percent) was committed to programs identified under the nutrition purpose code, while $3.56 million (0.10 percent) was actually dis- bursed. Reported ODA funding on nutrition represents only 2.33 percent of the estimated $152.6 million total domestic nutrition expenditure (table 5.3). TABLE 5.3  Committed and disbursed external funding, total and basic nutrition: Egypt, 2007–16 TOTAL ALLOCATION (US$, MILLIONS) 12240: BASIC NUTRITION ALLOCATION (US$, MILLIONS) COMMITMENT GROSS DISBURSEMENT COMMITMENT GROSS DISBURSEMENT YEAR ODA OOF PRIVATE GRANTS ODA OOF PRIVATE GRANTS ODA ODA 2007 1,697 306 — 1,549 1,805 — 0.08 0.08 2008 1,957 1,444 — 1,760 628 — 1.08 0.05 2009 1,264 1,854 — 1,626 1,099 — 0.00 0.72 2010 2,481 2,784 — 1,460 1,117 — 0.09 0.27 2011 1,498 1,078 — 1,231 608 — 0.09 0.17 2012 2,896 946 — 2,130 823 — 1.12 0.14 2013 7,630 1,325 — 5,916 803 — 0.00 0.00 2014 2,651 3,034 — 4,495 1,107 — 7.55 0.49 2015 4,260 4,378 — 3,569 5,887 — 0.52 5.21 2016 2,891 4,352 — 3,553 3,538 16.57 2.07 3.56 Source: DAC CRS Database, OECD, Paris, https://stats.oecd.org/Index.aspx?ThemeTreeID=3&lang=en. Note: — = none reported; 12240 = “basic nutrition” code; ODA = official development assistance; OOF = other official flows. 134 | Scaling Up Nutrition in the Arab Republic of Egypt Tracking funds for nutrition by means of the CRS database using only the “basic nutrition” purpose code has several limitations. The basic nutrition code includes many of the nutrition-specific priority interventions identified for scale-up in Egypt, but currently it also contains other interventions without evi- dence that they have a significant impact on nutrition outcomes. To determine the specific intervention being reported, it is necessary to review each relevant project description. These descriptions are not completed at the same level of detail by all donors. To capture other high-impact or nutrition-sensitive interventions in the CRS, one must investigate descriptions of other projects assigned to other codes9 to assess their alignment with the available nutrition policy documents in Egypt, including the National Food and Nutrition Policy and Strategy 2007–2017 (NFNPS) and the Nutrition Agenda for Action 2017. Many interventions may be assigned to other codes, such as other health categories. Furthermore, n utrition-sensitive interventions, such as those implemented through ­ water, sanitation, and hygiene (WASH) or education, will not be found under nutrition, even if nutrition is a defined outcome. Therefore, investigation of project descriptions is required to identify all nutrition-relevant projects. ­ Because nutrition is a multisectoral issue, nutrition-relevant programs would likely be identified across many purpose codes. However, because of lack of stan- dardization across donors, other difficulties may arise. Although some donors will disaggregate programs with multiple purposes across multiple codes, others will assign these larger activities to a single purpose code, meaning that the rel- evant nutrition programs may be attached to unexpected purpose codes requir- ing careful investigation of the project descriptions. Relevant projects can be identified by checking the detail of projects known to be or expected to be relevant to nutrition outcomes. This can be guided at a country level when donor activities are known. Another option is to use a key- word search of project descriptions, understanding that the level of detail in project descriptions will vary and keywords should be chosen to capture a vari- ety of relevant projects. Once projects are identified, an assessment will be required to determine what proportion of the project should be considered relevant to nutrition. ­ An approach recently developed for the SUN Donor Network tracks aid in the CRS that supports nutrition targets (D’Alimonte, Heung, and Hwang 2016). This methodology is meant to improve comparability across donors, recipients, and time; complement ongoing efforts to change the way in which the CRS tracks and codes for nutrition; and align with global nutrition-specific cost estimates. If this approach is adapted by CRS, tracking of donor nutrition estimates could be significantly simplified. Other sources of expenditure Funding for nutrition from civil society organizations (CSOs), nongovernmental organizations (NGOs), philanthropic organizations, and other sources is not eas- ily captured and could be substantial. These sources are normally not tracked through donor reporting or through the national accounts. In fact, this kind of primarily off-budget funding can be very difficult to track. Some country CSO networks track these investments. If NGOs provide significant resources for nutrition programming, these expenditures should be considered. Otherwise, these data may be excluded from the analysis. Fiscal Space to Scale Up Nutrition in Egypt | 135 IDENTIFYING FISCAL SPACE FOR NUTRITION: THE FIVE PILLARS Fiscal space is defined as the room in a government’s budget that allows it to provide resources for a desired purpose without jeopardizing the sustainability of its financial position or the stability of the economy (Heller 2005). Domestic revenue for nutrition spending is a function of several factors: eco- nomic growth, tax collection, and the allocation of revenues to social programs. Domestic public revenue can be increased for additional spending in several ways, including increasing the tax base (the number of organizations and indi- viduals that pay taxes); increasing the tax rates (tax as a share of economic out- put); and improving the efficiency of the tax administration (effectively and efficiently collecting revenue). ODA allocated to nutrition or to the general gov- ernment budget or borrowing are additional sources of revenue that should be counted and potentially leveraged to increase spending for nutrition programs. The potential for increasing fiscal space and mobilizing the additional resources required to finance the priority scale-up scenarios described in chap- ter 4 can be identified using Heller et al.’s 2006 framework examining five primary sources of change: ­ 1. Conducive macroeconomic conditions 2. Reprioritization of expenditures within the government budget 3. Increase in sector-specific resources 4. Sector-specific grants or foreign aid 5. Increased efficiency of the existing sector outlay. Conducive macroeconomic conditions Conducive macroeconomic conditions include sustained economic growth, improved revenue generation, and low levels of fiscal deficits and debt. High levels of economic growth can result in an increase in space for nutrition funding if all spending rises proportionately and price changes for nutrition interven- tions are in line with overall price changes in the country. According to Central Bank of Egypt figures, overall inflation in Egypt has been high in recent years, but fell considerably, to 14.4 percent in 2018, after peaking at over 30 percent in 2017 (figure 5.1). Because nutrition is a multisectoral issue, further investigation is required to understand the effects on fiscal space of changes in prices across sectors aligned with nutrition interventions. Figure 5.2 shows the change in the GDP growth rate over the past decade. Foreign direct investment (FDI) was a contributing factor in economic growth prior to 2010, with net inflows reaching 9.3 percent of GDP in 2006. The 2011 revolution produced an economic slowdown, which was again followed by expansion after 2012, with economic growth in 2017 at just over 4 percent and net inflows of FDI climbing steadily back up to reach 3.4 percent of GDP. Economic growth is forecast to remain relatively steady through 2020 (World Bank 2018). From 2012 to 2015, the domestic general government health expenditure responded less than proportionately to GDP growth, with an elasticity of 0.47,10 which is very low compared with the estimated average of low-income countries 136 | Scaling Up Nutrition in the Arab Republic of Egypt FIGURE 5.1 Core Consumer Price Index (year-on-year percentage change): Egypt, 2011–18 40 35 30 25 Percent 20 15 10 5 0 2011 2012 2013 2014 2015 2016 2017 2018 Source: Central Bank of Egypt, Economic Research Statistics: Inflation, http://www.cbe.org.eg​ /en/EconomicResearch/Statistics/Pages/Inflationhistorical​.