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COVID-19 concerns among caregivers and vitamin A supplementation coverage among children aged 6–59 months in four countries in Western sub-Saharan Africa

Published online by Cambridge University Press:  03 July 2023

Melissa M Baker*
Affiliation:
Helen Keller International, P.O. Box 14195 – 00800, Nairobi, Kenya
Amynah Janmohamed
Affiliation:
Helen Keller International, P.O. Box 14195 – 00800, Nairobi, Kenya
Djeinam Toure
Affiliation:
Helen Keller International, Dakar, Senegal
Romance Dissieka
Affiliation:
Helen Keller International, Abidjan, Côte d’Ivoire
Fatou Ndiaye
Affiliation:
Helen Keller International, Dakar, Senegal
Regina Khassanova
Affiliation:
Helen Keller International, Ouagadougou, Burkina Faso
Mohamed Lamine Fofana
Affiliation:
Helen Keller International, Corniche nord, Conakry, Guinea
David Doledec
Affiliation:
Helen Keller International, P.O. Box 14195 – 00800, Nairobi, Kenya
*
*Corresponding author: Email mbaker@hki.org
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Abstract

Objective:

To assess child vitamin A supplementation (VAS) coverage in 2019 and 2020 and explore key factors, including COVID-19 concerns, that influenced VAS status in four sub-Saharan African countries.

Design:

Data from eight representative household surveys were used to assess VAS coverage. Multivariable logistic regression models examined the effect of rural/urban residence, child sex and age, caregiver education, COVID-19 concern and household wealth on VAS status.

Setting:

Nine (2019) and 12 (2020) districts in Burkina Faso, Côte d’Ivoire, Guinea and Mali.

Participants:

28 283 caregivers of children aged 6–59 months.

Results:

Between 2019 and 2020, VAS coverage increased in Burkina Faso (82·2–93·1 %), Côte d’Ivoire (90·3–93·3 %) and Mali (76·1–79·3 %) and decreased in Guinea (86·0 % to 81·7 %). Rural children had a higher likelihood of VAS uptake compared with urban children in Burkina Faso (adjusted OR (aOR) = 4·22; 95 % CI: 3·11, 5·72), Côte d’Ivoire (aOR = 5·19; 95 % CI: 3·10, 8·70) and Mali (aOR = 1·41; 95 % CI: 1·15, 1·74). Children aged 12–59 months had a higher likelihood of VAS uptake compared with children aged 6–11 months in Côte d’Ivoire (aOR = 1·67; 95 % CI: 1·12, 2·48) and Mali (aOR = 1·74; 95 % CI: 1·34, 2·26). Moderate-to-high COVID-19 concern was associated with a lower likelihood of VAS uptake in Côte d’Ivoire (aOR = 0·55; 95 % CI: 0·37, 0·80).

Conclusion:

The increase in VAS coverage from 2019 to 2020 suggests that COVID-19 concerns may not have limited VAS uptake in some African countries, though geographic inequities should be considered.

Type
Research Paper
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 (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of The Nutrition Society

Vitamin A deficiency (VAD) is of significant public health concern in areas where nutritionally poor diets inhibit adequate consumption of vital nutrients for good health. Contributing to child malnutrition, VAD poses particularly serious consequences for children under 5 years of age(Reference Imdad, Mayo-Wilson and Herzer1). VAD remains highly prevalent in much of sub-Saharan Africa (SSA), where upwards of 50 % of children aged 6–59 months are affected(2). In 2019, central, eastern and western SSA had the highest age-standardised incidence and disability-adjusted life years rates of VAD, with rates of 15 571 per 100 000 and 37 per 100 000, respectively, in western SSA(Reference Zhao, Liu and Zhang3).

The WHO strongly recommends vitamin A supplementation (VAS) for infants and children of 6–59 months of age in areas where VAD is a public health problem(4). Recent evidence suggests a 12 % decrease in all-cause mortality and diarrhoea-specific mortality and significant reductions in the incidence of diarrhoea, measles, Bitot’s spots, night blindness and VAD in children under 5 years of age who receive biannual VAS(Reference Imdad, Mayo-Wilson and Herzer1). Helen Keller International and partner organisations work with governments throughout SSA to distribute VAS, mainly through semiannual door-to-door health events, and to support the integration of VAS into essential health service packages at the community level.

