Manipulation of starch bioaccessibility in wheat endosperm to regulate starch digestion, postprandial glycemia, insulinemia, and gut hormone responses: a randomized controlled trial in healthy ileostomy participants

Edwards, Cathrina H.; Grundy, Myriam M.-L.; Grassby, Terri; Vasilopoulou, Dafni; Frost, Gary; Butterworth, Peter J.; Berry, Sarah; Sanderson, Jeremy; Ellis, Peter R.

doi:10.3945/ajcn.114.106203

Cited by 154 publications

(132 citation statements)

References 47 publications

Supporting

Mentioning

125

Contrasting

Unclassified

Order By: Relevance

“…; Edwards et al . ). Enzymatic treatment and micro‐milling techniques designed to disrupt the aleurone cell walls enhance the release of iron from wheat flour during in vitro digestion and increase iron uptake by intestinal epithelial cells (Latunde‐Dada et al .…”

Section: Post‐harvest Improvements Of Iron and Zinc Bioavailabilitymentioning

confidence: 97%

Improving wheat as a source of iron and zinc for global nutrition

et al. 2019

View full text Add to dashboard Cite

Wheat is the staple food crop in temperate countries and increasingly consumed in developing countries, displacing traditional foods. However, wheat products are typically low in bioavailable iron and zinc, contributing to deficiencies in these micronutrients in countries where wheat is consumed as a staple food. Two factors contribute to the low contents of bioavailable iron and zinc in wheat: the low concentrations of these minerals in white flour, which is most widely consumed, and the presence of phytates in mineral‐rich bran fractions. Although high zinc types of wheat have been developed by conventional plant breeding (biofortification), this approach has failed for iron. However, studies in wheat and other cereals have shown that transgenic (also known as genetically modified; GM ) strategies can be used to increase the contents of iron and zinc in white flour, by converting the starchy endosperm tissue into a ‘sink’ for minerals. Although such strategies currently have low acceptability, greater understanding of the mechanisms which control the transport and deposition of iron and zinc in the developing grain should allow similar effects to be achieved by exploiting naturally induced genetic variation. When combined with conventional biofortification and innovative processing, this approach should provide increased mineral bioavailability in a range of wheat products, from white flour to wholemeal.

show abstract

Section: Post‐harvest Improvements Of Iron and Zinc Bioavailabilitymentioning

confidence: 97%

Improving wheat as a source of iron and zinc for global nutrition

et al. 2019

View full text Add to dashboard Cite

show abstract

“…Barriers, including plant cell wall and protein matrices, prevent or slow down enzyme diffusion to substrate and thus alter the digestion rate. Previous studies have reported a reduction of glycemic responses (C. H. Edwards et al, 2015) and excretion of undigested macronutrients (Ellis et al, 2004;Noah et al, 1998;Tovar, Bjorck, & Asp, 1992) on consumption of whole grains or cooked legumes in humans and rats. The in vitro digestion rate of starch and lipids was reduced due to the intact cell walls (Dhital, Bhattarai, Gorham, & Gidley, 2016;C.…”

Section: Access To Starch Substratementioning

confidence: 97%

High‐Amylose Starches to Bridge the “Fiber Gap”: Development, Structure, and Nutritional Functionality

Gidley

Dhital

2019

Comp Rev Food Sci Food Safe

198

View full text Add to dashboard Cite

Although high‐amylose starches are not a recent innovation, their popularity in recent years has been increasing due to their unique functional properties and enhanced nutritional values in food applications. While high‐amylose maize, barley, and potato are commercially available, high‐amylose variants of other main crops such as wheat and rice have once been developed more recently and will be available commercially in the near future. This review summarizes the development, structure, and nutritional functionality of high‐amylose starches developed and reported so far. The range of biotechnological strategies utilized are reviewed, as are the consequent effects on structural properties at different length scales, as well as sensory aspects of foods containing high‐amylose starch (HAS). This review identifies the molecular and microstructural features contributing to digestive enzyme resistance not only in native HAS but also in forms of relevance to food processing. During heat treatment, HAS tends to retain or form dense molecular structures that resist amylase degradation through the retention of the granular structure as well as helices (type‐2 resistant starch [RS]), reassociation of glucan chains (type‐3 RS), and formation of lipid–amylose complexes (type‐5 RS). The review also identifies opportunities for food manufacturers and consumers to incorporate HAS in food products and diets for better nutritional outcomes.

show abstract

“…; Edwards et al . ). Thus, a combination of physical inaccessibility of minerals encapsulated by plant cell walls, the removal of aleurone during milling, poor bioavailability of currently used fortificants and high levels of inhibitory phytates and phenolic compounds (Hallberg et al .…”

Section: Current Fortification Strategiesmentioning

confidence: 97%

Enhancing mineral bioavailability from cereals: Current strategies and future perspectives

et al. 2018

View full text Add to dashboard Cite

Inadequate intake of essential minerals such as iron and zinc is a public health concern in the UK, particularly for girls and young women. Approximately 30% and 50% of the zinc and iron, respectively, in the UK diet is provided by cereals. In wheat, most of the iron and zinc is contained within the aleurone cell layer; however, aleurone is removed during processing of wheat into white flour. While elemental iron powder is added back into white flour at the milling stage, there is no restoration of zinc. Elemental iron powder has very low bioavailability, and therefore, in our current Biotechnology and Biological Sciences Research Council Diet and Health Research Industry Club‐funded project, we are investigating the potential use of aleurone as a bioavailable source of minerals that could be added to wheat‐based foods. This work has relevance for the food industry and may establish the use of aleurone as a functional food ingredient for fortification of a range of cereal‐based food products.

show abstract

Manipulation of starch bioaccessibility in wheat endosperm to regulate starch digestion, postprandial glycemia, insulinemia, and gut hormone responses: a randomized controlled trial in healthy ileostomy participants

Cited by 154 publications

References 47 publications

Improving wheat as a source of iron and zinc for global nutrition

Improving wheat as a source of iron and zinc for global nutrition

High‐Amylose Starches to Bridge the “Fiber Gap”: Development, Structure, and Nutritional Functionality

Enhancing mineral bioavailability from cereals: Current strategies and future perspectives

Contact Info

Product

Resources

About