­aspx. Note: All index values are for January of the year shown. FIGURE 5.2 GDP growth rate: Egypt, 2008–18 8 6 4 Percent 2 0 –2 –4 2008 2010 2012 2014 2016 2018 Source: Tradingeconomics.com representation of data from Central Bank of Egypt. of 1.16. However, the analysis conducted in chapter 4 demonstrates that scaling up cost-effective stunting reduction interventions to full national coverage would result in significant internal returns (9.80 percent) on the initial five-year investment. This outcome results from the higher economic productivity of children, who do not become stunted because of the scaled-up interventions. ­ Although forecasting future GDP growth attributable to improvement in nutrition outcomes is outside the scope of this analysis, it is reasonable to expect a degree of economic growth from the increased productivity of Egypt’s work- force able to escape stunting and the reduced reliance on social programs such as health. The reduction of stunting in Asia and Africa is estimated to increase GDP by 4–11 percent (Horton and Steckel 2013). Assuming an annual growth rate for Egypt at the low end of 4 percent and based on the 2015 GDP and current elasticity (0.47), the stunting reduction in Egypt could potentially increase the available resources for health by $33.4 million over a five-year period. This addi- tional fiscal space is sufficient to finance the scale-up of more than half of the IYCF and micronutrient programs to full national coverage (estimated to cost a total of $61 million for the period 2018–22—see chapter 4). Fiscal Space to Scale Up Nutrition in Egypt | 137 Health, however, is only one element of the package of interventions for scal- ing up nutrition in Egypt. Consistent estimates of nutrition expenditures across sectors and years would depend on whether nutrition spending in all sectors is trending with health spending. If nutrition-related spending is targeting WASH, as suggested in the scenarios discussed in chapter 4, then changes in expendi- tures in the health sector alone would not be an accurate reflection of changes in nutrition investments and would not be sufficient to predict future expansion in the fiscal space for nutrition. Expenditures reflecting all nutrition programming should be collected over time to get a better overall picture. Aside from economic growth, government revenue could also increase if tax revenue increased through an expanded tax base, new taxes, or more efficient tax collection. Revenue was 12.4 percent of GDP in 2012 and 12.5 percent of GDP in 2015, but it fluctuated between 13.5 percent in 2013 and 12.2 percent in 2014 (figure 5.3). The median tax revenue as a percentage of GDP for lower-­ middle- income countries has exceeded 15 percent each year since 2004 (IMF 2016), suggesting there is some room for a moderate increase in fiscal space through ­ improved revenue generation. Revenue share in GDP tends to rise with income, but only slightly for lower-income countries. Without substantive tax policy and administration reforms, revenue increases tend not to be sustainable and are generally no more than half a percentage point of GDP per year (Bevan 2005). Economic growth and increased revenue provide a larger pool of resources. Additional fiscal space for nutrition, however, requires government prioritiza- tion. Multisectoral strategies can utilize greater fiscal capacity to access growth across sectors. However, nutrition could be overlooked or crowded out if owner- ship and focus do not accompany growth. Reprioritization of nutrition within the government budget Another source of expansion of fiscal space is through reprioritization of nutri- tion in the overall government budget. Raising the overall share of nutrition spending, particularly in health, is often a challenge in Egypt because of the com- peting priorities for finite resources and the country’s highly centralized budget allocation decisions, leaving little space to advance a nutrition agenda. In Egypt, FIGURE 5.3 Revenue as percentage of GDP: Egypt, 2005–15 17 16 15 14 Percent 13 12 11 10 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015 Source: World Bank, https://data.worldbank.org/indicator/GC.TAX.TOTL.GD.ZS?locations=EG. 138 | Scaling Up Nutrition in the Arab Republic of Egypt health expenditure as a percentage of GDP was 5.6 percent in 2014 as reported by the World Bank.11 This share falls below the median (6.1 percent) and mean (6.8 percent) for lower-middle-income countries in the Middle East and North Africa, Sub-Saharan Africa, and South Asia in the same time period (see figure 5.4). There is an opportunity, therefore, for an increase in fiscal space for ­ nutrition through health. Nutrition strategies, however, are multisectoral and require prioritization and coordination at a high level to achieve common goals. Egypt’s nutrition pol- icy is mainly divided among eight ministries: Health and Population; Agriculture and Land Reclamation; Industry, Trade and Small Industries; Supply and Internal Trade; Social Solidarity; Local Development (representing governor- ates); Higher Education and Scientific Research; and Education. Effective organization and management across these sectors are needed to set common goals, prioritize interventions across sectors, and coordinate activities to promote efficiencies and build on synergistic activities. Prioritization of a multisectoral issue such as nutrition requires agreement and buy-in from all par- ticipating ministries. No interministerial or intraministerial committees exist in Egypt to aid in coordination or joint accountability. In addition, complementary FIGURE 5.4 Health expenditure share of GDP: selected countries, 2008–14 14 12 10 Percent of GDP 8 6 4 2 0 Ar gla n Re esh An ic Sr ola G a Bh a Ni n au ia m ia n bo dia e ia yp en p. Cô b R . d’ p. re or a Tu o sia Pr an pe Es an D ini Le uti o Ar ep k n ny rd c th n ta a oo bl M ger Ca tan b e e oi an oc ha ut d d at ci o ni g Ca In Co am Ye o, R ,R ria Ba kis Ve so ab d Ke pu an Jor Su Iv er jib ín w iL ri Pa Z a M ng te Eg m d t, é m n To Sy o Sã Source: World Development Indicators (database), World Bank, Washington, DC, current health expenditure (percent of GDP) indicator SH.XPD. TOTL.ZS, https://data.worldbank.org/indicator/. Note: Bars represent (from left to right) the years 2008–14. GDP = gross domestic product. Fiscal Space to Scale Up Nutrition in Egypt | 139 areas of interest result in overlapping efforts, wasted resources, and competing management and control. Chronic weakness in cross-ministerial coordination, a lack of clear roles and responsibilities, and the absence of a results-based accountability framework for such cross-sectoral policies make aligning priori- ties and implementing a common results framework challenging. Increase in sector-specific resources Although the multisectorality of nutrition presents challenges across sectors, there may be an opportunity to increase fiscal space through a broader range of sectoral options. Nutrition programming involves diverse dimensions and entities. Even with agreement across sectors, interest and commitment within ­ sectors vary. Understanding the variation in commitment as well as the potential for improving nutrition outcomes resulted in the prioritization of the 13 inter- ventions for scale-up, leaving health as the main sector of implementation in the short term. New resources could be collected within the health sector through programs such as taxes earmarked for health (or nutrition), mandatory fee-bearing pro- grams (such as insurance), or user fees for public health facilities. Earmarking is effective in that it specifies where funding must be directed, thereby protecting nutrition programming in years when it is not as highly prioritized. Such an approach takes political will and a commitment to guaranteeing long-term fund- ing, but it can be inefficient if nutrition priorities change and the earmarking does not align with new interventions. This is complicated in multisectoral envi- ronments where it is not simple to define or identify “nutrition interventions,” especially in a changing environment and within evolving understanding of evidence-based practices. Furthermore, it is important to ensure that earmark- ­ ing is not used simply to shift resources and that the earmarked funds do not replace the existing flows of funding. Increasing taxes specifically on goods that are known to have adverse impact nutrition outcomes, such as sugary drinks and junk food, is another option. In addition to raising revenue, this approach can also reduce the types of behav- iors that nutrition programming seeks to change, providing both public health and economic benefits. Even if the funds are not specifically