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Nutritional status of school-age children and adolescents in low- and middle-income countries across seven global regions: a synthesis of scoping reviews

Published online by Cambridge University Press:  14 February 2022

Stephanie V Wrottesley*
Affiliation:
Emergency Nutrition Network (ENN), 2nd Floor, 69 High St, Marlborough House, Kidlington, Oxfordshire OX5 2DN, UK
Emily Mates
Affiliation:
Emergency Nutrition Network (ENN), 2nd Floor, 69 High St, Marlborough House, Kidlington, Oxfordshire OX5 2DN, UK
Eilise Brennan
Affiliation:
Emergency Nutrition Network (ENN), 2nd Floor, 69 High St, Marlborough House, Kidlington, Oxfordshire OX5 2DN, UK
Vasundhara Bijalwan
Affiliation:
Department of Population Health, London School of Hygiene & Tropical Medicine, London, UK
Rachael Menezes
Affiliation:
Emergency Nutrition Network (ENN), 2nd Floor, 69 High St, Marlborough House, Kidlington, Oxfordshire OX5 2DN, UK Department of Population Health, London School of Hygiene & Tropical Medicine, London, UK
Stephanie Ray
Affiliation:
Department of Population Health, London School of Hygiene & Tropical Medicine, London, UK
Zakari Ali
Affiliation:
Emergency Nutrition Network (ENN), 2nd Floor, 69 High St, Marlborough House, Kidlington, Oxfordshire OX5 2DN, UK Nutrition Theme, MRC Unit The Gambia, London School of Hygiene & Tropical Medicine, Banjul, The Gambia
Amirhossein Yarparvar
Affiliation:
UNICEF Regional Office for Europe and Central Asia, Almaty, Kazakhstan
Deepika Sharma
Affiliation:
UNICEF Headquarters, New York, NY, USA
Natasha Lelijveld
Affiliation:
Emergency Nutrition Network (ENN), 2nd Floor, 69 High St, Marlborough House, Kidlington, Oxfordshire OX5 2DN, UK
*
*Corresponding author: Email [email protected]
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Abstract

Objective:

To summarise available evidence on the nutritional status of school-age children and adolescents (5–19 years) from seven global regions and on interventions implemented to improve malnutrition in this population.

Setting:

Global.

Design:

Findings were compiled from seven scoping literature reviews, including data from low- and middle-income countries within the following UNICEF-defined global regions: East Asia and Pacific; Europe and Central Asia; South Asia; West and Central Africa; Eastern and Southern Africa; Middle East and North Africa and Latin America and the Caribbean.

Results:

A double burden of malnutrition was evident across the world regions reviewed: stunting, thinness, anaemia and other micronutrient deficiencies persisted, alongside rising overweight and obesity prevalence. Transitions towards diets increasingly high in energy-dense, processed and micronutrient-poor foods were observed. Evidence from intervention studies was limited, but suggested that providing multiple micronutrient-fortified foods or beverages at school may effectively target micronutrient deficiencies and facilitate weight gain in undernourished populations. Interventions to prevent or manage overweight and obesity were even more limited. There was minimal evidence of using novel technological approaches to engage school-age children and adolescents, or of involving them in designing interventions.

Conclusion:

The limited data available on nutrition of school-age children and adolescents are neither standardised nor comparable. Consensus on methods for assessing nutritional status and its determinants for this age group is urgently needed to set targets and monitor progress. Additionally, strategies are required to ensure that nutritious, safe and sustainable diets are available, affordable and appealing.

Type
Scoping Review
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of The Nutrition Society

The United Nations Sustainable Development Goal 2 calls for an end to all forms of malnutrition by 2030(1). To this end, global investment in nutrition has predominantly focused on children under 5 years of age and on pregnant and lactating women. In recent years, the adolescent period (defined by the WHO as between the ages of 10 and 19 years) has gained recognition as a potential second window of opportunity for achieving targeted gains in growth and development, with long-term nutrition and health benefits for current and future generations(Reference Prentice, Ward and Goldberg2Reference Patton, Olsson and Skirbekk5). However, the lack of inclusion of school-age children (5–9 years) and adolescents in research, policy and programming limits our understanding of the burden of malnutrition in these age groups, as well as of effective interventions(Reference Patton, Sawyer and Santelli6Reference Canavan and Fawzi8).

As children transition through adolescence and puberty, they experience rapid physical, behavioural and emotional growth. They also gain independence and the social determinants of their health behaviours broaden(Reference Viner, Ozer and Denny9). During this time, adolescents may be highly susceptible to the adoption of unhealthy lifestyles (including diet and activity behaviours), which can persist into adulthood(Reference Viner, Ozer and Denny9,Reference Frech10) . In low- and middle-income countries (LMIC), this is exacerbated by rapid urbanisation, which exposes adolescents to increasingly obesogenic environments characterised by energy-dense and ultra-processed diets and low levels of physical activity, often alongside food insecurity(Reference Popkin, Corvalan and Grummer-Strawn11Reference Farrell, Thow and Abimbola13).

According to the latest global Demographic and Health Survey data for non-pregnant adolescent girls (15–19 years) (Lelijveld et al., unpublished results), the prevalence of thinness ranges between 2 % in the Europe and Central Asia (ECA) region and 7 % in South Asia (SA). On the other hand, the East Asia and Pacific (EAP) region demonstrates a 4 % prevalence of overweight and obesity, compared with a prevalence of 40 % in Middle East and North Africa (MENA) region. Anaemia prevalence has remained high, affecting approximately 26 % of adolescent girls in ECA and 52 % in West and Central Africa (WCA). Given the rapidly transitioning patterns of malnutrition experienced in LMIC, as well as the limited inclusion of both girls and boys during later childhood and adolescence in monitoring of nutrition indicators at national and regional levels, exploration into available data describing the burden of malnutrition within and between regions is needed. In addition, better understanding of the determinants of malnutrition in these age groups, including dietary patterns, as well as differences according to age, sex and setting (e.g. rural v. urban), would be valuable in developing and targeting interventions.

To date, few interventions have been implemented to improve nutritional status in 5–19-year-olds. Additionally, while previous systematic reviews have explored evidence from interventions which tackle specific nutrition indicators (e.g. overweight and obesity(Reference Flodgren, Helleve and Lobstein14)) and/or via specific approaches (e.g. lifestyle modification(Reference Salam, Padhani and Das15)) reviews have failed to explore interventions targeting all forms of malnutrition in LMIC via diverse approaches, while taking into account context-specific prevalence and determinants of malnutrition across global regions.

Thus, this review aims to (1) summarise available evidence on the nutritional status of school-age children and adolescents (5–19 years) from LMIC in seven global regions and (2) describe evidence on the design, primary outcome(s) and main findings of interventions implemented to improve malnutrition in this population.

Methods

In preparing this paper, data were compiled from seven scoping literature reviews conducted by the authors focusing on LMIC within the following seven UNICEF-defined world regions: EAP; ECA; SA; WCA; Eastern and Southern Africa (ESA); MENA; and Latin America and the Caribbean (LAC). Due to the heterogeneity in the availability, design and outcomes of studies across countries, scoping review methodology was used to ensure that studies were not excluded based on systematic review criteria and that research gaps related to the heterogeneity of research in the area could be identified. All reviews were conducted between January 2020 and January 2021 to summarise the nutritional status of school-age children and adolescents (5–19 years old), as well as interventions implemented to target malnutrition in this population.

Search strategy

Literature searches were carried out using the PubMed, Embase, Cochrane, Web of Science (ESA and MENA), Africa Wide Information (ESA), ADOLEC (LAC), Global Health (EAP) and ScienceDirect (ECA) databases. A population, interventions, control and outcome (PICO) framework (Table 1) was used to define search terms (Supplementary Appendix A) and to guide the screening of articles. The results were reported according to the PRISMA guidelines for scoping reviews.

Table 1 Population, interventions, control and outcome (PICO) framework

Outcome definitions and classifications: stunting, height-for-age <−2 standard deviations (sd) below the WHO Child Growth Reference median; wasting, weight-for-height <−2 sd below the WHO Child Growth Reference median(Reference de Onis, Onyango and Borghi90); thinness, BMI-for-age <−2 sd below the WHO Growth Reference median(Reference de Onis, Onyango and Borghi90); overweight, BMI-for-age >+1 sd above the WHO Growth Reference median OR BMI-for-age expressed as ≥85th percentile of the CDC growth reference OR BMI-for-age equivalent to BMI ≥25 kg/m2 using International Obesity Task Force (IOTF) cut-offs by sex; obese, BMI-for-age ≥+2 sd above the WHO Growth Reference median OR BMI-for-age expressed as ≥95th percentile of the CDC growth reference OR BMI-for-age equivalent to BMI ≥30 kg/m2 using IOTF cut-offs by sex(Reference de Onis, Onyango and Borghi9092); anaemia, children <12 years (haemoglobin, Hb, <115 g/l), children 12–14 years and females 15+ years (Hb <120 g/l), males 15+ years (Hb <130 g/l); iron deficiency, serum ferritin <15 µg/l; iron-deficiency anaemia, various classifications used but involve a combination of anaemia and concurrent low ferritin level (iron deficiency + Hb <120 g/l)(93); iodine deficiency, median urinary iodine concentration (UIC) <100 µg/l(94); goitre, grade 1 – a goitre that is palpable but not visible when the neck is in the normal position (i.e. the thyroid gland is not visibly enlarged), nodules in a thyroid that is otherwise not enlarged fall into this category; grade 2 – a swelling in the neck that is clearly visible when the neck is in a normal position and is consistent with an enlarged thyroid gland when the neck is palpated(95); vitamin A deficiency, serum retinol concentrations ≤0·70 μmol/l(96); vitamin D deficiency, 25(OH)D <20 ng/ml (deficiency), 25(OH)D 21–29 ng/ml (insufficiency)(Reference Holick, Binkley and Bischoff-Ferrari97); zinc deficiency, children <10 years (serum zinc <65 ug/dl)(Reference de Benoist, Darnton-Hill and Davidsson98).