The global impact of COVID-19 on the health sector has been far-reaching. Widespread service disruptions have led to delayed child health events and limited outreach activities through which VAS is normally delivered(5). Though reported VAS coverage in some SSA countries exceeded 80 % prior to the COVID-19 pandemic(6), little is known about the effects of pandemic-related challenges and mitigation measures implemented by national governments and supporting international organisations on VAS coverage. Available data indicate that two-dose VAS coverage was substantially lower in 2020, as compared with pre-pandemic levels, in SSA and South Asia, with only approximately 40 % of targeted children reached and the lowest reported coverage in Central and West Africa(6). However, these coverage estimates are based on reported country administrative data, which have shown to be unreliable when compared with other assessment methods(Reference Janmohamed and Doledec7). This study aimed to assess VAS coverage among children aged 6–59 months in 2019 and 2020 and explore the key factors that influenced VAS uptake in 2020, including COVID-19 perceptions, in Burkina Faso, Côte d’Ivoire, Guinea and Mali.

Methods

Study design and population

This cross-sectional study utilised data from eight Post-Event Coverage Surveys (PECS) conducted in Burkina Faso, Côte d’Ivoire, Guinea and Mali during 2019 and 2020. All surveys were conducted within 6 weeks following door-to-door health events that included VAS distribution in each country. In 2019, PECS were conducted in each country between June and July. Due to the COVID-19 pandemic, periods of data collection varied throughout 2020, with PECS administered in July/August (Guinea), October (Mali) and December 2020/January 2021 (Burkina Faso, Côte d’Ivoire).

Each survey employed a randomised cluster design with enumeration areas selected using probability proportional to size sampling methodology. Numbers of survey strata, clusters and households varied by country in 2019 and 2020; however, the same design effect (2·5), non-response inflation factor (1·02), response rate (0·98), intracluster correlation coefficient (0·167), desired level of precision (0·95), alpha (0·05) and expected coverage (0·80) were consistent across all PECS. Survey enumeration areas in each stratum were randomly selected by the respective National Institute of Statistics in each country. Households were randomly selected from household lists in each cluster and were eligible to participate if there was a primary child caregiver present at the time of the survey and at least one child in the household was aged 6–59 months during the preceding health event. PECS were conducted by experienced and trained interviewers who were independent from the VAS distribution activities. Training tools and modalities were adapted to incorporate COVID-19 infection prevention and control measures and to sensitise interviewers on adherence to COVID-19 protocols. Additionally, survey supervisors visited 10 % of sampled households in each cluster to administer a shortened PECS to verify the data collected in the primary surveys.

Administrative systems in the study countries include a hierarchy of national, regional and local authorities. Structured according to functional and geographic responsibilities, the system includes ministries, regional authorities, and several health districts within each region that include urban and rural areas. Each country is unique in that different levels of the administrative system manage specific aspects of the VAS distribution and the PECS. In Burkina Faso, Mali and Guinea, oversight of VAS distribution and the PECS is at the regional level, whereas oversight is done at the health district level in Côte d’Ivoire. Of the 13 regions in Burkina Faso, the PECS was representative of three in 2019 and five in 2020. In Mali, five of the 11 regions were represented in 2019 and 2020. Of the 113 health districts in Côte d’Ivoire, the PECS was representative of 71 health districts in 2019 and 72 health districts in 2020. In Guinea, the PECS was nationally representative in 2019 and 2020. In all countries, both the 2019 and 2020 PECS included questions on: household socio-demographic characteristics; health-seeking practices; health event/campaign communication methods; vitamin A and VAS knowledge and attitudes; VAS status; and reasons for non-supplementation. An additional module in the 2020 PECS included questions related to COVID-19 knowledge, attitudes and behaviours, as well as compliance with infection control measures.