earmarked for nutrition programs, improved public health and expansion of the general revenues should both benefit nutrition programs and outcomes. ­ Care must be taken when implementing such taxes, however, to ensure that the taxed goods are not disproportionately affecting the poor and that healthier substitutes are available when prices faced by consumers rise. A detailed ­benefit-incidence analysis is needed to ensure a tax is not regressive, that increas- ing taxes will raise total tax revenue (and by what amount), and to determine if the tax will affect employment. In Egypt, sugar subsidies have increased consumption of sugar at the expense of the government budget. Removing subsidies has the same general effect as raising taxes both in benefits and detriments. Consideration must be given to secondary markets and employment. Nutrition-specific grants or foreign aid External assistance for health, and more recently nutrition, can be an import- ant element of overall fiscal space for improving nutrition. However, Egypt is 140 | Scaling Up Nutrition in the Arab Republic of Egypt not heavily reliant on aid in this area. According to the NHA, external funding as a proportion of the current health expenditure in 2015 was only 0.3 percent, down from 0.4 percent in 2012, with no external sources of funding for treat- ment of nutrition deficiencies identified (table 5.2). The CRS data show that $5.2 million in ODA was disbursed for basic nutrition in 2015, with a further $3.6 million disbursed in 2016 by donors (table 5.3). The 2016 figure represents 3.2 percent of the $112 million required for current coverage of the 13 priori- tized nutrition interventions. The low level of reliance on external funding sources at a time when health and nutrition-specific aid programs have increased significantly since the adop- tion of the Millennium Development Goals (MDGs) suggests there may be room to expand donor funding in Egypt. However, the unpredictability of aid flows may increase the risk of losing sustainable prioritized programming. Requesting aid for specific programs or start-up costs for programs may be a way to mitigate the uncertainty of external funds. It is important to ensure that external aid does not replace domestic resources and that a withdrawal plan is in place. This is, however, less of an issue in countries such as Egypt where overall donor funding is a small percentage of health expenditures and where domestic funding can supplement programs. How funds are distributed is also important to the effectiveness of applying funds to activities in national-level nutrition plans. Where donor assistance is off-budget, donors can control how resources are used, possibly ignoring gov- ernment priorities. The method of funding in Egypt has become more important in light of the law Regulating the Work of Associations and Other Institutions Working in the Field of Civil Work issued in 2017, which requires a rigorous pro- cess of state approval for all NGO operations. Domestic organizations need prior permission before they “cooperate with, join, affiliate with, or participate with” any foreign organization. Authorization is also required before receiving any foreign funds or funds from Egyptians abroad, conducting field research, or col- ­ lecting data. This law could severely curtail the ability of donors to support pro- grams within Egypt. On the other hand, if the law is well implemented, the GoE would have a much better understanding of the flow of funds and would be better able to ensure that funds align with priorities and to redirect resources ­ where there are overlaps and inefficiencies. Increased efficiency of the existing sector outlays Efficiency—technical or allocative—is achieved by maximizing outputs with a given level of inputs. Technical efficiency is achieved when maximum output (for example, the number of children reached) is achieved for a given level of inputs. Allocative efficiency refers to the choice of an appropriate mix of inputs to achieve the outputs needed (for example, the appropriate targets are reached). Nutrition programming in Egypt can benefit through changes in both. The cost-effectiveness analysis in chapter 4 identifies the package of inter- ventions and scale-up scenarios that produces the most impact (in terms of deaths prevented in children under 5, cases of stunting averted, and DALYs averted) for the least cost (scenario 3). The intervention package includes IYCF programs (breastfeeding and promotion of complementary feeding); iron–folic acid supplementation for pregnant women; vitamin A supplementation for chil- dren; and hygienic disposal of children’s stools. Scaling up this intervention package to full national coverage would require $82 million over the five-year Fiscal Space to Scale Up Nutrition in Egypt | 141 period from 2018 to 2022. This investment would avert 4,249 deaths and 421,360 cases of stunting and save 23,713 DALYs. The wide variation in nutrition outcomes across governorates suggests inef- ficiencies in the implementation of effective interventions that should be addressed. Geographic targeting of governorates and individuals differentially affected by poor nutrition outcomes both saves resources by reaching those most likely to be affected by interventions and is allocatively efficient by targeting those vulnerable populations most in need. In addition, it would be helpful to understand how nutrition spending is disbursed through the sectors and distrib- uted to target populations. A number of inefficiencies can arise when there are multiple layers from disbursement to implementation. Further inefficiencies can arise if funds are tied to specific activities or delivery channels, but these approaches are not appropriate in all contexts. A balance must be found between securing funds for specific nutrition activities and allowing flexible spending for nutrition outcomes. Achieving that balance will depend largely on an ability to translate options and results through the delivery system to the targeted population. Absorptive capacity is another potential area of inefficiency. It is not enough to disburse funds; the funds must be used appropriately. Lack of personnel, poor infrastructure, and weak supply chains are often large contributors to lack of absorptive capacity. On the supply side, additional resources are required to develop new capacity and strengthen the existing health system to address mal- nutrition. Egypt utilizes the Monitoring of Results Equity System (MORES) framework, which can allow, for example, an in-depth look at how effectively health centers are performing. An important factor especially relevant to multisectoral programs such as nutrition is the ability to coordinate efforts across sectors. Coordinated efforts in programming can create significant efficiencies in sharing resources, delivery platforms, and messaging, and can improve the effectiveness of interventions. Integration of multisectoral efforts in sectoral plans and priorities is important to ensure that implementation is also efficiently achieved within sectors. Currently, Egypt does not have a fully-costed nutrition action plan. However, the GoE is committed to developing such a plan. It will be important to have realistic cost estimates for achieving the goals of any plan developed, as well as disbursements aligned with those estimates. Without a thoughtful alignment of costs and impacts, disbursements will not align with needs and inefficiencies will result. Further alignment of nutrition policies and plans with overall health and other sector strategies is also vital to facilitating efficiencies within and across sectors. Longer-term development and coordination are occurring through the Ministry of Planning, Monitoring and Administrative Reform in response to the Sustainable Development Goals (SDGs). Global nutrition strategies are integral to 10 of the 17 SDGs. Multisectoral nutrition planning should not be done in iso- lation; it should work in step with the Sustainable Development Strategy: Egypt Vision 2030. SUMMARY OF FISCAL SPACE Table 5.4 summarizes the prospect for creating fiscal space for nutrition in Egypt using the five pillars discussed in this chapter. Improved macroeconomic 142 | Scaling Up Nutrition in the Arab Republic of Egypt TABLE 5.4  Fiscal space for nutrition in Egypt FISCAL SPACE SOURCE EXPLANATION  PROSPECT FOR FISCAL SPACE Conducive macroeconomic conditions Would increase the medium- and long-term GDP growth from Good improved