Screening of articles and selection of studies

For all of the reviews, the search results were extracted and imported into reference management software (Mendeley or EndNote X9). All duplicates were removed, and the results were screened by a single researcher, based on their title and abstract. Full texts were then screened for eligibility according to the following criteria:

Inclusion criteria

  • Guided by the PICO framework (Table 1)

  • Peer-reviewed publications, with conference abstracts (LAC; EAP; ECA) and grey literature (EAP) included in some cases

  • Only human studies

  • No restrictions on study design

  • Articles in English, Portuguese, French or Spanish

  • Articles published since 2005 (ECA, ESA, MENA), 2010 (LAC, EAP, WCA) and 2016 (SA, due to the availability of a UNICEF analysis, including literature published between 1990 and 2015(Reference Aguayo and Paintal16)

Exclusion criteria

  • Children and/or adolescents with a diagnosed disease (including COVID-19), with an addiction, or who were pregnant

  • EAP and SA reviews excluded studies with a sample size of n < 100, due to the large number of results

Data extraction

Data for the following outcomes of interest were extracted from relevant research articles for each regional literature review: stunting, wasting; thinness, overweight and/or obesity, anaemia and/or Fe deficiency, iodine deficiency and/or goitre, vitamin A deficiency, vitamin D deficiency, Zn deficiency and dietary intakes and/or patterns. Definitions and classifications of outcomes are provided with Table 1. Results are pooled by region to allow for regional comparisons. Available data describing determinants of nutrition outcomes, including differences by age, sex and setting (rural v. urban), are also discussed in narrative findings per outcome.

Since this paper aimed to provide a comprehensive overview of the available literature describing the nutritional status of adolescents and school-age children, and because the number of studies for individual countries and/or outcomes of interest varied substantially within and across regions, a formal risk of bias assessment was not carried out, in order to avoid excluding relevant studies. Due to the heterogeneity of studies and the limited results for many countries, it was not possible to conduct a meta-analysis or to apply weighting criteria to individual study results. The regional prevalence ranges provided are therefore based on the lowest and highest prevalence described across countries within the region.

Results

Availability of research articles

Figure 1 presents a flow diagram of the search results across the seven literature reviews. A total of 27 829 articles were identified for title and abstract screening. Following full text screening of 3075 articles, a total of 991 were included (a full list of all included studies by region can be found in Supplementary Appendix B).

Fig. 1 Flow diagram of search results. PICO, Population, Interventions, Control and Outcome; *Of the 991 articles included, the breakdown of articles per region was: South Asia, n 247; West and Central Africa, n 193; Europe and Central Asia, n 122; Eastern and Southern Africa, n 130; Middle East and North Africa, n 120; East Asia and Pacific, n 112; Latin America and the Caribbean, n 67

Summaries of the available evidence for countries within each region are depicted in Fig. 2(a) to (g). SA was the region represented in the largest number of studies (n 247), with most data available from India (n 144). Nigeria, in WCA, was also represented in a large number of studies (n 96), as was Turkey (n 72) in ECA region. There were large discrepancies in the availability of evidence across contexts, and even within regions. For example, WCA had a relatively large number of total studies (n 193); however, twelve of the twenty-four countries were represented in only three or fewer studies. A particularly low number of published studies were available for the LAC region (n 96), with twenty out of thirty-seven countries having no relevant published studies.

Fig. 2 Maps depicting the number of studies with data available from single-country and multi-country studies in the following regions: a, South Asia; b, West and Central Africa; c, Europe and Central Asia; d, Eastern and Southern Africa; e, Middle East and North Africa; f, East Asia and the Pacific; g, Latin America and Caribbean. (a) , 0; , 4–17; , 31–39; , 1–3; , 8–30; , 40+; (b), , 0; , 3–5; , 9–15; , 1–2; , 6–8; , 16+; (c) , 0; , 3–4; , 8–12; , 1–2; , 5–7; , 3+; (d) , 0; , 4–17; , 31–33; , 1–3; , 8–30; , 34+; (e) , 0; , 3–4; , 7–13; , 1–2; , 5–6; , 4+; (f) , 0; , 3–4; , 7–13; , 1–2; , 5–6; , 4+; (g) , 0; , 3–4; , 6–8; , 1–2; , 5–6; , 9+

Figure 3 depicts the number of studies reporting data for each nutrition outcome by global region. A summary of the number of studies reporting data for anthropometric indicators and anaemia by country and region is provided in Supplementary Appendix C. The majority of studies reported data for the prevalence of overweight and/or obesity (n 511), followed by thinness (n 293), with the highest number of studies for both indicators coming from SA (n 125 and n 108, respectively) and the lowest from LAC region (n 39 and n 11, respectively). Data describing the prevalence of stunting (n 179) and wasting (n 60) were more limited. The region with the most studies on stunting prevalence was WCA (n 55), while ECA and MENA had the fewest studies (n 8 each). Almost half (n 28) of the studies presenting data on wasting prevalence were conducted in ESA (mainly in Ethiopia, n 14), with eighteen studies being available for WCA (mainly in Nigeria, n 10). For the remaining regions, between one and five studies presented data on wasting prevalence. The majority of studies reporting data on the prevalence of anaemia and/or Fe deficiency and/or Fe deficiency anaemia (IDA) (n 162) came from SA (n 48) and the least from MENA (n 8) and ECA (n 7). Fewer studies were available for other micronutrient deficiencies: iodine deficiency and/or goitre (n 58), vitamin A deficiency (n 36), vitamin D deficiency (n 47) and Zn deficiency (n 26). The availability of evidence varied by region, with SA (n 14) and EAP (n 13) predominantly reporting data on iodine deficiency and/or goitre, ESA (n 10) and WCA (n 9) predominantly reporting data on vitamin A deficiency and MENA (n 14) predominantly reporting data on vitamin D deficiency.

Fig. 3 Total number of studies reporting data for anthropometric indicators, anaemia and micronutrient deficiencies by region. *Includes studies that also provide data for iron (Fe) deficiency and/or Fe deficiency anaemia. , West and Central Africa; , South Asia; , Eastern and Southern Africa; , Europe and Central Asia; , Middle East and North Africa; , East Asia and the Pacific; , Latin America and the Caribbean

Narrative results per nutrition outcome

Stunting

The lowest prevalence of stunting was documented in Brazil (1·7 %)(Reference da Silva Ferreira, de Assunção Bezerra and Lopes de Assunção17), in LAC region, and the highest was in the Democratic Republic of the Congo (61·0 %)(Reference Kabongo, Linsuke and Baloji18), in WCA (Fig. 4(a) and Supplementary Appendix D). Results for sex differences in stunting prevalence varied between studies; however, the prevalence was consistently higher in boys in ESA and WCA. One study in LAC demonstrated a higher risk of severe stunting in boys(Reference Dekker, Mora-Plazas and Marin19). While longitudinal data from EAP showed a decline in stunting prevalence with age (up to 15 years)(Reference Gausman, Kim and Subramanian20), cross-sectional data from EAP and SA suggested a higher prevalence of stunting at older ages(Reference Galgamuwa, Iddawela and Dharmaratne21Reference Pal, Pari and Sinha28). Across regions (LAC, ESA, WCA, SA), rural children and adolescents were more likely to be stunted than their urban counterparts. Other predictors of stunting included malaria parasitaemia, low socio-economic status (SES), parental (or father’s) unemployment status, a lower level of maternal education, attending a public v. a private school and being born to a single mother with higher parity. Lower nutrition knowledge, skipping breakfast, infrequently consuming snacks and having lower poultry consumption were also associated with higher stunting prevalence. Data from LAC and WCA showed that stunted children were more likely to be anaemic(Reference Iannotti, Delnatus and Odom29) and to have low memory and cognitive scores(Reference Sanou, Diallo and Holding30), respectively.

Fig. 4 Range in prevalence of nutrition indicators by country and region for: a, stunting; b, wasting; c, thinness; d: overweight and obesity; e, anaemia; red circles depict the lowest and blue circles the highest prevalence in the range; where only one value was available for a country only a single (blue) circle is depicted

Wasting

The lowest documented prevalence of wasting was in WCA region (0·3 % in Cameroon)(Reference Sumbele, Kimbi and Ndamukong-Nyanga31), and the highest was in Ethiopia (58·3 %), in ESA(Reference Mulugeta, Hagos and Stoecker32) (Fig. 4(b) and Supplementary Appendix D). Data from ESA showed differences in how wasting prevalence have changed over time, with repeated cross-sectional surveys conducted in Mozambique between 1992 and 2012 showing a decline from 19·0 % to 12·0 % (8–15 years of age)(Reference dos Santos, Maia and Gomes33), while national data from Zimbabwe indicated a very slight increase in wasting prevalence from 3·1 % in 2009 to 3·6 % in 2011(Reference Mushonga, Kujinga and Chagwena34). In WCA region, public (v. private) schooling, a rural (v. an urban) dwelling and low (v. high) SES were predictors of wasting in school-age children and adolescents.