Statistical analysis

Survey data were electronically recorded using smartphones and directly exported to Excel for preliminary analysis. Sampling weights were calculated to generate representative estimates for respective survey regions/districts. SPSS Complex Samples 26.0 (IBM Corp) was used to conduct descriptive, bivariate and multivariable analyses. The study outcome was child VAS status, as determined from the child’s health card or caregiver recall. Based on these data, VAS coverage estimates for 2019 and 2020 were calculated for each country. Logistic regression models examined the effects of rurality, child sex and age, caregiver education, household wealth and level of COVID-19 concern on VAS status. Model variables were included based on a significant (P < 0·05) bivariate relationship and/or acknowledged association with VAS. Results are presented as OR with 95 % CI (α = 0·05). Sample-weighted estimates are presented for all outcome results. Separate analyses were conducted for each country. Ethical approval was obtained from the respective institutions in each country, and informed consent was required from all survey respondents prior to participation.

Results

Data were collected from a total of n 28 283 respondents across the eight surveys. The proportion of rural v. urban households varied across countries, with approximately 80 % and 70 % of surveyed households in rural localities in Burkina Faso and Mali, respectively, and less than 50 % of households in rural areas in Côte d’Ivoire and Guinea (Table 1). In all countries, the majority of respondents in the 2019 and 2020 PECS were mothers. The largest proportions of fathers, grandparents and other respondents were in Guinea in the 2019 (41·1 %) and 2020 (47·7 %) surveys. In Côte d’Ivoire and Mali, there was an approximate 10 % decrease in the percentage of respondents who were mothers between 2019 and 2020. In all countries, more than 90 % of mothers in the household were aged 20 years or older. The majority of mothers reported having no formal education, with the highest percentage in Burkina Faso (73·1 % in 2019; 72·6 % in 2020). Infants aged 6–11 months comprised 9–13 % of surveyed children and child sex parity was observed across all four countries, with the largest difference (52·6 % male v. 47·4 % female) in Côte d’Ivoire in 2020 (Table 1). In 2020, 40·4 % of households in Burkina Faso, 42·7 % in Côte d’Ivoire, 39·9 % in Guinea and 54·5 % in Mali were classified as having very poor or poor wealth status. In the 2020 surveys, the majority of respondents in all countries expressed concern about COVID-19. Approximately one in five respondents in Côte d’Ivoire, Guinea and Mali and almost one-quarter (24·1 %) in Burkina Faso reported being very concerned about COVID-19, while 8·3 % of respondents in Burkina Faso, 11·2 % in Côte d’Ivoire, 15·7 % in Guinea and 10·8 % in Mali reporting not being concerned (Table 2). Notwithstanding the level of COVID-19 concern, more than 90 % of respondents in all countries reported they were willing for their child(ren) to receive VAS at the household (Table 2).

Table 1 Participant characteristics

Table 2 Level of COVID-19 concern and attitudes towards vitamin A supplementation among caregivers of children aged 6–59 months

In 2019, VAS coverage among children aged 6–59 months ranged from 76·1 % in Mali to 90·3 % in Côte d’Ivoire (Table 3). VAS coverage was higher in 2020, as compared with 2019, in Burkina Faso (93·1 % v. 82·2 %), Côte d’Ivoire (93·3 % v. 90·3 %) and Mali (79·3 % v. 76·1 %). In Guinea, a 4·3 % decrease in VAS coverage was observed between 2019 (86·0 %) and 2020 (81·7 %) (Table 3). In 2020, VAS coverage in the four countries was significantly higher among children in rural households, as compared with those in urban households (Burkina Faso: 93·4 % v. 81·0 %, P < 0·001; Côte d’Ivoire: 98·2 % v. 90·5 %, P < 0·001; Guinea: 85·9 % v. 64·8 %, P < 0·001; Mali: 81·3 % v. 72·1 %, P < 0·001) and was higher among children aged 24–59 months, as compared with those aged 6–11 months in Guinea (83·3 % v. 71·1 %, P < 0·001) and Mali (80·7 % v. 71·0 %, P < 0·001). No differences in VAS coverage were observed between male and female children in any of the four countries. VAS coverage was lowest among children in the wealthiest household category in Burkina Faso (P = 0·026), Côte d’Ivoire (P < 0·001), Guinea (P < 0·001) and Mali (P < 0·001) and was lowest among children of caregivers with the highest level of education in Burkina Faso (P = 0·028), Côte d’Ivoire (P = 0·036) and Mali (P < 0·001). Among children in households reporting a high level of COVID-19 concern, VAS coverage was 91·9 % in Burkina Faso, 91·5 % in Côte d’Ivoire, 85·9 % in Guinea and 78·1 % in Mali. In Mali, VAS coverage was 9·3 % higher (78·1 % v. 68·8 %, P = 0·029) for children in highly concerned households, as compared with not concerned households. Approximately 10 % more caregivers in rural, as compared with urban, households reported willingness for their child(ren) to receive VAS at the household in Burkina Faso, Côte d’Ivoire and Mali, whereas this difference was approximately 20 % in Guinea.

