RESUMO
Introduction: Anaemia is one of the micronutrient deficiency disorders that have global public health implications. The present study aims to determine the association of minimum dietary diversity (MDD) with anaemia among children aged 6-59 months in rural North India. Methods: In Rohtak (a north Indian city), a cross-sectional survey was conducted in 2018-19 (n = 266). Univariate and bivariate analyses were performed. The Chi-square test was used for assessing the significance level during bivariate analysis. Further, multivariable regression analysis was used for determining the factors for anaemia prevalence among children aged 6-59 months. Results: About 62.4% (n = 166) of the children aged 6-59 months were found to have anaemia in the study area. The prevalence of MDD was 35.3% (n = 94). It was found that children with no MDD have a higher prevalence of moderate (42% vs. 25.5%; P < 0.001) and severe (12.8% vs. 8.5%; P < 0.001) anaemia. It was revealed that the children with no MDD had a significantly higher likelihood of being anaemic than children with MDD in model-1 [aOR: 2.09; CI: 1.23, 3.55] and model-3 [aOR: 1.70; CI: 1.01, 3.01]. Children with mothers who never attended school had significantly higher odds for anaemia in reference to those children whose mothers ever attended school in model-2 [aOR: 3.62; CI: 2.07,6.34] and model-3 [aOR: 3.00; CI: 1.62,5.56]. Conclusion: Measures to alleviate under-five anaemia should include empowering and educating women, expanding access to supplementation, fortification programmes, and promoting and raising awareness about feeding diverse foods, while also considering the socioeconomic status.
RESUMO
BACKGROUND: Anthropogenic air pollution has been implicated in aberrant changes of DNA methylation and homocysteine increase (>15µM/L). Folate (<3 ng/mL) and vitamin B12 (<220 pg/mL) deficiencies also reduce global DNA methylation via homocysteine increase. Although B-vitamin supplements can attenuate epigenetic effects of air pollution but such understanding in population-specific studies are lacking. Hence, the present study aims to understand the role of air pollution, homocysteine, and nutritional deficiencies on methylation. METHODS: We examined cross-sectionally, homocysteine, folate, vitamin B12 (chemiluminescence) and global DNA methylation (colorimetric ELISA Assay) among 274 and 270 individuals from low- and high- polluted areas, respectively, from a single Mendelian population. Global DNA methylation results were obtained on 254 and 258 samples from low- and high- polluted areas, respectively. RESULTS: Significant decline in median global DNA methylation was seen as a result of air pollution [high-0.84 (0.37-1.97) vs. low-0.96 (0.45-2.75), p = 0.01]. High homocysteine in combination with air pollution significantly reduced global DNA methylation [high-0.71 (0.34-1.90) vs. low-0.93 (0.45-3.00), p = 0.003]. Folate deficient individuals in high polluted areas [high-0.70 (0.37-1.29) vs. low-1.21 (0.45-3.65)] showed significantly reduced global methylation levels (p = 0.007). In low polluted areas, despite folate deficiency, if normal vitamin B12 levels were maintained, global DNA methylation levels improved significantly [2.03 (0.60-5.24), p = 0.007]. Conversely, in high polluted areas despite vitamin B12 deficiency, if normal folate status was maintained, global DNA methylation status improved significantly [0.91 (0.36-1.63)] compared to vitamin B12 normal individuals [0.54 (0.26-1.13), p = 0.04]. CONCLUSIONS: High homocysteine may aggravate the effects of air pollution on DNA methylation. Vitamin B12 in low-polluted and folate in high-polluted areas may be strong determinants for changes in DNA methylation levels. The effect of air pollution on methylation levels may be reduced through inclusion of dietary or supplemented B-vitamins. This may serve as public level approach in natural settings to prevent metabolic adversities at community level.