productivity due to a reduction in stunting Has potential for improved revenue generation Reprioritization of nutrition within the Would strengthen intrasectoral coordination Limited government budget Increase in sector-specific resources Would entail taxes earmarked for health (or nutrition), Limited mandatory fee-bearing programs (such as insurance), or user fees for public health facilities Nutrition-specific grants or foreign aid Egypt is not heavily reliant on aid in nutrition. Limited Increased efficiency of the existing Would produce allocative and operational efficiency gains in Good sector outlays delivering only the most cost-effective interventions in stunting reduction Source: World Bank assessment, based on guidelines laid out in Heller 2005. Note: GDP = gross domestic product. conditions in the long run as well as medium-run efficiency gains are two areas with good prospects of generating significant additional resources for nutrition. In the long run, it is reasonable to expect significant economic growth from the greater productivity of Egypt’s workforce stemming from the reduction in stunting. Lower levels of stunting and the resulting improved health will also reduce reliance on social programs and cut stunting-related health costs. Aside from economic growth, GoE revenue could also grow if tax revenue increases through an expanded tax base, new taxes, or more efficient tax collection. Allocative and operational efficiency gains can be obtained in the medium run by focusing on delivery of the most cost-effective interventions in stunting reduction: IYCF (especially promotion of complementary feeding), iron–folic acid supplementation, vitamin A supplementation for children, and promotion of hygienic disposal of children’s stools. These interventions are also those that can be scaled up quickly either with the existing capacity or with relatively small investments. This strategy is expected to translate into substantial economic benefits and return the highest economic benefits over the productive lives of the children who receive the interventions. This discussion relies heavily on public information available for the health sector in Egypt. A complete analysis of fiscal space for nutrition that includes both health and the seven other represented sectors would require expanding the specifics in the pillars discussed here to include information that rep- resents all nutrition spaces. This would include an assessment of the elasticity of nutrition spending with respect to GDP, which will require assessing in turn elasticity across sectors; an understanding of the share of nutrition expendi- tures in the budget and the disposition of all stakeholders toward expanding that share; an assessment of potential revenue sources in each of the ministries earmarked or connected to nutrition programs and outcomes; an examination of the effects of the law Regulating the Work of Associations and Other Institutions Working in the Field of Civil Work on donor participation in Egypt; and a thorough examination of the distribution channels for nutrition interventions and the willingness and ability of the relevant sectors and higher levels of the government of Egypt to administer the multisectoral efforts to combat malnutrition. Fiscal Space to Scale Up Nutrition in Egypt | 143 NOTES  1. Health and Population; Agriculture and Land Reclamation; Industry, Trade and Small Industries; Supply and Internal Trade; Social Solidarity; Local Development (representing governorates); Higher Education and Scientific Research; and Education.  2. See http://scalingupnutrition.org/share-learn/planning-and-implementation/tracking​ -nutrition-investments/ for a description of the three-step approach used by SUN countries.  3. Organisation for Economic Co-operation and Development/Development Assistance Committee Creditor Reporting System. OECD/DAC CRS database: https://stats.oecd.org​ /Index.aspx?DataSetCode=CRS1.  4. The Health Accounts Country Platform provides the System of Health Accounts (SHA) framework, tools, and templates. Data are publicly available through the WHO’S Global Health Expenditure Database (GHED). Information and data are available at http://www​ .who.int/health-accounts/en/.  5. http://www.oecd.org/tax/automatic-exchange/common-reporting-standard/.  6. The system also has the capacity to track development assistance from private donors, of which one, the Bill and Melinda Gates Foundation, currently participates.  7. http://stats.oecd.org/.  8. “Basic nutrition” includes direct feeding programs (maternal feeding, breastfeeding and weaning foods, child feeding, school feeding); determination of micronutrient deficiencies; provision of vitamin A, iodine, and iron; monitoring of nutritional status; nutrition and food hygiene education; and household food security.  9. A complete list of DAC and CRS codes can be found at http://www.oecd.org/dac/stats​ /dacandcrscodelists.htm. 10. Elasticity of 0.47 implies that a 1 percent increase in GDP is associated on average with a 0.47 percent increase in the government health expenditure. 11. World Bank, World Development Indicators (database), current health expenditure percent of GDP) indicator SH.XPD.TOTL.ZS, https://data.worldbank.org/indicator/. (­ REFERENCES D’Alimonte, M., S. Heung, and C. Hwang. 2016. Tracking Funding for Nutrition: Improving How Aid for Nutrition Is Reported and Monitored. Policy Brief, Results for Development (R4D), Washington, DC. https://www.r4d.org/wp-content/uploads/R4D_TrackingAid4Nutrition​ -final-1.pdf. Bevan, David. 2005. “An Analytical Review of Aid Absorption: Recognizing and Avoiding Macroeconomic Hazards.” Paper presented to Seminar on Foreign Aid and Microeconomic Management, Maputo, March 14–15. Heller, P. 2005. “Back to Basics—Fiscal Space: What It Is and How to Get It.” Finance and Development (International Monetary Fund) 42 (2). http://www.imf.org/external/pubs/ft​ /fandd/2005/06/basics.htm. Heller, P. S., M. Katz, X. Debrun, T. Thomas, T. Koranchelian, and I. Adenauer. 2006. “Making Fiscal Space Happen: Managing Fiscal Policy in a World of Scaled-up Aid.” Working Paper, International Monetary Fund, Washington, DC. http://www.imf.org/external/pubs/ft​ /wp/2006/wp06270.pdf. Horton, S., and R. H. Steckel. 2013. “Malnutrition: Global Economic Losses Attributable to Malnutrition 1990–2000 and Projections to 2050.” In How Much Have Global Problems Cost the World? A Scorecard from 1900 to 2050, edited by B. Lomborg, 247–72 Cambridge, U.K.: Cambridge University Press. IMF (International Monetary Fund). 2016. World Revenue Longitudinal Data Set (WoRLD), https://data.world/imf/world-revenue-longitudinal-dat. OECD (Organisation for Economic Co-operation and Development), Eurostat, and WHO (World Health Organization. 2011. A System of Health Accounts. 2011 Edition. Paris: OECD Publishing. http://www.who.int/nha/sha_revision/sha_2011_final1.pdf. World Bank. 2018. “Middle East and North Africa.” In Global Economic Prospects, January 2018: Broad-Based Upturn, but for How Long?, 117–156. Washington, DC: World Bank. http://­ pubdocs.worldbank.org/en/124691512062603210/Global​-Economic-Prospects-Jan-2018​ -Middle-East-and-North-Africa-analysis.pdf. APPENDIX A Statistical Methods Applied to Analysis of the Determinants of Malnutrition among Egyptian Children METHODS The following describes how the determinants from each level of the UNICEF Conceptual Framework for the Determinants of Malnutrition were operational- ized and the analytic approach taken. Identifying the immediate determinants Disease incidence. The Egypt Demographic and Health Survey (EDHS) provides information on recent incidence of infectious diseases among young children (MOHP, El-Zanaty and Associates, and ICF International 2015). In our analysis, we coded variables for the incidence of diarrhea and respiratory infection. For diarrhea, respondents were asked if the child had diarrhea in the two weeks pre- ceding the survey. A response of “yes” was coded 1; 0 otherwise. For respiratory infection, respondents were asked if the child experienced a cough accompanied by short rapid breaths in the two weeks preceding the survey. A response of “yes” for both conditions was coded 1; 0 otherwise. Identifying the underlying determinants Feeding practices. Feeding practices were defined according to the established World Health Organization (WHO) standards for infant and young child feeding (IYCF) practices (WHO 2008). Specifically, it is recommended that children under 6 months of age be exclusively breastfed and that children 6–23 months old of age continue breastfeeding and have a minimum number of feedings of nutritionally diverse complementary foods. A nutritionally diverse diet must include foods from at least four of the seven basic food groups; (1) grains, roots, and tubers; (2) legumes and nuts; (3) dairy (milk, yogurt, cheese); (4) meat and fish; (5) eggs; (6) fruits and vegetables rich in vitamin A; and (7) other fruits and vegetables. Table A.1 summarizes the recommendations for dietary intake for children 0–23 months of age, along with how the relevant indicators were coded in our analyses.  