Thinness

Nauru and Vanuatu, in EAP region, had the lowest documented prevalence of thinness (0·0 %)(Reference Dancause, Vilar and Chan35,Reference Caleyachetty, Thomas and Kengne36) , while the highest prevalence was documented in Nigeria (95·7 % (within country range: 5·6 %–95·7 %))(Reference Bamidele, Abodunrin and Olajide37), in WCA (Fig. 4(c) and Supplementary Appendix D). There was substantial variation in the prevalence of thinness within regions, with the lowest prevalence in WCA being 0·6 % in Cameroon(Reference Chelo, Mah and Chiabi38). Pooled analysis in SA found that, while the prevalence of thinness had declined over time, the overall burden had increased, due to growing population sizes(39). Data from WCA, MENA, ESA and EAP showed a higher prevalence of thinness in boys compared with girls. The same pooled analysis of national and sub-national surveys in SA also showed a higher prevalence of thinness in boys(39); however, other individual studies from SA showed mixed evidence for sex differences. Older age was positively associated with thinness in LAC and MENA, but negatively associated in SA. In WCA, public (v. private) schooling, a rural (v. an urban) dwelling and low (v. high) SES were predictors of thinness. Thinness was also associated with public (v. private) schooling in SA, and with lower SES in SA and ECA. Rural dwelling was positively associated with thinness in some, but not all, studies in SA. Other predictors included larger family size and living in joint families, lower levels of maternal education and father’s literacy, poor dietary diversity, poor water, sanitation and hygiene (WASH) practices and a history of illness. Food insecurity and maternal unemployment were predictors of thinness in MENA.

Overweight and obesity

The range of overweight and obesity prevalence varied widely within and between regions (Fig. 4(d) and Supplementary Appendix D). The lowest documented prevalence rates for overweight and obesity were 0·0 %, using data from Nigeria (WCA)(Reference Bamidele, Olarinmoye and Olajide40Reference Ayogu, Nnam and Ibemesi42). The highest prevalence of overweight was 73·0 % in Brazil (LAC)(Reference Cesar, Santos and Black43), and the highest obesity prevalence was 37·2 % (Nigeria in WCA and Venezuela in LAC)(Reference Sabageh, Ogunfowokan and Ojofeitimi44,Reference Valero, Prieto and García45) .

In some regions (LAC, MENA, SA), results for sex differences in overweight and obesity prevalence were mixed; however, studies in WCA and ESA showed consistently higher overweight and/or obesity prevalence rates in girls. Age-related differences in prevalence also varied, with studies in EAP and ECA suggesting higher prevalence of overweight and obesity in younger ages and those in ESA suggesting an increase with age. Private schooling (LAC, ESA, SA), urban dwelling (ECA, ESA, SA, WCA) and higher SES (ECA, ESA, SA, MENA, WCA) were consistently identified as risk factors for overweight and obesity. Dietary behaviours positively associated with overweight and obesity across regions included higher intakes of processed snacks, sugar-sweetened beverages, fast-food, total sugar and lower intakes of fruit and vegetables, as well as skipping breakfast, purchasing food at school, visiting restaurants more frequently and purchasing more food from street vendors. Lower levels of physical activity and/or more time spent being sedentary or using screens on digital devices also increased the risk of overweight and obesity, while higher levels of maternal/parental education reduced the risk. A higher maternal BMI and parental obesity, as well as higher family income and being more food secure, were positively associated with overweight and obesity in adolescents. Data from WCA showed that adolescents with overweight and obesity were more likely to have high systolic blood pressure and a distorted body image.

Micronutrient deficiencies

Anaemia and iron

There were wide ranges in anaemia prevalence documented within countries, as well as between countries and regions (Fig. 4(e) and Supplementary Appendix D). The lowest prevalence of anaemia was found in LAC region (3·9 %, in Mexico)(Reference González-Rosendo, Polo and Rodríguez-Jerez46) and the highest in EAP (98·5 %, in Indonesia)(Reference Dewi, Widardo and Suprapto47). Fewer studies reported on the prevalence of Fe deficiency and/or IDA; however, available data showed that Fe deficiency prevalence ranged from 3·7 % in Nepal (SA)(Reference Ford, Bichha and Parajuli48) to 71·3 % in Ghana (WCA)(Reference Egbi, Steiner-Asiedu and Kwesi49), with IDA prevalence ranging from 0·2 % in Malaysia (EAP)(Reference Khor, Chee and Shariff50) to 37·4 % in Ethiopia (ESA)(Reference Desalegn, Mossie and Gedefaw51). In LAC, the prevalence of anaemia (and of stunting and thinness) was consistently high in studies from Haiti and Venezuela, as well as in indigenous and underserved/rural (v. urban) populations, children and adolescents attending public (v. private) schools and for children and adolescents from low (v. high) SES households. Similar findings for associations between living in slum or rural areas and low SES and anaemia prevalence were documented in ECA, ESA and SA. Other predictors of anaemia in SA included low dietary diversity – particularly linked to irregular consumption of green leafy vegetables, milk, egg, fruits and meat – worm infestation, lack of Fe and folic acid supplementation and poor hand washing practices. There were mixed results for age- and sex-related differences in anaemia prevalence, with studies from some regions (LAC and WCA) presenting inconsistent results. For studies from other regions, some showed higher anaemia prevalence in girls (SA) and at older ages (SA, MENA), while others indicated higher prevalence in boys (ECA) or at younger ages (EAP).

Iodine and goitre

Across regions, data suggested low prevalence of iodine deficiency and/or goitre overall, due to implementation of effective salt iodisation programmes (Table 2). For example, nationally representative longitudinal data from Sri Lanka showed a reduction in the prevalence of iodine deficiency (2·7 % to 1·6 %) and goitre (18·0 % to 1·9 %) between 2000 and 2016(Reference Jayatissa, Gorstein and Okosieme52). However, there was variation within and between regions, with both the lowest (0·0 % in Indonesia)(Reference Kartini, Suhartono and Pangestuti53) and the highest (88·1 % in Papua New Guinea)(Reference Goris, Temple and Zomerdijk54) prevalence of iodine deficiency documented in EAP region. Data from studies in ECA, SA and WCA suggested a greater likelihood of iodine deficiency in girls and at older ages.

Table 2 Summary of available studies describing prevalence of micronutrient deficiencies in school-age children and adolescents, by region

* Study conducted in women of reproductive age (15–49 years).

Iodine deficiency, median urinary iodine concentration (UIC) <100 µg/l(94); goitre, grade 1 – a goitre that is palpable but not visible when the neck is in the normal position (i.e. the thyroid gland is not visibly enlarged), nodules in a thyroid that is otherwise not enlarged fall into this category; grade 2 – a swelling in the neck that is clearly visible when the neck is in a normal position and is consistent with an enlarged thyroid gland when the neck is palpated(95); vitamin A deficiency, serum retinol concentrations ≤0·70 μmol/l(96); vitamin D deficiency, 25(OH)D < 20 ng/ml (deficiency), 25(OH)D 21–29 ng/ml (insufficiency)(Reference Holick, Binkley and Bischoff-Ferrari97); Zn deficiency, children <10 years (serum Zn <65 μg/dl)(Reference de Benoist, Darnton-Hill and Davidsson98); N indicates number of available articles presenting data on micronutrient deficiencies from single-country studies and from single-country studies including girls only; prevalence range per region based on the lowest and highest prevalence described across countries within the region.

Vitamin A

Overall, the prevalence of vitamin A deficiency ranged from 0·0 % in Nigeria (WCA)(Reference Udo, Bassey and Akpan55) and Turkey (ECA)(Reference Vuralli, Tumer and Hasanoglu56) to 74·0 % in (SA)(Reference Rahman, Rahman and Alam57) (Table 2). There were also wide ranges in the prevalence of vitamin A deficiency documented within countries where more than one study was available (e.g. between 0·0 % and 51·5 % prevalence in Nigeria)(Reference Ayogu, Afiaenyi and Madukwe41,Reference Udo, Bassey and Akpan55) . Few studies disaggregated data by sex and age; however, one study in EAP (Philippines) showed a higher prevalence of vitamin A deficiency in children 6–12 years of age (10·7 %) compared with those 13–19 years of age (4·0 %)(58).

Vitamin D

The prevalence of vitamin D deficiency ranged from 5 % in Guatemala (LAC)(Reference Naqvi, Solomons and Campos59) to 100 % in Mongolia (EAP)(Reference Ganmaa, Stuart and Sumberzul60) and Saudi Arabia (MENA)(Reference Al-Musharaf, Al-Othman and Al-Daghri61) (Table 2). In EAP and ESA, the prevalence of vitamin D deficiency was higher for urban adolescents than for their rural counterparts. Sex differences were also evident, with lower prevalence rates shown in boys from ECA, MENA and SA – potentially due to higher levels of sun exposure. There was also evidence of seasonal differences in vitamin D deficiency, with comparatively higher risk of deficiency at the end of winter in ECA and in summer in MENA (less time spent outdoors due to high temperatures). Other predictors of vitamin D deficiency in SA included low sun exposure, low Ca intake, use of sun protection and darker skin.