Table 3 VAS coverage among children aged 6–59 months during 2019 and 2020 campaigns

In Burkina Faso, Côte d’Ivoire and Mali, the most frequently reported reason for children not receiving VAS during both the 2019 and 2020 events was health workers not coming to the household to provide VAS (Table 4). In Guinea, the child being absent at the time of supplementation (41·2 %) and health workers not coming to administer VAS at the household (55·7 %) were the most commonly mentioned barriers to supplementation during the 2019 and 2020 events, respectively. In 2020, the child not being present at the time of VAS distribution was reported by approximately 30 % of respondents in Côte d’Ivoire. In Mali, about 20 % of respondents reported not being informed about VAS and/or the health event, while in Burkina Faso 12–15 % of respondents cited a lack of VAS supply as the reason for non-supplementation. VAS refusal ranged from < 0·5 % of households in Burkina Faso in 2019 and 2020 to 13·6 % of households in the 2019 Guinea survey (Table 4). Mask wearing by health workers distributing VAS at the household during the 2020 events was observed by 86·9 % of respondents in Burkina Faso, 84·5 % in Côte d’Ivoire, 72·6 % in Guinea and 67·0 % in Mali.

Table 4 Reasons for children aged 6–59 months not receiving vitamin A supplementation during 2019 and 2020 campaigns

N/A: Data not collected.

As we could not statistically compare 2019 and 2020 coverage estimates due to country sampling variations, the following findings were generated from adjusted models that included data from the 2020 surveys. Children in rural areas had a higher likelihood of receiving VAS, as compared with those in urban areas, in Burkina Faso (OR = 4·22; 95 % CI: 3·11, 5·72), Côte d’Ivoire (OR = 5·19; 95 % CI: 3·10, 8·70), Guinea (OR = 2·94; 95 % CI: 2·30, 3·77) and Mali (OR = 1·41; 95 % CI: 1·15, 1·74) (Table 5). Children aged 12–59 months were more likely to receive VAS, as compared with those aged 6–11 months, in Côte d’Ivoire (OR = 1·67; 95 % CI: 1·12, 2·48), Guinea (OR = 1·93; 95 % CI: 1·34, 2·77) and Mali (OR = 1·74; 95 % CI: 1·34, 2·26). In Mali, caregiver education was associated with a higher likelihood of child VAS (OR = 1·26; 95 % CI: 1·04, 1·53), while children in the middle household wealth (OR = 0·45; 95 % CI: 0·37, 0·54) and highest wealth (OR = 0·37; 95 % CI: 0·30, 0·46) categories had a lower likelihood of VAS. A moderate to high level of caregiver concern regarding COVID-19 was associated with a lower likelihood of child VAS only in Côte d’Ivoire in both the unadjusted (OR = 0·50; 95 % CI: 0·34, 0·72) and multivariable (adjusted OR (aOR) = 0·55; 95 % CI: 0·37, 0·80) models (Table 5). A further exploration of COVID-19 concerns by socio-economic position in Côte d’Ivoire revealed that middle (OR = 1·40; 95 % CI: 1·12, 1·74) and highest (OR = 1·66; 95 % CI: 1·38, 1·98) wealth households were more likely to have a moderate/high level of COVID-19 concern, as compared with the lowest wealth households. In addition, rural households were less likely to have a moderate/high level of COVID-19 concern, as compared with urban households (OR = 0·75; 95 % CI: 0·64, 0·88).