145 146 | Scaling Up Nutrition in the Arab Republic of Egypt TABLE A.1  Indicators for feeding practices AGE GROUP RECOMMENDATION VARIABLE Under 6 months Exclusively breastfed Exclusively breastfed = 1 if breastfed in the 24 hours preceding the survey and had no old other solid, semisolid, or soft foods or liquids; = 0 otherwise. Breastfed, At least two feedings Adequate feeding frequency = 1 if fed with solid, semisolid, or soft foods at least two 6–8 months and diverse diet times during the 24 hours preceding the survey; = 0 otherwise. old Diverse diet = 1 if child consumed foods from four of the seven basic food groups in the 24 hours preceding the survey; = 0 otherwise. Breastfed, At least three feedings Adequate feeding frequency = 1 if fed with solid, semisolid, or soft foods at least three 9–23 months and diverse diet times during the 24 hours preceding the survey; = 0 otherwise. old Diverse diet = 1 if child consumed foods from four of the seven basic food groups in the 24 hours preceding the survey; = 0 otherwise. Nonbreastfed, At least four feedings Adequate feeding frequency = 1 if fed with solid, semisolid, or soft foods at least four 6–23 months and two feedings of times during the 24 hours preceding the survey; = 0 otherwise. old milk and diverse diet Adequate milk feeding = 1 if child was fed with any combination of powdered/tinned/ (four of the six basic fresh milk, infant formula, and yogurt at least two times in the 24 hours preceding the food groups, not survey; = 0 otherwise. counting dairy, the seventh) Diverse diet = 1 if child consumed foods from four of the six basic food groups (excludes dairy from the standard seven) in the 24 hours preceding the survey; = 0 otherwise. Care practices. Care practices for both the mother and infant are considered. Infant care practices included early initiation of breastfeeding and timely atten- dance at a postnatal checkup after birth. Early initiation of breastfeeding was dichotomized and coded 1 if the mother reported having breastfed the infant within one hour of delivery; 0 otherwise. Timely attendance at postnatal checkup was coded 1 if the mother responded that the child received a checkup from a skilled provider within two days of birth; 0 otherwise. Maternal care practices included attendance at antenatal care visits, delivery in a health facility, and timely maternal postnatal care. Antenatal care was dichotomized, with 1 repre- senting four or more visits during the most recent pregnancy; 0 otherwise. Delivery in health facility was coded 1 for “yes”; 0 otherwise. Maternal postnatal checkup was coded 1 if the mother reported being examined by a skilled provider immediately or within two days of delivery; 0 otherwise. Household environment. The adequacy of the household environment was assessed based on the availability of improved water source and improved sanita- tion facilities. Improved facilities for water and sanitation were defined according to standards established by the WHO/UNICEF Joint Monitoring Programme for Water Supply, Sanitation, and Hygiene (2017). Variables for improved sanitation facility were each coded 1 if they met the Joint Monitoring Programme (JMP) cri- teria; 0 otherwise.1 Because nearly 86 percent of children lived in households with piped water, water source was dichotomized as 1 for piped source; 0 otherwise. Health services. Access to and utilization of health services was proxied using child’s immunization and vitamin A supplementation status. Completeness of immunization was defined based on guidelines for age-appropriate immuniza- tion from Egypt’s Ministry of Health and Population (UNICEF 2015). Vitamin A status was based on a child receiving a vitamin A supplement in the six months preceding the survey. Women’s empowerment. Women’s empowerment has been linked to positive child health and nutrition outcomes (Smith et al. 2003). We defined women’s status based on a series of questions about participation in three decisions: on large household purchases, on visiting her family, and on seeking care for herself. Each of these were dichotomized into binary variables for analysis. Statistical Methods Applied to Analysis of the Determinants of Malnutrition among Egyptian Children | 147 Identifying the basic determinants Basic determinants were modeled using maternal education and household wealth quintile. Maternal education was coded into categorical responses for no education, completed primary or less, incomplete secondary, completed second- ary, and higher education. Household wealth quintiles were based on the Demographic and Health Survey (DHS) classifications, with wealth quintile 1 comprising the poorest households and wealth quintile 5 comprising the richest households. OTHER BACKGROUND CHARACTERISTICS The regression models used in the analyses controlled for other maternal, child, and household background characteristics. These were maternal stature, maternal body mass index (BMI) status (thin, normal, overweight/ ­ obese), maternal age group (15–19, 20–24, 25–29, 30–34, 35 or older), child being a boy, child’s birth order (1, 2, 3, 4, 5, or greater), the preceding birth interval (less than 24 months, 24–35 months, 35–47 months, 48 months or longer), mother’s report of child’s size at birth, and the number of children under 5 in the household. STATISTICAL ANALYSIS Analytic sample. The 2014 EDHS data set includes records on 15,848 chil- dren under 5. Included in the sample are 5,752 children (36 percent of 0–5 sample) 0–23 months of age with valid anthropometric measurements. Our analytic sample excluded children who were not usual residents of the sam- ple household (328 cases) or not the youngest child living with the mother (231 cases). Our final analytic sample included 5,193 children 0–23 months of age. Analyses. Analyses were conducted using the R statistical computing soft- ware version 3.3.2 and accompanying packages for complex survey analysis and data manipulation (Lumley 2004; Smith et al. 2003).2 We used chi-square tests to assess the association between each variable and the odds of stunting. Variables from the bivariate analysis with p values of less than 0.30 were selected for inclu- sion in the subsequent multivariate models. We used multivariate logistic regres- sion models to assess the association between the odds of stunting and the set of child, maternal, and household variables at the immediate, underlying, and basic levels of the UNICEF framework for determinants of malnutrition. We then fit three models. First, we fit a model (I) for all children 0–23 months of age, includ- ing all covariates except breastfeeding and complementary feeding variables. Second, we fit the same model for children 0–5 months of age with an additional variable for exclusive breastfeeding (model II). And third, we fit model (I) for children 6–23 months of age and included variables for complementary feeding practices such as feeding frequency and diet diversity (model III). We report odds ratios and 95 percent confidence intervals for the multivariate models. Covariates from the regression estimates with p values less than 0.05 were con- sidered significant. We used survey weights and took account of clustering to adjust point estimates and standard errors for the complex sampling design of the DHS. 148 | Scaling Up Nutrition in the Arab Republic of Egypt NOTES 1. The JMP classification for improved water source is as follows: piped water into the dwell- ing, public taps, boreholes/tube wells, protected wells and springs, rainwater, packaged water, delivered water (including tankers and small carts); improved sanitation facilities: flush and pour flush toilets connected to sewer, flush and pour flush toilets or latrines connected to septic tanks or pits, ventilated improved pit latrine, pit latrines with slabs, ­ ­composting toilets. 