Zinc

Both the highest and lowest prevalence of Zn deficiency was documented in ESA; 3 % in Kenya(Reference Talsma, Borgonjen-Van Den Berg and Melse-Boonstra62) and 75·6 % in South Africa(Reference Van Der Hoeven, Faber and Osei63) (Table 2). Overall, studies from ESA showed a positive association between prevalence of Zn deficiency and being male, food insecurity and poverty, while data from Turkey (ECA) showed no differences in prevalence according to sex or SES.

Dietary intakes and patterns

A total of 241 articles presented data on dietary intakes and patterns. The number of available studies ranged from fifty-four in WCA to eighteen in ESA. Methods for describing diets of school-age children and adolescents varied between studies; however, some commonly used indicators included assessment of food insecurity, nutrition knowledge, dietary intakes and patterns, dietary diversity, breakfast consumption and junk/fast-food consumption. Data collection for these indicators was questionnaire-based and included dietary assessment via FFQ (quantitative, semi-quantitative or non-quantitative) or 24-h-recall questionnaires (either on single or multiple days), as well as various other questionnaire tools. A summary of the commonly assessed dietary indicators and the main findings per region are provided in Table 3.

Table 3 Summary of commonly reported dietary indicators and main findings per region

Overall, the findings showed that school-age children and adolescents commonly skipped breakfast, with some studies suggesting that this was more likely in girls and in those from rural areas, as well as those experiencing greater household poverty. Food insecurity and a lack of affordability of, and access to, food (healthy diets in particular) was a strong driver of poor dietary diversity and unhealthy food choices. In contrast, some studies showed a reduction in dietary diversity for higher wealth categories that was often coupled with higher junk/fast-food consumption. There was evidence of transitioning dietary patterns across regions, with diets varying between more traditional patterns (e.g. high intakes of cereals and grains, vegetables, nuts, seeds and legumes, coconut, local beverages and meat) and patterns increasingly high in processed foods, fats and oils, snacks, SSB and sweets. This was echoed in the food practices reported in all regions, where snacking, eating in restaurants and consuming high quantities of junk/fast-foods were increasingly common, and where intakes of micronutrient-rich fruits and vegetables were low. Where data on nutrition knowledge were available, this was found to be poor in MENA and ECA (between 7 % and 14 % demonstrating moderate or good levels of knowledge), but higher in SA and WCA. In Nepal (SA) specifically, knowledge around obesity was attributed to the inclusion of nutrition education in the school curriculum. However, even in cases where adolescents reported having good knowledge on what constituted unhealthy foods, these items were commonly consumed. Besides affordability and access, dietary behaviours were influenced by a range of factors, including food advertising, children and adolescents’ level of autonomy around food choices, seasonality and the views or practices of family members, peers and school administrators.

Interventions

A summary of the intervention studies, identified according to intervention type and primary outcome, is provided in Table 4. Intervention studies targeting malnutrition in school-age children and adolescents were limited in all regions (n 103), with the most studies available in LAC (n 30). Little evidence was available from regions in Africa, especially in ESA (n 7) and from African countries in MENA (n 1). In regions where intervention studies were available, few countries were represented. For example, in LAC, two-thirds of the interventions took place in Mexico and Brazil (n 10 each).

Table 4 Summary of intervention studies across world regions, according to intervention type and primary outcome

The primary outcomes of interventions were anaemia and/or micronutrient deficiencies (n 42, 41 % of intervention studies); overweight and obesity (n 33, 32 %); undernutrition (stunting, wasting or thinness) (n 18, 17 %) and improved nutrition knowledge or dietary practices (n 10, 10 %). Most interventions included boys and girls, with a total of 10 (10 %) including girls only. A total of twenty-two intervention studies targeted school-age children (5–9 years), forty-three targeted adolescents (10–19 years) and the remaining thirty-eight included participants across these age groups. The majority of interventions were implemented in schools (n 98, 95 %), with three being implemented at community or provincial level, one in a clinical setting and one in a university setting.

Interventions targeting micronutrient deficiencies (n 42) focused primarily on reducing the prevalence of anaemia and/or Fe deficiency via supplementation and fortified food (e.g. biscuits or meals) and beverages (e.g. milk or water) (n 20). The remaining micronutrient interventions either incorporated other micronutrients (iodine, vitamin A or multiple micronutrients; MMN) within anaemia reduction programmes (n 8) or targeted other single-micronutrient deficiencies, including vitamin D (n 7), iodine (n 1), Zn (n 3) and Ca (n 2). The duration of interventions ranged from one to 12 months. Overall, benefits of supplementation and fortification were seen in improved Fe and vitamin D status, as well as Hb levels, reduced anaemia prevalence and reduced prevalence of vitamin A, Zn and iodine deficiencies in some cases. There was evidence of greater improvement in these outcomes from using fortification as compared with using supplementation and from using MMN approaches as compared with single micronutrients (particularly Fe) or iron and folic acid. Supplementation with vitamin D facilitated greater improvement in vitamin D status than either sunlight exposure or oily fish consumption, and while both iodised oil capsules and iodised water increased urinary iodine concentration (UIC), there was a greater risk of excess in those receiving capsules. One study in the Gambia showed that, while Ca supplementation facilitated greater linear growth and higher stature at 15 years of age for boys, it also resulted in earlier cessation of growth and shorter stature in adulthood (23 years)(Reference Prentice, Dibba and Sawo64).

The majority of interventions addressing undernutrition (n 18) took place in SA (n 5) and WCA (n 4); the duration of interventions ranged from one to 27 months. The majority of interventions addressing overweight and obesity (n 33) took place in LAC (n 19) and EAP (n 6) and ranged from 2·5 to 36 months in duration. The provision of food or beverages, particularly fortified with MMN, was associated with reductions in stunting and/or thinness. In cases where fortified foods did not effectively reduce stunting prevalence, beneficial effects on micronutrient status and anaemia prevalence were shown. In one study from Kenya, while food provided at school had no overall effect on height, gains in weight, lean muscle mass and cognitive function were observed, particularly when the meal included meat, rather than milk or oil(Reference Neumann, Murphy and Gewa65). Providing nutrition education and ‘healthy’ snacks (including sandwiches and fruit) in schools reduced thinness and increased daily intakes of energy, fibre, protein and micronutrients; however, saturated fat intake also increased. Other multi-component programmes, including a combination of school gardens, nutrition, WASH and health education, supplementation, deworming and healthcare referral, showed mixed effects on thinness and/or stunting; however, those that were ineffective in reducing stunting and thinness prevalence did show positive effects on nutrition knowledge and health behaviours (e.g. increased consumption of fruit and vegetables).

Interventions targeting overweight and obesity comprised a range of social and behaviour change communication (SBCC) approaches. These included educational leaflets, in-person education and counselling, group learning and workshops, as well as interactive approaches (e.g. cooking classes, exercise programmes and game-based methods). Multi-component programmes that included a combination of nutrition education, diet and physical activity programmes, as well as targeting the food environment, the built environment and the building of life skills seemed most effective in improving access to healthy food in school or home environments, as well as improving behaviours related to diets and physical activity. Few interventions had any effect, or a large effect, on the overall prevalence of overweight and obesity; however, some studies documented beneficial effects on weight, body composition (waist circumference and skinfolds) and metabolic markers (e.g. glycaemic control). Programmes that were more successful in facilitating behaviour change and/or anthropometric changes often involved other stakeholders (e.g. parents and teachers) in the intervention programme. There was limited evidence of using novel approaches (e.g. social media platforms and game-based approaches) to engage children and adolescents. However, in Nigeria, two studies that incorporated game-enhanced approaches (board games, clubs and vouchers) to nutrition and health education showed positive effects on participants’ knowledge and perceptions of healthy eating, promoted the consumption of more nutritious foods (e.g. fruits and vegetables) and facilitated more engagement in physical activity(Reference Ogunsile and Ogundele66,Reference Ezezika, Oh and Edeagu67) .

Discussion

This review summarises evidence on the burden of malnutrition in school-age children and adolescents in LMIC from seven global regions, as well as on interventions implemented to improve nutritional status. While a total of 990 studies were identified, large geographical data gaps were found to exist, due to the fact that the bulk of evidence concentrated on a small number of countries. Studies presenting prevalence data focused on certain anthropometric and nutrition indicators, particularly overweight and obesity, thinness and anaemia, with a dearth of evidence available on the prevalence of other micronutrient deficiencies. With the exception of the LAC and EAP regions, there was limited evidence available on interventions targeting the rising burden of overweight and obesity. The majority of interventions targeted micronutrient deficiencies (mainly anaemia and/or Fe deficiency). Thus, there was little acknowledgement across regions of the broader spectrum of nutrition challenges affecting adolescents, the similar and interrelated causes of undernutrition, overweight and obesity and micronutrient deficiencies and the benefits of double-duty actions to address these. In contrast, substantial evidence exists from high-income countries, including detailed data on food intake, the role of food environments and commercial marketing and advertising (traditional and social media) in driving food choices and interventions targeting the rising burden of overweight and obesity(Reference Neufeld, Andrade and Ballonoff Suleiman68,Reference Jacob, Hardy-Johnson and Inskip69) , and programmes such as school feeding are widely available(Reference Wang and Fawzi70), despite the fact that the majority of the world’s children and adolescents (5–19 years) live in LMIC(Reference Galloway, Bundy, de Silva and Horton71).

