Improving the Dietary Vitamin A Content of Rural Communities in South Africa by Replacing Non-Biofortified White Maize and Sweet Potato with Biofortified Maize and Sweet Potato in Traditional Dishes

Overview

Journal Nutrients

Date 2019 May 31

PMID 31141908

Citations 9

Authors

Laurencia Govender

Kirthee Pillay

Muthulisi Siwela

Albert Thembinkosi Modi

Tafadzwanashe Mabhaudhi

Affiliations

Soon will be listed here.

Abstract

Biofortification of staple crops has a potential for addressing micronutrient deficiencies, such as vitamin A deficiency (VAD), which are prevalent in South Africa. The poor acceptability of provitamin A (PVA)-biofortified foods could be improved by combining them with other food items to produce modified traditional dishes. The nutritional composition of the dishes could also be improved by the modification. The study aimed to investigate the effect of replacing white maize and cream-fleshed sweet potato (CFSP)] with PVA-biofortified maize and orange-fleshed sweet potato (OFSP) on the nutritional composition of South African traditional dishes. The protein, fibre, total mineral (ash), lysine, and iron concentrations of the PVA maize (traditional porridge) composite dishes (control), were not significantly different ( > 0.05) from those of white maize composite dishes. However, the PVA concentration of PVA maize composite dishes was higher than that of the white composite dishes ( > 0.05). The OFSP had a significantly lower protein concentration, but a significantly higher ( > 0.05) fibre, ash, lysine, isoleucine, leucine, and PVA concentration, relative to the CFSP. The findings indicate that composite dishes in which white maize is replaced with PVA-biofortified maize, and switching over from CFSP to OFSP, would contribute to combating VAD in South Africa, and in other developing counties.

Citing Articles

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Fermented Gluten-Free Multi-Grain Cereal Paste Development: The Role of the Orange-Fleshed Sweet Potato (OFSP) as a Dietary Supplement.

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