2. Lumley, A. T. No date. “Survey: Analysis of Complex Survey Samples”. R package version 3.32. https://rdrr.io/rforge/survey/; R Core Team, R: A Language and Environment for Statistical Computing. R Found Stat Comput. 2016; version 3:3503, doi:10.1007/978-3-540​ -74686-7; H. Wickam, tidyverse: Easily Install and Load the “Tidyverse,” R package version 1.2.1. 2017, https://cran.r-project.org/package=tidyverse; H. Wickham and E. Miller, Haven: Import and Export “SPSS,” “Stata” and “SAS” Files. R package version 1.1.1. 2018, https:// cran.r-project.org/package=haven. REFERENCES Lumley, A. T. 2004. “Analysis of Complex Survey Samples.” Journal of Statistical Software 9 (1): 1–19. MOHP (Ministry of Health and Population), El-Zanaty and Associates, and ICF International. 2015. Egypt Demographic and Health Survey 2014. Cairo, Egypt and Rockville, MD: Ministry of Health and Population and ICF International. https://dhsprogram.com/pubs/pdf​ /FR302/FR302.pdf. Smith, L. C., U. Ramakrishnan, A. Ndiaye, L. Haddad, and R. Martorell. 2003. The Importance of Women’s Status for Child Nutrition in Developing Countries. Research Report 131, International Food Policy Research Institute, Washington, DC. UNICEF (United Nations Children’s Fund). 2015. “Immunization and Health.” In Children in Egypt: A Statistical Digest. Cairo: UNICEF. WHO (World Health Organization). 2008. Indicators for Assessing Infant and Young Child Feeding Practices: Part 1—Definitions: Conclusions of a Consensus Meeting held 6–8 November 2007 in Washington DC, USA. Geneva: WHO. http://apps.who.int/iris/bitstream​ /­handle/10 665/43895/9789241596664_eng.pdf?sequence=1. WHO (World Health Organization)/UNICEF (United Nations Children’s Fund) Joint Monitoring Programme for Water Supply and Sanitation. 2017. Progress on Drinking Water, Sanitation and Hygiene: 2017 Update and SDG Baselines. Geneva. https://www.who​ .int/mediacentre/news/releases/2017/launch-version-report-jmp-water-sanitation​ -hygiene.pdf. APPENDIX B Distribution of Sample by Key Characteristics and Regression Analysis Results  149 TABLE B.1  Distribution of sample of children 0–23 months of age by child, maternal, and household characteristics 150 | Scaling Up Nutrition in the Arab Republic of Egypt URBAN RURAL URBAN RURAL URBAN RURAL FRONTIER URBAN FRONTIER NATIONAL GOVERNORATES UPPER EGYPT UPPER EGYPT LOWER EGYPT LOWER EGYPT GOVERNORATES GOVERNORATES   (n = 5,193) (n = 714) (n = 1,632) (n = 611) (n = 1,408) (n = 494) (n = 102) (n = 232) Child characteristics Sex  Male 52.5 49.9 51.5 57.0 52.1 55.5 51.9 53.1  Female 47.5 5.01 48.5 43.0 47.9 44.5 48.1 46.9 Age group (months)  0–5 21.6 20.3 24.0 23.5 20.4 18.1 14.3 19.7  6–8 15.1 13.3 16.2 16.4 14.8 13.1 16.5 11.9  9–11 13.4 16.3 11.0 12.9 14.4 14.4 10.4 15.5  12–23 49.9 50.1 48.8 47.2 50.4 54.4 58.8 52.9 Birth order  First 27.7 26.6 23.9 25.1 31.8 28.1 17.8 31.5  Second 28.6 32.4 25.4 28.5 29.2 32.9 26.4 36.3  Third 22.8 22.7 21.0 22.4 24.4 23.5 20.9 14.5  Fourth 12.5 14.0 14.0 14.4 10.7 11.0 13.7 9.0   Fifth or later 8.4 4.3 15.7 9.6 3.9 4.5 21.2 8.7 Birth size   Large or very large 2.2 1.4 2.3 0.4 2.9 2.2 1.1 4.4  Average 80.9 85.9 80.5 85.2 79.1 79.2 92.2 72.3   Small or very small 16.9 12.7 17.2 14.4 18.0 18.6 6.7 23.3   Has all age-appropriate immunizations 82.6 85.0 80.8 82.4 83.3 82.7 78.0 85.9 Maternal characteristics Age group (years)  15–19 4.8 2.2 5.8 3.2 5.4 3.7 5.5 2.5  20–24 28.3 16.6 31.1 23.5 32.5 18.9 20.7 31.2  25–29 34.2 36.2 32.0 30.7 35.0 40.1 38.6 32.9  30–34 20.7 25.4 20.0 25.4 18.0 24.3 19.9 20.1   35 or older 12.0 19.6 11.1 17.2 9.1 13.0 15.3 13.3 Education   No education 16.3 10.3 27.9 13.0 11.5 6.7 35.8 11.4   Primary or less 8.7 8.5 10.9 7.5 7.8 6.7 14.7 7.5   Incomplete secondary 15.0 14.1 18.0 13.4 14.2 11.4 10.9 13.0 continued TABLE B.1, continued URBAN RURAL URBAN RURAL URBAN RURAL FRONTIER URBAN FRONTIER NATIONAL GOVERNORATES UPPER EGYPT UPPER EGYPT LOWER EGYPT LOWER EGYPT GOVERNORATES GOVERNORATES   (n = 5,193) (n = 714) (n = 1,632) (n = 611) (n = 1,408) (n = 494) (n = 102) (n = 232)   Completed secondary 43.7 41.0 36.0 45.1 49.9 45.5 25.1 44.4   Higher education 16.3 26.1 7.2 21.0 16.6 29.7 13.5 23.7 Maternal characteristics Height   <145 cm 0.7 0.3 1.2 0.6 0.4 0.2 2.3 0.1   ≧145 cm 99.3 99.7 98.8 99.7 99.6 99.8 97.7 99.9 BMI   Thin (BMI <18.5) 0.4 0.3 0.7 0.2 0.3 0.0 0.3 0.0   Normal (BMI ≧18.5 and <25) 23.8 23.0 29.1 19.4 23.2 13.5 30.9 28.4   Overweight or obese (BMI ≧25) 75.8 76.7 70.2 80.4 76.5 86.5 68.8 71.6 Attended at least four antenatal visits during last 83.0 89.6 72.6 81.0 88.3 91.8 64.9 84.6 pregnancy Distribution of Sample by Key Characteristics and Regression Analysis Results | 151 Had postnatal care checkup after last delivery 97.7 98.7 97.7 98.9 97.4 96.5 100.0 97.0 Delivered last child in health facility 88.2 95.2 79.0 90.9 91.0 97.5 76.0 90.1 Makes decisions about her own health care 80.2 85.9 76.0 87.0 79.3 85.0 69.2 80.1 Makes decisions about large household purchases 63.6 71.0 52.3 74.3 66.4 70.7 60.5 57.7 Makes decisions about visiting her family 71.9 82.2 64.2 79.8 71.6 79.1 64.8 70.0 Household characteristics Place of residence  Urban 29.8 n.a. n.a. n.a. n.a. n.a. n.a. n.a.  Rural 70.2 n.a. n.a. n.a. n.a. n.a. n.a. n.a. Wealth index  Poorest 16.7 0.8 31.4 4.0 15.7 2.6 33.8 14.0  Second 18.8 0.8 35.4 3.6 18.1 1.9 31.3 5.0  Third 25.4 2.0 25.8 7.5 41.0 3.4 27.0 4.1  Fourth 22.8 31.6 7.4 39.5 25.2 36.4 7.9 27.6  Richest 16.3 64.8 0.0 45.4 0.0 55.7 0.0 49.3 Household has piped water into the dwelling 89.7 96.5 90.5 97.0 85.6 90.8 60.2 68.1 Household uses improved sanitation 88.9 99.5 92.7 98.4 78.1 99.2 99.3 100.0 Number of children under 5 in the household   Less than three 87.5 91.6 81.5 90.5 89.6 92.7 72.0 89.4   Three or more 12.5 8.4 18.5 9.5 10.4 7.8 28.0 10.6 Note: BMI = body mass index; cm = centimeter; n = number; n.a. = not applicable. 152 | Scaling Up Nutrition in the Arab Republic of Egypt TABLE B.2  Adjusted odds ratio of stunting for children 0–23 months of age in Egypt AGE GROUP 0–23 MONTHS 0–5 MONTHS 6–23 MONTHS ADJUSTED OR (95% CI) ADJUSTED OR (95% CI) ADJUSTED OR (95% CI) Sex (reference: female)  Male 1.47*** (1.22, 1.78) 2.01** (1.28, 3.16) 1.44*** (1.17, 1.78) Child’s size at birth (mother’s report) (reference: average size)   Large or very large 0.54 (0.25, 1.17) 1.74 (0.36, 8.47) 0.42* (0.18, 0.99)   Small or very small 1.25 (0.98, 1.60) 1.88* (1.06, 3.34) 1.16 (0.88, 1.52) Early initiation of breastfeeding 0.75** (0.60, 0.93) 0.67 (0.38, 1.17) 0.77* (0.61, 0.98) Adequate meal frequency 0.99 (0.80, 1.24) Fed a diverse diet 1.13 (0.91, 1.41) Currently breastfed 0.91 (0.69, 1.20) Exclusively breastfed 0.93 (0.54, 1.60) Mother’s education level (reference: completed secondary)   No education 1.11 (0.82, 1.49) 1.24 (0.64, 2.40) 1.12 (0.80, 1.56)   At least some primary 1.34 (0.95, 1.90) 1.20 (0.52, 2.75) 1.37 (0.94, 2.02)   Incomplete secondary 1.35* (1.03, 1.77) 1.78 (0.95, 3.34) 1.25 (0.93, 1.70)   Completed secondary 1.07 (0.82, 1.41) 1.08 (0.55, 2.09) 1.06 (0.78, 1.44)  Higher 0.87 (0.71, 1.08) 0.81 (0.50, 1.31) 0.88 (0.69, 1.12) Child received postnatal checkup 0.99 (0.76, 1.29) 0.63 (0.34, 1.17) 1.04 (0.77, 1.39) Mother received postnatal checkup 1.68 (0.87, 3.23) 1.96 (0.41, 9.31) 1.63 (0.80, 3.35) Woman participates in decisions on large household purchases 0.87 (0.69, 1.10) 0.78 (0.45, 1.33) 0.88 (0.68, 1.13) Woman participates in decisions about visiting her family 1.02 (0.80, 1.30) 1.10 (0.60, 2.03) 1.04 (0.79, 1.36) Wealth quintile (reference: poorest)  Second 1.20 (0.88, 1.64) 0.52 (0.22, 1.23) 1.32 (0.93, 1.87)  Third 0.89 (0.64, 1.22) 1.03 (0.50, 2.14) 0.88 (0.61, 1.27)  Fourth 1.02 (0.70, 1.48) 2.48* (1.03, 5.99) 0.87 (0.57, 1.31)  Richest 1.17 (0.74, 1.87) 2.51 (0.77, 8.17) 1.03 (0.62, 1.72) Household has improved toilet facility 1.05 (0.74, 1.49) 1.22 (0.53, 2.82) 1.02 (0.69, 1.52) Region (reference: urban governorates)   Rural Upper Egypt 1.48 (0.96, 2.30) 1.62 (0.54, 4.85) 1.55 (0.96, 2.50)   Urban Upper Egypt 1.74** (1.20, 2.51) 0.89 (0.37, 2.13) 2.04*** (1.35, 3.09)   Rural Lower Egypt 0.97 (0.64, 1.48) 0.91 (0.33, 2.51) 1.00 (0.63, 1.58)   Urban Lower Egypt 0.99 (0.67, 1.48) 0.40 (0.14, 1.12) 1.21 (0.78, 1.88)   Rural frontier governorates 0.86 (0.38, 1.98) 2.40 (0.30, 19.40) 0.77 (0.31, 1.93)   Urban frontier governorates 1.33 (0.80, 2.20) 0.57 (0.18, 1.78) 1.53 (0.87, 2.70) Note: CI = confidence interval; OR = odds ratio. *p < .05 **p < .01 ***p < .001. Distribution of Sample by Key Characteristics and Regression Analysis Results | 153 TABLE B.3  Adjusted odds ratio of stunting for urban