Efficacy of iron-biofortified crops

Biofortification aims to increase the content of micronutrients in staple crops without sacrificing agronomic yield, making the new varieties attractive to farmers. Food staples that provide a major energy supply in low- and middle-income populations are the primary focus. The low genetic variability of iron in the germplasm of most cereal grains is a major obstacle on the path towards nutritional impact with these crops, which is solvable only by turning to transgenic approaches. However, biofortified varieties of common beans and pearl millet have been developed successfully and made available with iron contents as high as 100 mg/kg and 80 mg/kg, respectively, two to five times greater than the levels in the regular varieties. This brief review summarizes the research to date on the bioavailability and efficacy of iron-biofortified crops, highlights their potential and limitations, and discusses the way forward with multiple biofortified crop approaches suitable for diverse cultures and socio-economic milieu. Like post-harvest iron fortification, these biofortified combinations might provide enough iron to meet the additional iron needs of many iron deficient women and children that are not covered at present by their traditional diets. Keywords: Biofortification, Iron, Beans, Pearl millet, Rice, Polyphenols, Phytic acid, Anemia, Efficacy, Nutrition-Agriculture linkages

[1]  Sarah Luna,et al.  The Effects Of Iron-Biofortified Beans On Iron Status, Physical Performance, And Physical Activity In Rwandan Women , 2015 .

[2]  I. Egli,et al.  Phytic acid concentration influences iron bioavailability from biofortified beans in Rwandese women with low iron status. , 2014, The Journal of nutrition.

[3]  I. Egli,et al.  Genetic reduction of phytate in common bean (Phaseolus vulgaris L.) seeds increases iron absorption in young women. , 2013, The Journal of nutrition.

[4]  Erick Boy,et al.  Stable iron isotope studies in Rwandese women indicate that the common bean has limited potential as a vehicle for iron biofortification. , 2012, The Journal of nutrition.

[5]  I. Egli,et al.  Polyphenols and phytic acid contribute to the low iron bioavailability from common beans in young women. , 2010, The Journal of nutrition.

[6]  J. Laparra,et al.  Bioaccessibility of phenols in common beans ( Phaseolus vulgaris L.) and iron (Fe) availability to Caco-2 cells. , 2008, Journal of agricultural and food chemistry.

[7]  L. Murray-Kolb,et al.  Iron absorption prediction equations lack agreement and underestimate iron absorption. , 2007, The Journal of nutrition.

[8]  B. Mcclafferty,et al.  From Harvest to Health: Challenges for Developing Biofortified Staple Foods and Determining Their Impact on Micronutrient Status , 2007, Food and nutrition bulletin.

[9]  R. Hurrell,et al.  Chili, but not turmeric, inhibits iron absorption in young women from an iron-fortified composite meal. , 2006, The Journal of nutrition.

[10]  E. Ategbo Food and nutrition insecurity in northern Benin : impact on growth performance of children and on year to year nutritional status of adults , 1993 .

[11]  M Brune,et al.  Iron absorption and phenolic compounds: importance of different phenolic structures. , 1989, European journal of clinical nutrition.