Reducing Dietary Acrylamide Exposure from Wheat Products Through Crop Management and Imaging

Overview

Journal J Agric Food Chem

Specialties Chemistry
Nutritional Sciences

Date 2023 Feb 6

PMID 36745538

Authors

Joseph Oddy

John Addy

Andrew Mead

Chris Hall

Chris Mackay

Tom Ashfield

Faye McDiarmid

Tanya Y Curtis

Sarah Raffan

Mark Wilkinson

J Stephen Elmore

Nicholas Cryer

Isabel Moreira de Almeida

Nigel G Halford

Affiliations

Soon will be listed here.

Abstract

The nutritional safety of wheat-based food products is compromised by the presence of the processing contaminant acrylamide. Reduction of the key acrylamide precursor, free (soluble, non-protein) asparagine, in wheat grain can be achieved through crop management strategies, but such strategies have not been fully developed. We ran two field trials with 12 soft (biscuit) wheat varieties and different nitrogen, sulfur, potassium, and phosphorus fertilizer combinations. Our results indicated that a nitrogen-to-sulfur ratio of 10:1 kg/ha was sufficient to prevent large increases in free asparagine, whereas withholding potassium or phosphorus alone did not cause increases in free asparagine when sulfur was applied. Multispectral measurements of plants in the field were able to predict the free asparagine content of grain with an accuracy of 71%, while a combination of multispectral, fluorescence, and morphological measurements of seeds could distinguish high free asparagine grain from low free asparagine grain with an accuracy of 86%. The acrylamide content of biscuits correlated strongly with free asparagine content and with color measurements, indicating that agronomic strategies to decrease free asparagine would be effective and that quality control checks based on product color could eliminate high acrylamide biscuit products.

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