children 0–23 months in Egypt AGE GROUP 0–23 MONTHS 0–5 MONTHS 6–23 MONTHS ADJUSTED OR (95% CI) ADJUSTED OR (95% CI) ADJUSTED OR (95% CI) Sex (reference: female)  Male 1.51** (1.11, 2.06) 1.92 (0.90, 4.09) 1.47* (1.04, 2.07) Child’s size at birth (mother’s report) (reference: average size)   Large or very large 0.46 (0.09, 2.30) 0.05* (0.005, 0.64) 0.51 (0.09, 2.88)   Small or very small 0.98 (0.65, 1.48) 1.64 (0.58, 4.64) 0.91 (0.57, 1.46) Early initiation of breastfeeding 1.08 (0.76, 1.53) 0.72 (0.31, 1.67) 1.24 (0.83, 1.84) Adequate meal frequency 1.08 (0.75, 1.55) Fed a diverse diet 1.07 (0.74, 1.53) Currently breastfed 0.83 (0.53, 1.28) Exclusively breastfed 0.76 (0.30, 1.97) Mother’s education level (reference: completed secondary)   No education 1.31 (0.73, 2.36) 0.51 (0.14, 1.88) 1.61 (0.86, 3.02)   At least some primary 0.81 (0.42, 1.59) 0.77 (0.18, 3.29) 0.74 (0.34, 1.60)   Incomplete secondary 1.15 (0.71, 1.86) 1.59 (0.47, 5.44) 1.07 (0.62, 1.84)  Higher 1.11 (0.78, 1.60) 1.33 (0.56, 3.18) 1.05 (0.70, 1.57) Mother is overweight or obese 0.90 (0.62, 1.31) 0.45 (0.20, 1.00) 1.10 (0.70, 1.72) Child received postnatal checkup 0.82 (0.53, 1.26) 0.21* (0.06, 0.75) 1.06 (0.67, 1.69) Mother received postnatal checkup 3.61 (0.90, 14.38) 3.02 (0.28, 32.23) 4.58 (0.76, 27.66) Mother participates in decisions on large household purchases 0.85 (0.58, 1.24) 1.93 (0.82, 4.53) 0.74 (0.48, 1.12) Mother participates in decisions about visiting her family 1.19 (0.76, 1.86) 0.59 (0.20, 1.69) 1.34 (0.81, 2.21) Household in top two wealth quintiles 1.17 (0.66, 2.08) 1.65 (0.41, 6.56) 1.13 (0.59, 2.16) Note: CI = confidence level; OR = odds ratio. *p < 0.05 **p < 0.01 ***p < 0.001. 154 | Scaling Up Nutrition in the Arab Republic of Egypt TABLE B.4  Adjusted odds ratio of stunting for rural children 0–23 months in Egypt AGE GROUP 0–23 MONTHS 0–5 MONTHS 6–23 MONTHS ADJUSTED OR (95% CI) ADJUSTED OR (95% CI) ADJUSTED OR (95% CI) Sex (reference female)  Male 1.48** (1.17, 1.87) 2.06* (1.18, 3.61) 1.47** (1.13, 1.91) Child’s size at birth (mother’s report) (reference: average size)   Large or very large 0.50 (0.21, 1.24) 1.83 (0.29, 11.55) 0.35* (0.13, 0.95)   Small or very small 1.39* (1.03, 1.86) 1.95 (0.97, 3.96) 1.32 (0.95, 1.84) Early initiation of breastfeeding 0.64** (0.48, 0.85) 0.64 (0.29, 1.43) 0.65** (0.48, 0.88) Adequate meal frequency 0.92 (0.69, 1.22) Fed a diverse diet 1.20 (0.91, 1.59) Currently breastfed 0.95 (0.66, 1.36) Exclusively breastfed 0.95 (0.47, 1.90) Mother’s education level (reference: completed secondary)   No education 1.08 (0.76, 1.53) 1.67 (0.77, 3.58) 1.01 (0.68, 1.49)   At least some primary 1.53* (1.02, 2.30) 1.50 (0.54, 4.22) 1.52 (0.97, 2.38)   Incomplete secondary 1.48* (1.07, 2.06) 2.06 (0.98, 4.33) 1.36 (0.95, 1.96)  Higher 1.02 (0.67, 1.55) 0.80 (0.28, 2.28) 1.07 (0.68, 1.69) Mother is overweight or obese 0.83 (0.64, 1.07) 1.09 (0.60, 2.00) 0.79 (0.59, 1.05) Child received postnatal checkup 1.09 (0.78, 1.52) 0.99 (0.48, 2.02) 1.06 (0.73, 1.54) Mother received postnatal checkup 1.28 (0.61, 2.70) 1.70 (0.26, 10.95) 1.26 (0.56, 2.83) Mother participates in decisions on large household purchases 0.88 (0.66, 1.17) 0.53 (0.28, 1.00) 0.96 (0.70, 1.31) Mother participates in decisions about visiting her family 0.97 (0.72, 1.31) 1.27 (0.64, 2.50) 0.95 (0.68, 1.32) Wealth quintile (reference: poorest)  Second 1.15 (0.84, 1.57) 0.54 (0.23, 1.28) 1.25 (0.88, 1.77)  Third 0.76 (0.55, 1.05) 0.95 (0.47, 1.92) 0.74 (0.51, 1.06)  Fourth 0.81 (0.53, 1.22) 2.39 (0.98, 5.88) 0.63 (0.39, 1.01) Household has improved toilet facility 1.23 (0.87, 1.74) 1.25 (0.55, 2.85) 1.22 (0.83, 1.80) Note: CI = confidence level; OR = odds ratio. *p < 0.05 **p < 0.01 ***p < 0.001. Glossary adiposity The quality or state of being fat. anemia Defined as a hemoglobin concentration below a specified cutoff point that can change according to the age, gender, physiological status, smoking hab- its, and altitude at which the population being assessed lives. The World Health Organization (WHO) defines anemia in children under 5 years of age and preg- nant women as a hemoglobin concentration of less than 110 grams per liter at sea level. A low hemoglobin concentration impairs the ability of red blood cells to supply oxygen to body tissues and is associated with an increased risk of mater- nal and child mortality. Anemia can be caused by an inadequate intake or poor absorption of iron, folate, vitamin B12, and other nutrients, as well as infectious diseases (including malaria and hookworm infections) and genetic factors. Iron-deficiency anemia reduces the work capacity of individuals and entire ­ populations, with serious consequences for an economy and national develop- ­ ment. In addition, the negative consequences of iron-deficiency anemia on the cognitive and physical development of children and on physical performance—­ particularly on the work productivity of adults—are major concerns. anthropometry Measurement of physical body characteristics, most com- monly weight and height, but also circumference of body parts (head, arm, waist, etc.), as a tool for monitoring growth. Anthropometry is also used as a proxy indicator of nutritional status. Anthropometric indicators can point to malnutri- tion, but they do not provide evidence of deficiencies in specific macro- or micronutrients. body mass index (BMI) A measure of relative weight given by weight in kilo- grams divided by height in square meters. In adults, both underweight (thin- ness) and overweight are measured using BMI. colostrum The first breast milk secreted in the first few days after childbirth, often thick and yellow. Colostrum has many health and nutrition benefits: it con- tains antibodies and other proteins that help transfer immunity from the mother to child and protect the infant from infection; it contains growth factors to keep the intestines mature; and it is rich in vitamin A, vitamin K, and other nutrients.  155 156 | Scaling Up Nutrition in the Arab Republic of Egypt complementary feeding The process of introducing age-appropriate, ade- quate, and safe solid or semisolid foods in addition to breast milk or a breast milk substitute when breast milk alone is no longer sufficient to meet the nutritional requirements of an infant. The target age range for complementary feeding is 6–23 months. disability-­adjusted life year (DALY) A measure equivalent to a year of healthy life lost from a health condition. The DALY, developed in 1993 by the World Bank, is a measure of the overall disease burden and combines the years of life lost from a disease and the years of life spent with disability from the disease. DALYs averted is a key measure used in health economics to evaluate and com- pare the cost-effectiveness of health programs and interventions. It captures the number of years of a person’s life saved by a given intervention and adjusts it by the health status that person is expected to have during those years. Combined with cost data, DALYs allow one to estimate and compare the cost-effectiveness of scaling up nutrition interventions in different countries. epigenetic modifications Changes in the expression of genes (rather than the genes themselves), which can stem from external and internal environmental exposures and influence physiological processes such as metabolism and the development of disease. Epigenetic modifications provide a potential link between maternal nutrition, early life environmental exposures, and susceptibil- ity to disease. food fortification Addition of micronutrients to food during or after processing. infant and young child feeding (IYCF) Feeding of infants (under 12 months of age) and young children (12–23 months of age). The key interventions of IYCF include protection, promotion, and support of optimal breastfeeding practices (exclusive breastfeeding for the first six months and continued breastfeeding for two years or beyond) and support for and promotion of optimal complementary feeding practices (such as the timely introduction of complementary feeding). Issues of policy and legislation around the regulation of marketing infant formula and other breast milk substitutes are also addressed by these interventions. Lives Saved Tool (LiST) An estimation tool that translates measured coverage changes into estimates of mortality reduction and cases of childhood stunting averted. LiST is used to estimate the impact of scaling up health and nutrition interventions on maternal, newborn, and child health, and stillbirths. low birthweight (LBW) Weight of less than 2,500 grams at time of birth. LBW is a significant public health concern, with the birth of LBW infants 20 times more likely than that of heavier infants. It is associated with a greater likelihood of developing stunting and chronic diseases later in life. It includes preterm neo- nates (born before 37 weeks of gestation), small-for-gestational-age neonates at term, and the overlap between these two situations (preterm and small-for-­ gestational-age neonates). macronutrients The fat, protein, and carbohydrates needed for a wide range of body functions and processes. malnutrition A broad term commonly used as an alternative to undernutrition but that technically refers to any dysfunction of nutrition, including inadequate, excessive, or unbalanced nutrition. Glossary | 157 metabolic syndrome A group of risk factors including abdominal obesity, dys- lipidemia, hypertension, and impaired glucose tolerance. micronutrients Essential vitamins and minerals required in miniscule amounts for the maintenance of essential body processes. mid–upper arm circumference (MUAC) The circumference of the mid–upper arm as measured on a straight left arm midway between the tip of the shoulder and the tip of the elbow. This measure can be used to measure acute malnutrition and wasting in children 6–59 months of age. nutrition-­sensitive interventions Interventions that address the underly- ing determinants of malnutrition and development (such as food security and adequate resources) at the individual (especially maternal and caregiver), household, and community levels; access to health services and a safe and hygienic environment; and access to information about healthy food choices. These interventions incorporate specific nutrition goals and actions. Nutrition-sensitive programs can be used as delivery platforms for nutri- tion-specific interventions, which can increase their scale, coverage, and effectiveness. nutrition-­specific interventions Interventions that address the immediate determinants of malnutrition, including fetal and child nutrition and develop- ment or the nutritional status of older children and adults (adequate food and nutrient intake, feeding, caregiving and parenting practices, and burden of infec- tious disease). obesogenic Factors tending to make individuals fat, such as environments dense that promote decreased physical activity or increased intake of energy-­ foods. overnutrition Consumption of more calories than needed to maintain growth and health. overweight/obesity For children under 5, overweight is measured as a child who has a weight for height more than two standard deviations higher than the median for a child of the same height and sex, according to the WHO Child Growth Standard. WHO has recommended classifications of overweight (BMI greater than or equal to 25) and obesity (BMI greater than or equal to 30) that are associated with an increased risk of some noncommunicable diseases. As a measure of relative body weight, BMI is easy to obtain. It is an acceptable proxy for fatness and has been directly related to health risks and death rates in many populations. At the population level, the prevalence of overweight/obesity derived from BMI cutoffs can be useful for developing and implementing pol- icy actions and for facilitating prevention. BMI cutoffs for overweight and obesity can also be used as screening tools to identify high-risk individuals and ­ for diagnostic purposes in combination with other clinical measurements and risk factors. short stature Often measured in women of reproductive age and defined as height less than 145 centimeters. Women of short stature are at greater risk of obstetric complications because of a smaller pelvis. Small women are at greater risk of delivering an infant with low birthweight, which contributes to an inter- generational cycle of malnutrition because infants of low birthweight or retarded intrauterine growth tend to be smaller as adults. 158 | Scaling Up Nutrition in the Arab Republic of Egypt stunting Often referred to as “chronic malnutrition” and measured as low height for age, stunting is the most common form of undernutrition. Among ­children under 5, stunting is reflected in low height for age (that is, a height more than two standard deviations below the median height of a child of the same age and sex, according to the WHO Child Growth Standard). The percentage of children with a low height for age (stunting) reflects the cumulative effects of ­ undernutrition and infections since and even before birth. This measure can therefore be interpreted as an indication of poor environmental conditions or long-term restriction of a child’s growth potential. undernutrition A state of inadequate or unbalanced intake or absorption of the macro- and micronutrients needed for growth and maintenance of health, resulting in nutrition deficiency. Undernutrition covers a range of disorders, including growth failure and micronutrient deficiencies. underweight Low weight for age. Among children under 5, underweight is reflected in a weight that is more than two standard deviations below the median weight of a child of the same age and sex, according to the WHO Growth Standard. The percentage of children who are underweight can include children who have both low weight for height and low height for age. Thus it is a compos- ite indicator and can be difficult to interpret. wasting Also known as acute malnutrition. Among children under 5, wasting can be measured using weight-for-height or mid–upper arm circumference. Using weight-for-height cutoffs, wasting is defined as a weight that is more than two standard deviations below the median weight of a child of the same height and sex. Using MUAC, acute malnutrition is defined as an MUAC of less than 125 millimeters or the presence of bilateral pitting edema. There are two levels of wasting severity: moderate acute malnutrition (MAM) and severe acute ­ malnutrition (SAM). Wasting in children is a symptom of acute undernutrition, usually as a consequence of insufficient food intake or a high incidence of infectious diseases, especially diarrhea. Wasting in turn impairs the functioning ­ of the immune system and can lead to greater susceptibility to infectious diseases, increased severity and duration of such diseases, and an increased risk ­ of death. ECO-AUDIT Environmental Benefits Statement The World Bank Group is committed to reducing its environmental footprint. In support of this commitment, we leverage electronic publishing options and print- on-demand technology, which is located in regional hubs worldwide. Together, these initiatives enable print runs to be lowered and shipping distances decreased, resulting in reduced paper consumption, chemical use, greenhouse gas emissions, and waste. We follow the recommended standards for paper use set by the Green Press Initiative. The majority of our books are printed on Forest Stewardship Council (FSC)–certified paper, with nearly all containing 50–100 percent recycled content. The recycled fiber in our book paper is either unbleached or bleached using totally chlorine-free (TCF), processed chlorine–free (PCF), or enhanced elemental chlo- rine–free (EECF) processes. More information about the Bank’s environmental philosophy can be found at http://www.worldbank.org/corporateresponsibility. M alnutrition is a huge burden on the Arab Republic of Egypt’s economy. Undernutrition—manifested by poor linear growth (stunting), wasting, and micronutrient deficiencies in children and by anemia among women of reproductive age—collectively saps an estimated two percent of Egypt’s annual gross domestic product through forgone productivity and health care costs, representing an economic hemorrhaging of billions of U.S. dollars per year. Adding to this challenge is the co-occurrence of overweight and obesity among children, leading to a malnutrition double burden. Scaling Up Nutrition in the Arab Republic of Egypt aims to inform the development of nutrition policy and guide nutrition investments over the coming years. It reviews Egypt’s nutrition situation, the interventions currently in place, and the opportunities, costs, benefits, and fiscal space implications of scaling up a set of high-impact interventions to address undernutrition. The book, a collaborative effort between the World Bank and UNICEF, is targeted at all those involved in developing and implementing nutrition interventions in Egypt and beyond. ISBN 978-1-4648-1467-9 SKU 211467