Table 5 Multivariable regression associations between predictor variables and vitamin A supplementation among children aged 6–59 months during 2020 campaigns

AOR, adjusted OR.

* Unadjusted estimates: Burkina Faso (OR = 1·13; 95 % CI: 0·84, 1·51); Côte d’Ivoire (OR = 0·50; 95 % CI: 0·34, 0·72); Guinea (OR = 0·93; 95 % CI: 0·74, 1·18); and Mali (OR = 1·02; 95 % CI: 0·84, 1·25).

Discussion

We sought to assess VAS coverage and examine the influence of key factors, including COVID-19 concerns, on VAS uptake among children aged 6–59 months in four countries in SSA. The higher VAS coverage observed in 2020, as compared with pre-pandemic levels, in three countries was unexpected. Global evidence (based on administrative data) from the same time period suggests the suspension of door-to-door (mass campaign) health events caused a 19 % decrease in two-dose VAS coverage in 2020, as compared with 2019, particularly during the first half of the year which subsequently impacted two-dose VAS coverage in 2020(Reference Hasman, Imohe and Krasevec8). Despite the challenges imposed by the pandemic, Helen Keller International managed to promote, facilitate and support the distribution of VAS through two rounds of door-to-door health events within most supported countries in 2020, albeit while respecting the mitigation measures recommended by WHO and country governments. Standard supplementation procedures were followed in Helen Keller International-supported programmes in Burkina Faso, Côte d’Ivoire and Mali during the pandemic, with the addition of COVID-19 infection control measures. In Guinea, VAS distribution modalities changed during the first campaign round in 2020 from a pre-pandemic 5-d distribution event to a multi-phased approach targeting different districts over a 2-month period. This altered delivery strategy may have contributed to the lower VAS coverage observed in Guinea in 2020, as compared with 2019. Furthermore, in Guinea, a higher percentage of survey respondents were non-mothers which could have affected knowledge and or recall of children’s supplementation status.

A possible explanation for the higher-than-expected VAS coverage observed during the pandemic in our study is apprehensions surrounding COVID-19 did not negatively impact VAS uptake in areas supported by Helen Keller International where VAS distribution occurred. There may have been increased propensity towards positive health-seeking behaviours due to heightened health and safety awareness from media and other sources, in addition to intensive mobilisation efforts by Helen Keller International and partners that incorporated strategies to sensitise communities and adopt infection prevention and control measures during door-to-door visits(Reference Sakho, Badila and Dembele9). This is further supported by the vast majority (83–94 %) of respondents affirming they could reduce COVID-19 transmission through their own actions. In addition to community knowledge about vitamin A and its importance for child health, the likely greater attention to hygiene/disease prevention during the pandemic may have bolstered parental willingness for VAS to protect children from illness at a time when access to routine health services was especially limited. Furthermore, across the four countries, high VAS coverage (78–92 %) was observed among households reporting a high level of concern about COVID-19. Though this was unexpected, as 65–78 % of households expressed being concerned or very concerned about COVID-19, these findings further support the likelihood that pandemic-related fears did not greatly affect perceptions and attitudes towards VAS in these settings.

Though the precise reasons for the lower VAS coverage observed in Guinea in 2020 are not known, the large proportion of caregivers who reported that their child(ren) did not receive VAS due to health workers not coming to their community suggests that logistical constraints, perhaps worsened by pandemic-related challenges, may have played a greater role in Guinea. Notwithstanding, the lack of distribution in target areas was also the primary reported barrier to VAS receipt in Burkina Faso, Côte d’Ivoire and Mali and reduced accessibility due to geographic, pandemic and/or other factors presumably affected VAS delivery in all countries. Though community outreach challenges were likely exacerbated during the pandemic, our findings are consistent with results from other studies conducted prior to the pandemic indicating that households not being reached during door-to-door campaigns is a key contributor to missed VAS doses in the SSA context(Reference Hodges, Sesay and Kamara10,Reference Janmohamed, Klemm and Doledec11) .

