Selenium Concentration and Speciation in Biofortified Flour and Bread: Retention of Selenium During Grain Biofortification, Processing and Production of Se-enriched Food

Overview

Journal Food Chem

Specialties Chemistry
Nutritional Sciences

Date 2014 Sep 13

PMID 25213956

Citations 21

Authors

D J Hart

S J Fairweather-Tait

M R Broadley

S J Dickinson

I Foot

P Knott

S P McGrath

H Mowat

K Norman

P R Scott

J L Stroud

M Tucker

P J White

F J Zhao

R Hurst

Affiliations

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Abstract

The retention and speciation of selenium in flour and bread was determined following experimental applications of selenium fertilisers to a high-yielding UK wheat crop. Flour and bread were produced using standard commercial practices. Total selenium was measured using inductively coupled plasma-mass spectrometry (ICP-MS) and the profile of selenium species in the flour and bread were determined using high performance liquid chromatography (HPLC) ICP-MS. The selenium concentration of flour ranged from 30ng/g in white flour and 35ng/g in wholemeal flour from untreated plots up to >1800ng/g in white and >2200ng/g in wholemeal flour processed from grain treated with selenium (as selenate) at the highest application rate of 100g/ha. The relationship between the amount of selenium applied to the crop and the amount of selenium in flour and bread was approximately linear, indicating minimal loss of Se during grain processing and bread production. On average, application of selenium at 10g/ha increased total selenium in white and wholemeal bread by 155 and 185ng/g, respectively, equivalent to 6.4 and 7.1μg selenium per average slice of white and wholemeal bread, respectively. Selenomethionine accounted for 65-87% of total extractable selenium species in Se-enriched flour and bread; selenocysteine, Se-methylselenocysteine selenite and selenate were also detected. Controlled agronomic biofortification of wheat crops for flour and bread production could provide an appropriate strategy to increase the intake of bioavailable selenium.

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