Despite limitations in data availability, evidence was found of an emerging double burden of malnutrition across world regions, with stunting and thinness remaining especially high in the WCA, ESA and SA regions. Overweight and obesity affected all world regions, especially countries in LAC, EAP and MENA, where prevalence rates were consistently high across countries. All regions were affected by anaemia, although there was variability between countries. Where data were available, most regions experienced high rates of iodine, vitamin A, vitamin D and Zn deficiencies. Dietary transitions associated with rapid urbanisation were evident across all regions, with diets high in energy-dense, processed and micronutrient-poor foods increasingly being consumed.

A large degree of methodological variability was observed across the studies included in this review, limiting our ability to compare findings within and between regions. In particular, inconsistencies in the use of reference populations (WHO, International Obesity Task Force, US Centers for Disease Control and context-specific references in some cases) and thresholds used to classify thinness, overweight and obesity limited the comparability between studies and may account for some of the variability described. Similarly, the lack of a universal method to assess diet diversity and/or quality in school-age children and adolescents meant that a range of methods and indicators were used. Studies lacked consistency in the age ranges examined, with subjects from various subgroups within the 5–19-year age range being included. There was also inadequate availability of sex-disaggregated data, as well as data for other subgroups, such as those out of school, those living in rural (v. urban) settings, those with disabilities and those in vulnerable contexts, such as refugee populations. There is a need for consensus on the methodology to be used in assessing the nutritional status of school-age children and adolescents, to allow for comparable assessments of the burden of malnutrition across global regions, as well as to set international and national targets and to monitor progress against agreed targets(Reference Ali, Lelijveld and Wrottesley72).

A range of risk factors for nutrition outcomes were identified across studies. Our findings suggest that undernutrition (stunting, wasting and thinness) is more prevalent in boys, and overweight and obesity are more prevalent in girls, particularly as children age and transition through puberty and beyond. As supported by previous research, this may in part be because girls are less likely to be physically active and more likely to engage in sedentary behaviours (e.g. watching television)(Reference Darling, Sunguya and Ismail73Reference Muthuri, Wachira and Leblanc75), as well as being more likely to skip breakfast and to consume foods high in fat and sugar. An absence of sex-related trends in food security and dietary patterns have also been demonstrated(Reference Darling, Sunguya and Ismail73).

There was consistent evidence that urban dwelling, being from a higher socioeconomic background, being more food secure and consuming breakfast and healthy snacks decreased the risk of undernutrition. Conversely, in more obesogenic environments, these same factors were associated with higher consumption of processed and junk/fast-food items, a greater likelihood of eating outside the home and a higher risk of overweight and obesity. In both cases, micronutrient deficiencies persisted. This highlights the increasingly ubiquitous nature of malnutrition in LMIC, and that, despite variations in nutritional outcomes between contexts, interventions that improve access to, and consumption of, healthy, diverse diets should be prioritised as double-duty actions to improve outcomes across the malnutrition spectrum. However, better insight into what drives poor diet and activity behaviours in children and adolescents, and how best to target boys and girls as they age, across diverse contexts, is critical in order to ensure that the barriers that exist to making healthy dietary choices are addressed. This will require a food systems approach to make nutritious, safe, affordable and sustainable diets available, appealing and aspirational, while contributing to long-term environmental sustainability and planetary health(Reference Hawkes, Fox and Downs76,Reference Hollis, Collins and DeClerck77) .

Regarding intervention studies, it was found that the majority targeted anaemia through fortification or supplementation programmes, while those aimed at prevention or management of undernutrition, or overweight and obesity, were more limited. There were few studies in general, and there was little comparability between studies on intervention targets and the baseline nutritional status of subjects, as well as the type, dose and duration of the interventions implemented. This made it challenging to draw conclusions regarding effective intervention approaches for school-age children and adolescents.

However, our synthesis of evidence suggests that MMN-fortified foods or beverages may be effective in reducing micronutrient deficiencies, alongside weight gain, in undernourished populations. Supplementation and non-fortified food-based approaches were less successful, as was sunlight exposure in the case of vitamin D. Previous evidence from systematic reviews assessing the effects of fortified foods and beverages in adults, adolescents and children across high-, middle- and low-income countries have demonstrated varied results on anaemia and Fe status, with inconclusive effects on growth, morbidity and cognitive outcomes(Reference Das, Salam and Kumar78Reference Gera, Sachdev and Boy80). However, these reviews also highlighted similar issues around the comparability of findings. Other evidence has highlighted the benefits of MMN fortification and supplementation as compared with single-micronutrient approaches(Reference Mithra, Khatib and Sinha81). The recent Lancet Series on Maternal and Child Undernutrition Progress highlighted the strong evidence supporting MMN supplementation during the antenatal period for improved birth outcomes and suggested the potential benefit of extending this into the preconception period for adolescent girls and young women in high-burden contexts(Reference Baxter, Wasan and Soofi82Reference Keats, Das and Salam84). Current WHO guidelines recommend daily Fe-only or weekly Fe and folic acid supplementation in menstruating, non-pregnant women and adolescents, depending on the anaemia burden(Reference Baxter, Wasan and Soofi82,Reference Baxter, Wasan and Hussain83,85) . However, evidence is lacking on implementation strategies to examine the acceptability and effectiveness of supplementation dose, delivery and duration, either for these guidelines or for MMN approaches(Reference Canavan and Fawzi8). Additionally, evidence is scarce regarding the benefits for nutritional status, development and morbidity in school-age children and adolescents in the short and longer term(Reference Bhutta, Lassi and Bergeron86,Reference Salam, Das and Ahmed87) , and further exploration is needed of the effectiveness of MMN programmes within a package of nutrition-specific and nutrition-sensitive interventions, for girls and boys and across contexts.

Interventions targeting overweight and obesity via education and SBCC strategies showed beneficial effects on nutrition knowledge; however, evidence on the impacts on behaviour change and growth outcomes was inconclusive. Most interventions assessed anthropometric outcomes over a short-term follow-up period (up to a year maximum), with only three studies (in LAC) following up between 18 months and 3 years. There is a need for multi-component programmes that start early and extend through the childhood and adolescent years, which consider the wider food environment, and which involve other stakeholders (peers, family andteachers), in order to facilitate behaviour change, improve dietary diversity and quality and improve nutritional status. Such strategies should provide effective double-duty approaches to promoting healthy growth and body size, as well as tackling micronutrient deficiencies across contexts, and should be proactive in those regions where undernutrition remains the priority and where overweight is rising. The use of novel technological approaches to engaging adolescents, as well as approaches designed by adolescents themselves, both of which were largely absent in our findings, are also critical in order to ensure that interventions appeal to adolescent needs and interests. Interventions that extend beyond schools (e.g. using health platforms and social/community-based platforms) are also needed to address the needs of the approximately one-in-five children and adolescents globally who do not attend school(88).

Limitations

This review has provided a comprehensive summary of available literature from seven global regions; however, methodological differences between the literature reviews feeding into this synthesis may have limited comparability. For example, three reviews included articles published since 2005 (ECA, ESA, MENA), three included articles published since 2010 (LAC, EAP, WCA) and one included articles published since 2016 (SA). Additionally, the EAP and SA reviews excluded studies with sample sizes of n < 100 and the EAP review also included data from grey literature. Despite differences in search criteria, the large number of search results in SA were comparable to those published in the UNICEF review(Reference Aguayo and Paintal16), specifically showing persistent burdens of stunting and thinness, alongside emerging burdens of overweight and obesity, which were higher in more affluent, well-educated and urban households. In reviews that did not screen according to sample size, only between 1·5 % and 9·0 % of studies had n < 100 subjects, and in the EAP review grey literature corroborated the results from peer-reviewed publications. Thus, these differences were unlikely to substantially influence the overall findings per region. Similarly, due to the wide research and streamlining of methods, for example the databases searched, across literature reviews, it is feasible that some manuscripts from particular regions were overlooked; e.g. regional databases such as SciELO were not searched and may have provided additional studies for the LAC region. Future research that involves more targeted searches by researchers living in LMIC may be beneficial in filling some context-specific gaps in the data identified in this literature review synthesis.

As described above, differences in methodology between individual studies also limited comparability within and between countries and regions. This restricted our ability to draw conclusions on the burden of malnutrition and on effective interventions. It is also an important finding in and of itself: highlighting key research gaps, as well as a need for global consensus on the indicators used to describe nutritional status and to assess dietary quality in school age children and adolescents. In addition, previous findings have demonstrated a high degree of comparability between standards of weight classification (i.e. US Centers for Disease Control, International Obesity Task Force and WHO growth standards) in adolescents and in their associations with health outcomes(Reference Li, Haynie and Palla89). This suggests that the potential for misclassification of anthropometric outcomes between studies is likely to be small overall.