In 2020, VAS coverage was > 90 % in Burkina Faso and Côte d’Ivoire and approximately 80 % in Guinea and Mali. Though these levels meet the WHO/UNICEF guidelines for at least 80 % coverage as a measure of effective VAS programming, subnational disparities and socio-economic inequities remain, particularly between rural and urban areas. In 2020, VAS coverage was 10–20 % higher in rural, as compared with urban, areas across the four countries. A possible reason for this disparity may be poorer accessibility in densely populated urban areas that was exacerbated by pandemic-related disruptions in health services. Apart from the unique challenges imposed by COVID-19, mixed evidence exists for the association between rural/urban residence and VAS, with both higher rural and urban coverage observed in different settings(Reference Janmohamed, Klemm and Doledec11Reference Zegeye, Olorunsaiye and Ahinkorah18).

In our study, a higher level of caregiver education and increased household wealth were not predictors of VAS uptake in Burkina Faso, Côte d’Ivoire and Guinea, while caregiver education was positively associated with VAS in Mali. Although these were unexpected findings, it is possible that caregivers with a higher level of education did not consider VAS to be necessary, whereas households with a lower socio-economic status may have been more willing for their children to receive VAS due to increased perceptions of vulnerability to illness, particularly during the pandemic. Additionally, heightened COVID-19 concern among more educated individuals could have influenced decisions surrounding child VAS at the household, as evident in Côte d’Ivoire where wealthier urban households had increased apprehensions about COVID-19, as compared with poorer rural households.

Therefore, our findings suggest good VAS compliance across socio-economic strata, also possibly due to effective community sensitisation strategies. While our findings contrast with available evidence from SSA indicating higher VAS uptake among advantaged children with educated mothers and wealthier households(Reference Aghaji, Duke and Aghaji12,Reference Berde, Bester and Kruger14Reference Sagalova, Zagre and Vollmer21) , large multi-country studies tend to pool data from various delivery models, thereby potentially masking key contributors to VAS uptake. We hypothesise that education and wealth status may not be key determinants of VAS coverage in door-to-door delivery models, but rather more significant factors in facility-based programmes that require active seeking of health services. In a pooled analysis of 44 PECS conducted in 13 SSA countries, caregivers with some formal education were more likely to have brought their children to a fixed site for VAS and less likely to have their children receive VAS during door-to-door distribution events(Reference Janmohamed, Klemm and Doledec11).

In Côte d’Ivoire, Guinea and Mali, children aged 12 months and older had a higher likelihood of VAS, as compared with infants 6–11 months of age. Similarly, a pooled analysis of Demographic and Health Surveys conducted from 2011 to 2015 in 23 SSA countries showed children aged 12–23 months (OR = 1·63; 95 % CI: 1·58, 1·69) and 24–35 months (OR = 1·38; 95 % CI: 1·34, 1·43) were more likely to receive VAS, as compared with those aged 6–11 months(Reference Berde, Bester and Kruger14). The lower VAS coverage observed for children under one year of age in our study could indicate challenges reaching these youngest children during the campaigns and/or that these infants may have been provided VAS during their routine childhood immunisation visits in the months preceding the survey.

A key strength of our study was the inclusion of data representative at the regional/district level from four countries in the West African region. In addition, VAS distribution followed a similar door-to-door delivery model in all countries, and standard survey design, sampling and data collection methods were employed in all regions. The 6-week time interval between VAS distributions and the post-event household surveys likely minimised the effect of recall bias. As PECS are cross-sectional, we examined associations between VAS and explanatory variables but could not infer causality. Though we controlled for potential confounding variables, there may have been influences from other factors not accounted for in the study. We could not statistically compare 2019 and 2020 coverage estimates due to country sampling variations. Moreover, the results should not be compared across countries as the individual surveys were not designed to detect inter-country differences. The time of year during which VAS distribution occurred varied within and across countries, which could have affected VAS delivery mechanisms and coverage. The limited information available in our study regarding disruptions in service delivery due to COVID-19 that could have affected VAS coverage in our settings should be considered. In addition, as the PECS assessed door-to-door VAS coverage, we were not able to capture VAS doses administered at health facilities or other fixed sites. Lastly, our findings should be considered with the caveat that surveys and administrative records serve distinct purposes with different populations, sampling, data collection methods and outcome measures (single- v. two-dose) and, therefore, tend to produce dissimilar VAS coverage estimates.

