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Iron availability of a fortified processed wheat cereal: a comparison of fourteen iron forms using an in vitro digestion/human colonic adenocarcinoma (CaCo-2) cell model

Published online by Cambridge University Press:  08 March 2007

Gary Wortley ,
Steven Leusner ,
Carolyn Good ,
Eric Gugger  and
Raymond Glahn
Gary Wortley
Affiliation:
The Institute of Food Research, Norwich Research Park, Colney, Norwich, NR4 7UA, UK
Steven Leusner
Affiliation:
Ottens Flavors, 7800 Holstein Avenue, Philadelphia, PA 19153, USA
Carolyn Good
Affiliation:
General Mills, Bell Institute of Health & Nutrition, 9000 Plymouth Avenue North, Minneapolis, MN 55427, USA
Eric Gugger
Affiliation:
General Mills, Bell Institute of Health & Nutrition, 9000 Plymouth Avenue North, Minneapolis, MN 55427, USA
Raymond Glahn*
Affiliation:
US Department of Agriculture – Agricultural Research Service, US Plant, Soil & Nutrition Laboratory, Tower Road, Ithaca, NY 14853, USA
*
*Corresponding author: Dr R. Glahn, fax +1 607 2551132, email [email protected]
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Abstract

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In this three-phase study we first compared the availability of fourteen Fe forms in a wheat-based ready-to-eat breakfast cereal using an in vitro digestion/human colonic adenocarcinoma (CaCo-2) cell model. We then investigated the effect of milk and/or coffee on those fortified cereals found in phase 1 to show promising increases in Fe availability. The Fe forms assessed in phase 1 were reduced (control), carbonyl, electrolytic, FePO4, FeSO4, FeCO3, Na2FeEDTA, Ferrochel® (Albion Laboratories, Clearfield, UT, USA; ferrous bis-glycinate), encapsulated ferrous fumarate, FeSO4, ferrous lactate and Biofer® (LipoTech, Britwell Salome, Oxfordshire; FeSO4), SQM® (Sea-Questra-Min Iron; Quali Tech, Chaska, MN, USA; polysaccharide-complexed FeSO4) and Sun Active® (Taiyo Kagaku, Yokkaichi, Japan). All these forms increased Fe uptake compared with the unfortified cereal. Relative to the control, the following increases in Fe availability were observed: electrolytic, 52 %; ferrous fumarate, 30–35 %; Sun Active, 78 %; Ferrochel, 125 %; Na2FeEDTA, 291 %. Recent human studies have shown similar data with regard to Ferrochel, FeSO4 and Na2FeEDTA, with the latter being more bioavailable. Our phase-2 studies indicated that the addition of milk to FeSO4-fortified cereal increased Fe availability, but this availability was markedly decreased by the addition of coffee to the digest. Conversely, a loss in availability from Na2FeEDTA was observed with the addition of milk; however, the addition of coffee did not markedly affect Fe availability from this form. In phase-3 studies we observed increased Fe availability upon the addition of milk to cereals containing Ferrochel, FeSO4, Sun Active, a mixture of reduced Fe and Na2FeEDTA or reduced Fe. For these forms we did not assess the behaviour after the addition of coffee. In conclusion, when considering possible fortificants for optimizing Fe bioavailability within a foodstuff, it is of paramount importance to consider the interaction between the fortified foodstuffs and other components of the meal (such as milk and coffee with a breakfast).

Keywords

Iron availabilityIn vitro digestionCaCo-2Wheat cerealsIron fortification
Type
Research Article
Information
British Journal of Nutrition , Volume 93 , Issue 1 , January 2005 , pp. 65 - 71
Copyright
Copyright © The Nutrition Society 2005

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