Conclusion

Globally, persistent food insecurity, poor growth and micronutrient deficiencies continue to plague school-age children and adolescents, as the new challenge of obesity emerges. Despite this, the persistent absence of these age groups across research, policy and programming means that the limited information available is neither standardised nor comparable. Consensus is urgently needed on methods for assessing nutritional status and its determinants (e.g. dietary intake and quality), in order to set targets and monitor progress. In addition, an understanding of double-duty interventions is needed, to ensure that healthy diets are available, affordable and appealing for all adolescents, alongside efforts to promote healthy behaviours that support optimal growth and development for current and future generations.

Acknowledgements

Financial support: UNICEF Headquarters New York, USA, and Ireland’s Department for Foreign Affairs. Authorship: E.M., E.B., V.B., R.M., S.R., Z.A., A.Y. and N.L. conducted the seven regional literature reviews. E.M., N.L. and S.V.W. conceptualised the paper. S.V.W. was responsible for the synthesis of all literature reviews and summarised the overall findings. All authors contributed to the interpretation of the results. S.V.W. wrote the original draft. All authors contributed to a critical review of the manuscript, approved the final version to be submitted and agreed to be accountable for all aspects of the work. D.S. and A.Y. are staff members of UNICEF. The views expressed in this publication do not necessarily represent the views, decisions or policies of the organisation. Ethics of human subject participation: Not applicable

Conflict of interest:

There are no conflicts of interest.

Supplementary material

For supplementary material accompanying this paper visit https://doi.org/10.1017/S1368980022000350