In our study, COVID-19-related concerns were not limiting factors to the uptake of VAS through house-to-house delivery in the West African context, suggesting high coverage can be achieved during a public health crisis. Nonetheless, geographic disparities in coverage, particularly between urban and rural areas, should be further investigated and considered in the planning and implementation of door-to-door VAS distribution. This is especially important during public health crises when service disruptions further exacerbate health disparities and prevent equitable coverage in certain areas. Targeted post-pandemic efforts are needed for missed VAS doses, ideally provided with other essential child health services, including immunisations, deworming and screening for acute malnutrition. Achieving substantial reductions in child mortality requires children aged 6–59 months to receive twice-yearly vitamin A supplements where VAD is a public health problem, such as in these study settings. Though our findings suggest high coverage can be achieved during a public health crisis, local factors that may have affected programme implementation during the pandemic should be considered, along with targeted efforts for hard-to-reach areas.

Acknowledgements

The authors would like to send their gratitude to the Helen Keller Intl staff and everyone in Burkina Faso, Côte d’Ivoire, Guinea and Mali who worked tirelessly to ensure that VAS distribution continued, and that hundreds of thousands of young children received VAS, during a global health crisis. We would also like to thank every person involved in the collection of data for the PECS, and all the people who participated in the surveys, including Le Ministère de la Sante à travers la Division Alimentation Nutrition, Guinée, Le Ministère de la Sante à travers le Programme National ce Nutrition, Côte d’Ivoire, La Direction Générale de la Santé et de l’Hygiène publique du ministère de la Santé et des Affaires Sociales, Mali, La Direction de Nutrition du Ministere de la Santé, Burkina Faso, and UNICEF and Effect Hope in Côte d’Ivoire. We would like to thank Dr. Jennifer Nielsen (Helen Keller Intl) and Dr. Rolf Klemm (Helen Keller Intl and Johns Hopkins University) for their careful review of this article, the analysis and the study results.

Financial support

This work was supported by GiveWell via a donation to Helen Keller International.

Conflict of interest

There are no conflicts of interest.

Authorship

MB, DT and RD conceived and designed the study. DD and DT supervised the study. MB and AJ drafted the analytical framework and developed the first iteration of the manuscript, AJ conducted all statistical analysis. DT, RD, DD, FT, RK, MLF and MB verified the analytical methods and study findings and contributed critical feedback and helped shape the Methods and Discussion sections of the manuscript.

Ethical standards

This study was conducted according to the guidelines outlined in the Declaration of Helsinki and all procedures involving research study participants were approved by the national research ethics committee in each country where data were collected, namely Le Comité National d’Éthique pour la Recherche en Santé (CNERS), République de Guinée, Le Comité National D’éthique des Sciences de la Vie et de la Santé (CNESVS), Ministère de la santé et de l’hygiène publique, République de Côte d’Ivoire, Le Comité d’éthique de l’institut national de recherche en santé publique (INRSP), Ministère de la santé et des affaires sociales, République du Mali, and Le Comité d’éthique pour la recherche en santé (CERS), Ministère de la santé et Ministère de l’enseignement supérieur, de la recherche scientifique et de l’innovation, Burkina Faso. Verbal informed consent was obtained from all subjects/patients. Verbal consent was witnessed and formally recorded.

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Table 1 Participant characteristics

Figure 1

Table 2 Level of COVID-19 concern and attitudes towards vitamin A supplementation among caregivers of children aged 6–59 months

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Table 3 VAS coverage among children aged 6–59 months during 2019 and 2020 campaigns

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Table 4 Reasons for children aged 6–59 months not receiving vitamin A supplementation during 2019 and 2020 campaigns

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Table 5 Multivariable regression associations between predictor variables and vitamin A supplementation among children aged 6–59 months during 2020 campaigns