Abstract
Improving the nutritional quality of Fe in maize (Zea mays) represents a biofortification strategy to alleviate iron deficiency anemia. Therefore, the present study measured iron content and bioavailability via an established bioassay to characterize Fe quality in parts of the maize kernel. Comparisons of six different varieties of maize demonstrated that the germ fraction is a strong inhibitory component of Fe bioavailability. The germ fraction can contain 27–54% of the total kernel Fe, which is poorly available. In the absence of the germ, Fe in the non-germ components can be highly bioavailable. More specifically, increasing Fe concentration in the non-germ fraction resulted in more bioavailable Fe. Comparison of wet-milled fractions of a commercial maize variety and degerminated corn meal products also demonstrated the inhibitory effect of the germ fraction on Fe bioavailability. When compared to beans (Phaseolus vulgaris) containing approximately five times the concentration of Fe, degerminated maize provided more absorbable Fe, indicating substantially higher fractional bioavailability. Overall, the results indicate that degerminated maize may be a better source of Fe than whole maize and some other crops. Increased non-germ Fe density with a weaker inhibitory effect of the germ fraction are desirable qualities to identify and breed for in maize.
Highlights
Biofortification was a term officially coined in 2001 and became a formal strategy for nutritional enhancement of staple crops around 2003
The germ fractions contained the highest density of Fe, ranging from 51.0 to 141.3 μg/g
It is notable that the three varieties, M37W, Ki3, and CML333, demonstrating the highest Fe bioavailability had the highest non-germ Fe concentrations: 15.9–18.9 μg/g (Figure 3)
Summary
Biofortification was a term officially coined in 2001 and became a formal strategy for nutritional enhancement of staple crops around 2003 It was at this time that the organization known as HarvestPlus was formed and headquartered at the International Food Policy Research Institute in Washington, DC. The biofortification research objective is to improve human health via enhancement of the nutritional content in staple food crops of the micronutrients vitamin A, zinc (Zn), and iron (Fe). These three micronutrients represent the majority of the “hidden hunger” affecting approximately two billion people worldwide.
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