References

United Nations (2015) Transforming Our World: The 2030 Agenda for Sustainable Development. New York, NY: United Nations.Google Scholar
Prentice, AM, Ward, KA, Goldberg, GR et al. (2013) Critical windows for nutritional interventions against stunting. Am J Clin Nutr 97, 911918.CrossRefGoogle ScholarPubMed
Dorn, LD, Hostinar, CE, Susman, EJ et al. (2019) Conceptualizing puberty as a window of opportunity for impacting health and well-being across the life span. J Res Adolesc 29, 155176.CrossRefGoogle ScholarPubMed
Das, JK, Lassi, ZS, Hoodbhoy, Z et al. (2018) Nutrition for the next generation: older children and adolescents. Ann Nutr Metab 72, Suppl. 3, 5664.CrossRefGoogle ScholarPubMed
Patton, GC, Olsson, CA, Skirbekk, V et al. (2018) Adolescence and the next generation. Nature 554, 458466.CrossRefGoogle ScholarPubMed
Patton, GC, Sawyer, SM, Santelli, JS et al. (2016) Our future: a Lancet commission on adolescent health and wellbeing. Lancet 387, 24232478.CrossRefGoogle ScholarPubMed
Christian, P & Smith, ER (2018) Adolescent undernutrition: global burden, physiology, and nutritional risks. Ann Nutr Metab 72, 316328.CrossRefGoogle ScholarPubMed
Canavan, CR & Fawzi, WW (2019) Addressing knowledge gaps in adolescent nutrition: toward advancing public health and sustainable development. Curr Dev Nutr 3, nzz062.CrossRefGoogle ScholarPubMed
Viner, RM, Ozer, EM, Denny, S et al. (2012) Adolescence and the social determinants of health. Lancet 379, 16411652.CrossRefGoogle ScholarPubMed
Frech, A (2012) Healthy behavior trajectories between adolescence and young adulthood. Adv Life Course Res 17, 5968.Google ScholarPubMed
Popkin, BM, Corvalan, C & Grummer-Strawn, LM (2020) Dynamics of the double burden of malnutrition and the changing nutrition reality. Lancet 395, 6574.CrossRefGoogle ScholarPubMed
Ronto, R, Wu, JH & Singh, GM (2018) The global nutrition transition: trends, disease burdens and policy interventions. Public Health Nutr 21, 22672270.CrossRefGoogle ScholarPubMed
Farrell, P, Thow, AM, Abimbola, S et al. (2018) How food insecurity could lead to obesity in LMICs: when not enough is too much: a realist review of how food insecurity could lead to obesity in low- and middle-income countries. Health Promot Int 33, 812826.CrossRefGoogle ScholarPubMed
Flodgren, GM, Helleve, A, Lobstein, T et al. (2020) Primary prevention of overweight and obesity in adolescents: an overview of systematic reviews. Obes Rev 21, e13102.CrossRefGoogle ScholarPubMed
Salam, RA, Padhani, ZA, Das, JK et al. (2020) Effects of lifestyle modification interventions to prevent and manage child and adolescent obesity: a systematic review and meta-analysis. Nutrients 12, 2208.CrossRefGoogle ScholarPubMed
Aguayo, VM & Paintal, K (2017) Nutrition in adolescent girls in South Asia. BMJ 357, j1309.CrossRefGoogle ScholarPubMed
da Silva Ferreira, H, de Assunção Bezerra, MK, Lopes de Assunção, M et al. (2016) Prevalence of and factors associated with anemia in school children from Maceió, northeastern Brazil. BMC Public Health 16, 380.CrossRefGoogle ScholarPubMed
Kabongo, MM, Linsuke, S, Baloji, S et al. (2018) Schistosoma Manson infection and its association with nutrition and health outcomes: a household survey in school-aged children living in Kasansa, Democratic Republic of the Congo. Pan Afr Med J 31, 197.CrossRefGoogle Scholar
Dekker, LH, Mora-Plazas, M, Marin, C et al. (2010) Stunting associated with poor socioeconomic and maternal nutrition status and respiratory morbidity in Colombian schoolchildren. Food Nutr Bull 31, 242250.CrossRefGoogle ScholarPubMed
Gausman, J, Kim, R & Subramanian, SV (2019) Stunting trajectories from post-infancy to adolescence in Ethiopia, India, Peru, and Vietnam. Matern Child Nutr 15, e12835.CrossRefGoogle ScholarPubMed
Galgamuwa, LS, Iddawela, D, Dharmaratne, SD et al. (2017) Nutritional status and correlated socio-economic factors among preschool and school children in plantation communities, Sri Lanka. BMC Public Health 17, 377.CrossRefGoogle ScholarPubMed
Darling, AM, Fawzi, WW, Barik, A et al. (2020) Double burden of malnutrition among adolescents in rural West Bengal, India. Nutrition 79–80, 110809.CrossRefGoogle ScholarPubMed
Naotunna, NP, Dayarathna, M, Maheshi, H et al. (2017) Nutritional status among primary school children in rural Sri Lanka; a public health challenge for a country with high child health standards. BMC Public Health 17, 57.CrossRefGoogle ScholarPubMed
Roy, S, Barman, S, Mondal, N et al. (2016) Prevalence of stunting and thinness among adolescent girls belonging to the Rajbanshi population of West Bengal, India. J Nepal Paediatr Soc 36, 147155.CrossRefGoogle Scholar
van Tuijl, CJW, Madjdian, DS, Bras, H et al. (2021) Sociocultural and economic determinants of stunting and thinness among adolescent boys and girls in Nepal. J Biosoc Sci 53(4), 531556.CrossRefGoogle ScholarPubMed
Chattopadhyay, A, Sethi, V, Nagargoje, VP et al. (2019) WASH practices and its association with nutritional status of adolescent girls in poverty pockets of eastern India. BMC Womens Health 19, 89.CrossRefGoogle ScholarPubMed
Zainab, S & Kadir, M (2016) Nutritional status and physical abuse among the children involved in domestic labour in Karachi Pakistan: a cross-sectional survey. J Pak Med Assoc 66, 12431248.Google ScholarPubMed
Pal, A, Pari, AK, Sinha, A et al. (2017) Prevalence of undernutrition and associated factors: a cross-sectional study among rural adolescents in West Bengal, India. Int J Pediatr Adolesc Med 4, 918.CrossRefGoogle ScholarPubMed
Iannotti, LL, Delnatus, JR, Odom, AR et al. (2015) Determinants of anemia and hemoglobin concentration in Haitian school-aged children. Am J Trop Med Hyg 93, 10921098.CrossRefGoogle ScholarPubMed
Sanou, AS, Diallo, AH, Holding, P et al. (2018) Association between stunting and neuro-psychological outcomes among children in Burkina Faso, West Africa. Child Adolesc Psychiatry Ment Health 12, 30.CrossRefGoogle ScholarPubMed
Sumbele, IU, Kimbi, HK, Ndamukong-Nyanga, JL et al. (2015) Malarial anaemia and anaemia severity in apparently healthy primary school children in urban and rural settings in the Mount Cameroon area: cross sectional survey. PLoS One 10, e0123549.CrossRefGoogle Scholar
Mulugeta, A, Hagos, F, Stoecker, B et al. (2009) Nutritional status of adolescent girls from rural communities of Tigray, northern Ethiopia. Ethiop J Health Dev 23, 511.CrossRefGoogle Scholar
dos Santos, FK, Maia, JAR, Gomes, TNQF et al. (2014) Secular trends in growth and nutritional status of Mozambican school-aged children and adolescents. PLOS One 9, e114068.CrossRefGoogle ScholarPubMed
Mushonga, NGT, Kujinga, P, Chagwena, DT et al. (2014) A restrospective study of the nutritional status of primary school children in Harare. Afr J Food Agric Nutr Dev 14, 569577.Google Scholar
Dancause, KN, Vilar, M, Chan, C et al. (2012) Patterns of childhood and adolescent overweight and obesity during health transition in Vanuatu. Public Health Nutr 15, 158166.CrossRefGoogle ScholarPubMed
Caleyachetty, R, Thomas, GN, Kengne, AP et al. (2018) The double burden of malnutrition among adolescents: analysis of data from the global school-based student health and health behavior in school-aged children surveys in 57 low- and middle-income countries. Am J Clin Nutr 108, 414424.CrossRefGoogle ScholarPubMed
Bamidele, JO, Abodunrin, OL, Olajide, FO et al. (2010) Prevalence and determinants of anemia among primary school pupils of a peri-urban community in Osun State, Nigeria. Int J Adolesc Med Health 22, 461468.CrossRefGoogle ScholarPubMed
Chelo, D, Mah, EM, Chiabi, EN et al. (2019) Prevalence and factors associated with hypertension in primary school children, in the centre region of Cameroon. Transl Pediatr 8, 391397.CrossRefGoogle ScholarPubMed
NCD Risk Factor Collaboration (2017) Worldwide trends in body-mass index, underweight, overweight, and obesity from 1975 to 2016: a pooled analysis of 2416 population-based measurement studies in 128.9 million children, adolescents, and adults. Lancet 390, 26272642.CrossRefGoogle Scholar
Bamidele, JO, Olarinmoye, EOA, Olajide, FO et al. (2011) Prevalence and socio-demographic determinants of under-weight and pre-obesity among in-school adolescents in Olorunda local government area, Osun State, Nigeria. TAF Prev Med Bull 10, 397402.CrossRefGoogle Scholar
Ayogu, RNB, Afiaenyi, IC, Madukwe, EU et al. (2018) Prevalence and predictors of under-nutrition among school children in a rural South-eastern Nigerian community: a cross sectional study. BMC Public Health 18, 587.CrossRefGoogle Scholar
Ayogu, RN, Nnam, NM, Ibemesi, O et al. (2016) Prevalence and factors associated with anthropometric failure, vitamin A and iron deficiency among adolescents in a Nigerian urban community. Afr Health Sci 16, 389398.CrossRefGoogle Scholar
Cesar, JA, Santos, IS, Black, RE et al. (2020) Iodine status of Brazilian school-age children: a national cross-sectional survey. Nutrients 12, 1077.CrossRefGoogle Scholar
Sabageh, AO, Ogunfowokan, AA & Ojofeitimi, EO (2013) Obesity and body image discrepancy among school adolescents in Ile-Ife, Osun State, Nigeria. Pak J Nutr 12, 377381.CrossRefGoogle Scholar
Valero, P, Prieto, C, García, D et al. Consumption of snacks and its relationship with lipid profile in school children and adolescents of the municipality of Maracaibo, Estado Zulia. Rev Latinoam Hipertens 13, 194201.Google Scholar
González-Rosendo, G, Polo, J, Rodríguez-Jerez, JJ et al. (2010) Bioavailability of a heme-iron concentrate product added to chocolate biscuit filling in adolescent girls living in a rural area of Mexico. J Food Sci 75, H73H78.CrossRefGoogle Scholar
Dewi, YLR, Widardo, & Suprapto, B (2013) Iron and iodine supplementation in school children in Ngargoyoso sub-district, Karanganyar regency, Central Java, Indonesia. J Biol Agric Healthc 3, 8892.Google Scholar
Ford, ND, Bichha, RP, Parajuli, KR et al. (2020) Factors associated with anaemia among adolescent boys and girls 10–19 years old in Nepal. Matern Child Nutr 18, e13013.CrossRefGoogle ScholarPubMed
Egbi, G, Steiner-Asiedu, M, Kwesi, FS et al. (2014) Anaemia among school children older than 5 years in the Volta Region of Ghana. Pan Afr Med J 17, Suppl. 1, 10.CrossRefGoogle ScholarPubMed
Khor, GL, Chee, WSS, Shariff, ZM et al. (2011) High prevalence of vitamin D insufficiency and its association with BMI-for-age among primary school children in Kuala Lumpur, Malaysia. BMC Public Health 11, 95.CrossRefGoogle ScholarPubMed
Desalegn, A, Mossie, A & Gedefaw, L (2014) Nutritional iron deficiency anemia: magnitude and its predictors among school age children, southwest Ethiopia: a community based cross-sectional study. PLoS One 9, e114059.CrossRefGoogle Scholar
Jayatissa, R, Gorstein, J, Okosieme, OE et al. (2020) Stable iodine nutrition during two decades of continuous universal salt iodisation in Sri Lanka. Nutrients 12, 1109.CrossRefGoogle ScholarPubMed
Kartini, A, Suhartono, , Pangestuti, DR et al. (2018) Goiter and hypothyroidism among elementary school children in lowland agricultural area, Brebes district Indonesia. Indian J Public Health Res Dev 9, 120125.CrossRefGoogle Scholar
Goris, JM, Temple, VJ, Zomerdijk, N et al. (2018) Iodine status of children and knowledge, attitude, practice of iodised salt use in a remote community in Kerema district, Gulf province, Papua New Guinea. PLoS One 13, e0197647.CrossRefGoogle Scholar
Udo, N, Bassey, IE, Akpan, UO et al. (2020) Differences in micronutrient levels between urban and rural children in Cross River State, Nigeria. N Z J Med Lab Sci 74, 129134.Google Scholar
Vuralli, D, Tumer, L, Hasanoglu, A et al. (2014) Vitamin A status and factors associated in healthy school-age children. Clin Nutr 33, 509512.CrossRefGoogle ScholarPubMed
Rahman, S, Rahman, AS, Alam, N et al. (2017) Vitamin A deficiency and determinants of vitamin A status in Bangladeshi children and women: findings of a national survey. Public Health Nutr 20, 11141125.CrossRefGoogle ScholarPubMed
FNRI-DOST (2015) Philippine 8th National Nutrition Survey: Biochemical Survey. Republic of the Philippines: Food and Nutrition Research Institute-Department of Science and Technology.Google Scholar
Naqvi, A, Solomons, NW, Campos, R et al. (2017) Vitamin D status among indigenous Mayan (Kekchi) and Afro-Caribe (Garifuna) adolescents from Guatemala: a comparative description between two ethnic groups residing on the Rio Dulce at the Caribbean coast in Izabal Province, Guatemala. Public Health Nutr 20, 17291737.CrossRefGoogle ScholarPubMed
Ganmaa, D, Stuart, JJ, Sumberzul, N et al. (2017) Vitamin D supplementation and growth in urban Mongol school children: results from two randomized clinical trials. PLoS One 12, e0175237.CrossRefGoogle ScholarPubMed
Al-Musharaf, S, Al-Othman, A, Al-Daghri, NM et al. (2012) Vitamin D deficiency and calcium intake in reference to increased body mass index in children and adolescents. Eur J Pediatr 171, 10811086.CrossRefGoogle ScholarPubMed
Talsma, EF, Borgonjen-Van Den Berg, KJ, Melse-Boonstra, A et al. (2018) The potential contribution of yellow cassava to dietary nutrient adequacy of primary-school children in Eastern Kenya; the use of linear programming. Public Health Nutr 21, 365376.CrossRefGoogle ScholarPubMed
Van Der Hoeven, M, Faber, M, Osei, J et al. (2016) Effect of African leafy vegetables on the micronutrient status of mildly deficient farm-school children in South Africa: a randomized controlled study. Public Health Nutr 19, 935945.CrossRefGoogle ScholarPubMed
Prentice, A, Dibba, B, Sawo, Y et al. (2012) The effect of prepubertal calcium carbonate supplementation on the age of peak height velocity in Gambian adolescents. Am J Clin Nutr 96, 10421050.CrossRefGoogle ScholarPubMed
Neumann, CG, Murphy, SP, Gewa, C et al. (2007) Meat supplementation improves growth, cognitive, and behavioral outcomes in Kenyan children. J Nutr 137, 11191123.CrossRefGoogle ScholarPubMed
Ogunsile, SE & Ogundele, BO (2016) Effect of game-enhanced nutrition education on knowledge, attitude and practice of healthy eating among adolescents in Ibadan, Nigeria. Int J Health Promot Educ 54, 207216.CrossRefGoogle Scholar
Ezezika, O, Oh, J, Edeagu, N et al. (2018) Gamification of nutrition: a preliminary study on the impact of gamification on nutrition knowledge, attitude, and behaviour of adolescents in Nigeria. Nutr Health 24, 137144.CrossRefGoogle Scholar
Neufeld, LM, Andrade, EB, Ballonoff Suleiman, A et al. (2021) Food choice in transition: adolescent autonomy, agency, and the food environment. Lancet 399(10320),185197.CrossRefGoogle ScholarPubMed
Jacob, CM, Hardy-Johnson, PL, Inskip, HM et al. (2021) A systematic review and meta-analysis of school-based interventions with health education to reduce body mass index in adolescents aged 10 to 19 years. Int J Behav Nutr Phys Act 18, 1.CrossRefGoogle ScholarPubMed
Wang, D & Fawzi, WW (2020) Impacts of school feeding on educational and health outcomes of school-age children and adolescents in low- and middle-income countries: protocol for a systematic review and meta-analysis. Syst Rev 9, 55.CrossRefGoogle ScholarPubMed
Galloway, R (2017) Global nutrition outcomes at ages 5 to 19. In Child and Adolescent Health and Development, Chapter 3 [Bundy, DAP, de Silva, N, Horton, S et al., editors]. Washington, DC: The International Bank for Reconstruction and Development/The World Bank.Google Scholar
Ali, Z, Lelijveld, N, Wrottesley, S et al. (2020) Adolescent Nutrition Mapping Study: A Global Stakeholder Survey of Policies, Research, Interventions and Data Gaps. https://www.ennonline.net/adolescentnutritionmappingstudy (accessed May 2021).Google Scholar
Darling, AM, Sunguya, B, Ismail, A et al. (2020) Gender differences in nutritional status, diet and physical activity among adolescents in eight countries in sub-Saharan Africa. Trop Med Int Health 25, 3343.CrossRefGoogle ScholarPubMed
Manyanga, T, El-Sayed, H, Doku, DT et al. (2014) The prevalence of underweight, overweight, obesity and associated risk factors among school-going adolescents in seven African countries. BMC Public Health 14, 887.CrossRefGoogle ScholarPubMed
Muthuri, SK, Wachira, L-JM, Leblanc, AG et al. (2014) Temporal trends and correlates of physical activity, sedentary behaviour, and physical fitness among school-aged children in Sub-Saharan Africa: a systematic review. Int J Environ Res Public Health 11, 33273359.CrossRefGoogle ScholarPubMed
Hawkes, C, Fox, E, Downs, SM et al. (2020) Child-centered food systems: reorienting food systems towards healthy diets for children. Glob Food Secur 27, 100414.CrossRefGoogle Scholar
Hollis, JL, Collins, CE, DeClerck, F et al. (2020) Defining healthy and sustainable diets for infants, children and adolescents. Glob Food Secur 27, 100401.CrossRefGoogle Scholar
Das, JK, Salam, RA, Kumar, R et al. (2013) Micronutrient fortification of food and its impact on woman and child health: a systematic review. Syst Rev 2, 67.CrossRefGoogle ScholarPubMed
Eichler, K, Hess, S, Twerenbold, C et al. (2019) Health effects of micronutrient fortified dairy products and cereal food for children and adolescents: a systematic review. PLoS One 14, e0210899.CrossRefGoogle ScholarPubMed
Gera, T, Sachdev, HS & Boy, E (2012) Effect of iron-fortified foods on hematologic and biological outcomes: systematic review of randomized controlled trials. Am J Clin Nutr 96, 309324.CrossRefGoogle ScholarPubMed
Mithra, P, Khatib, MN, Sinha, AP et al. (2021) Interventions for addressing anemia among children and adolescents: an overview of systematic reviews. Front Pediatr 8, 549549.CrossRefGoogle ScholarPubMed
Baxter, J-AB, Wasan, Y, Soofi, SB et al. (2018) Feasibility and effect of life skills building education and multiple micronutrient supplements v. the standard of care on anemia among non-pregnant adolescent and young Pakistani women (15–24 years): a prospective, population-based cluster-randomized trial. Reprod Health 15, 103.CrossRefGoogle Scholar
Baxter, J-AB, Wasan, Y, Hussain, A et al. (2021) Characterizing micronutrient status and risk factors among late adolescent and young women in rural Pakistan: a cross-sectional assessment of the MaPPS trial. Nutrients 13, 1237.CrossRefGoogle Scholar
Keats, EC, Das, JK, Salam, RA et al. (2021) Effective interventions to address maternal and child malnutrition: an update of the evidence. Lancet Child Adolesc Health 5, 367384.CrossRefGoogle ScholarPubMed
World Health Organization (2018) Weekly Iron and Folic Acid Supplementation As an Anaemia-Prevention Strategy in Women and Adolescent Girls: Lessons Learnt from Implementation of Programmes Among Non-Pregnant Women of Reproductive Age. Geneva: World Health Organization.Google Scholar
Bhutta, ZA, Lassi, ZS, Bergeron, G et al. (2017) Delivering an action agenda for nutrition interventions addressing adolescent girls and young women: priorities for implementation and research. Ann N Y Acad Sci 1393, 6171.CrossRefGoogle Scholar
Salam, RA, Das, JK, Ahmed, W et al. (2019) Effects of preventive nutrition interventions among adolescents on health and nutritional status in low- and middle-income countries: a systematic review and meta-analysis. Nutrients 12, 49.CrossRefGoogle ScholarPubMed
UNESCO Institute for Statistics (2018) One in Five Children, Adolescents and Youth is Out of School. Montreal: UIS.Google Scholar
Li, K, Haynie, D, Palla, H et al. (2016) Assessment of adolescent weight status: similarities and differences between CDC, IOTF, and WHO references. Prev Med 87, 151154.CrossRefGoogle ScholarPubMed
de Onis, M, Onyango, AW, Borghi, E et al. (2007) Development of a WHO growth reference for school-aged children and adolescents. Bull World Health Organ 85, 660667.CrossRefGoogle ScholarPubMed
Cole, TJ, Bellizzi, MC, Flegal, KM et al. (2000) Establishing a standard definition for child overweight and obesity worldwide: international survey. BMJ 320, 12401243.CrossRefGoogle ScholarPubMed
National Center for Health Statistics (2000) 2000 CDC Growth Charts: United States. http://www.cdc.gov/growthcharts/ (accessed April 2021).Google Scholar
World Health Organization (2011) Haemoglobin Concentrations for the Diagnosis of Anaemia and Assessment of Severity. Geneva: World Health Organization.Google Scholar
World Health Organization (2013) Urinary Iodine Concentrations for Determining Iodine Status Deficiency in Populations. Vitamin and Mineral Nutrition Information System. Geneva: World Health Organization.Google Scholar
World Health Organization (2014) Goitre as a Determinant of the Prevalence and Severity of Iodine-Deficiency Disorders in Populations. Geneva: World Health Organization.Google Scholar
World Health Organization (2011) Serum Retinol Concentrations for Determining the Prevalence of Vitamin A Deficiency in Populations. Geneva: World Health Organization.Google Scholar
Holick, MF, Binkley, NC, Bischoff-Ferrari, HA et al. (2011) Evaluation, treatment, and prevention of vitamin D deficiency: an Endocrine Society clinical practice guideline. J Clin Endocrinol Metab 96, 19111930.CrossRefGoogle ScholarPubMed
de Benoist, B, Darnton-Hill, I, Davidsson, L et al. (2007) Conclusions of the joint WHO/UNICEF/IAEA/IZiNCG interagency meeting on zinc status indicators. Food Nutr Bull 28, S480S484.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Population, interventions, control and outcome (PICO) framework

