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Aflatoxin exposure and micronutrient deficiency among young children from Guinea

Published online by Cambridge University Press:  11 September 2015

S. Watson
Affiliation:
Institute for Global Food Security, School of Biological Sciences, Queen's University Belfast, Belfast BT9 5BN, UK
G. Chen
Affiliation:
Institute for Global Food Security, School of Biological Sciences, Queen's University Belfast, Belfast BT9 5BN, UK
Y.Y. Gong
Affiliation:
Institute for Global Food Security, School of Biological Sciences, Queen's University Belfast, Belfast BT9 5BN, UK
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Abstract

Type
Abstract
Copyright
Copyright © The Authors 2015 

The causes of high prevalence of micronutrient deficiency in children from developing countries are multifactorial and not simply a direct result of inadequate dietary intake (Reference Ruel and Alderman1). It has been postulated that aflatoxin, a type of mycotoxin, that frequently affects dietary staples such as groundnuts and maize, may impair gut permeability, reduce nutrient bioavailability, and consequently exacerbate micronutrient deficiency (Reference Gong, Turner and Hall2). Most of the evidence supporting this relationship is from animal feeding studies (Reference Williams, Phillips and Jolly3) and the limited evidence in human subjects is inconsistent. The aim of this study was to examine the relationship between aflatoxin exposure and micronutrient deficiency among young children from Guinea.

A total of 305 children (50·5 % male; mean age 28·8 ± 8·4 months) were randomly recruited at harvest (October) from subsistence farming households located within the region of Kindia, West Guinea, an area where groundnuts are a dietary staple and aflatoxin exposure is high. To assess seasonal variations, six months post-harvest, the children were followed up again where possible (n = 288). Aflatoxin exposure was assessed in blood samples using the aflatoxin-albumin adduct (AF-alb) biomarker measured by an ELISA method. Plasma micronutrient concentrations including vitamin A, vitamin E, beta-carotene and zinc were measured using HPLC methods. Socio-demographic and dietary information were recorded.

At harvest 88·2 % and at post-harvest 93·4 % of blood samples had detectable AF-alb concentrations. The geometric mean AF-alb concentration at harvest was significantly lower than at post-harvest (12·70, 95 % CI: 10·91, 14·73 vs. 16·29, 95 % CI: 14·44, 18·54 pg/mg; P = 0·009). Vitamin A, vitamin E and beta-carotene median concentrations increased significantly from harvest to post-harvest (P < 0·001); whereas zinc concentrations decreased (P = 0·008). Similarly, more children were deficient in vitamin A (78·9 % vs. 60·5 %, P < 0·001) and vitamin E (44·7 % vs. 26·3 %, P = 0·001) at harvest than at post-harvest; while more children were deficient in zinc at post-harvest than at harvest (75·2 % vs. 57·5 %, P = 0·001). Logistic regression was undertaken to determine the association between micronutrient deficiency and aflatoxin exposure at each time point. As shown in the table below, children in the highest aflatoxin exposure group (Q4), compared to the lowest (Q1) were 1·98 (95 % CI: 1·00, 3·92) and 3·56 (95 % CI: 1·13, 11·15) times more likely to be zinc and vitamin A deficient at harvest. Also, children in the second lowest aflatoxin exposure group (Q2) were 2·05 (95 % CI: 1·03, 4·07) times more likely to be zinc deficient compared to the lowest exposed group (Q1). No correlation was found at post-harvest.

Analysed using logistic regression: *P ⩽ 0·05, **P ⩽ 0·01, ***P ⩽ 0·001. Data presented as odd ratios (95 % CI). Adjusted for age, gender, socio-economic status and breastfeeding status. Q is quartile. Q1 is the reference group (lowest exposed) and Q4 is the highest exposed group.

Aflatoxin exposure and micronutrient deficiencies were highly prevalent in this population group and were influenced by season. Children with high aflatoxin exposure levels were more likely to be zinc and vitamin A deficient at harvest. Targeting aflatoxin exposure may help the outcomes of micronutrient supplementation trials.

References

1. Ruel, MT & Alderman, H (2013) Lancet 382, 536–531.Google Scholar
2. Gong, YY, Turner, PC, Hall, AJ et al. (2008) In: Mycotoxins: Detection Methods, Management, Public Health, and Agricultural Trade, pp. 5366. Wallingford, UK.Google Scholar
3. Williams, JH, Phillips, TD, Jolly, PE et al. (2004) Am J Clin Nutr 80, 11061122.Google Scholar