Figure 1

Fig. 1 Flow diagram of search results. PICO, Population, Interventions, Control and Outcome; *Of the 991 articles included, the breakdown of articles per region was: South Asia, n 247; West and Central Africa, n 193; Europe and Central Asia, n 122; Eastern and Southern Africa, n 130; Middle East and North Africa, n 120; East Asia and Pacific, n 112; Latin America and the Caribbean, n 67

Figure 2

Fig. 2 Maps depicting the number of studies with data available from single-country and multi-country studies in the following regions: a, South Asia; b, West and Central Africa; c, Europe and Central Asia; d, Eastern and Southern Africa; e, Middle East and North Africa; f, East Asia and the Pacific; g, Latin America and Caribbean. (a) , 0; , 4–17; , 31–39; , 1–3; , 8–30; , 40+; (b), , 0; , 3–5; , 9–15; , 1–2; , 6–8; , 16+; (c) , 0; , 3–4; , 8–12; , 1–2; , 5–7; , 3+; (d) , 0; , 4–17; , 31–33; , 1–3; , 8–30; , 34+; (e) , 0; , 3–4; , 7–13; , 1–2; , 5–6; , 4+; (f) , 0; , 3–4; , 7–13; , 1–2; , 5–6; , 4+; (g) , 0; , 3–4; , 6–8; , 1–2; , 5–6; , 9+

Figure 3

Fig. 3 Total number of studies reporting data for anthropometric indicators, anaemia and micronutrient deficiencies by region. *Includes studies that also provide data for iron (Fe) deficiency and/or Fe deficiency anaemia. , West and Central Africa; , South Asia; , Eastern and Southern Africa; , Europe and Central Asia; , Middle East and North Africa; , East Asia and the Pacific; , Latin America and the Caribbean

Figure 4

Fig. 4 Range in prevalence of nutrition indicators by country and region for: a, stunting; b, wasting; c, thinness; d: overweight and obesity; e, anaemia; red circles depict the lowest and blue circles the highest prevalence in the range; where only one value was available for a country only a single (blue) circle is depicted

Figure 5

Table 2 Summary of available studies describing prevalence of micronutrient deficiencies in school-age children and adolescents, by region

Figure 6

Table 3 Summary of commonly reported dietary indicators and main findings per region

Figure 7

Table 4 Summary of intervention studies across world regions, according to intervention type and primary outcome

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