Alterations of selenium level and speciation during milling and cooking in different wheat cultivars.

BACKGROUND: Selenium (Se) deficiency is a recognized problem that threatens the health of people worldwide, and wheat is grown worldwide and is one of the major sources of dietary Se. Since there are few studies that have investigated the changes in Se content and speciation of different varieties of Se-enriched wheat from primary to deep processing, we studied four naturally Se-enriched kinds of wheat and two Se-fertilized kinds of wheat. RESULTS: Glutenin- and albumin-bound Se accounted for the highest proportion of protein-bound Se in refined wheat flour (7.29 ± 0.19 to 10.82 ± 0.50% and 6.16 ± 0.34 to 8.45 ± 0.07%); water-soluble polysaccharide-bound Se accounted for the highest proportion of polysaccharide-bound Se in refined wheat flour (12.02 ± 0.54 to 24.62 ± 1.87%). Coarse bran Se content was significantly higher than refined wheat flour (137.94 ± 7.80 to 174.55 ± 5.09% for unpeeled wheat, 147.27 ± 10.96 to 187.72 ± 17.70% for peeled wheat). The peeling and processing of wheat into flour had different effects on Se the content and speciation dependent on the particular wheat variety. Whole wheat flour enabled better retention of selenomethionine (101.64 ± 2.32 to 138.41 ± 2.84% for unpeeled wheat, 158.59 ± 13.72 to 250.20 ± 4.94% for peeled wheat). The cooking process had no significant effect on Se content, but Se species were possibly interconverted. CONCLUSION: The organic Se content of different varieties of Se-enriched wheat was different, but the milling and cooking process retained the total Se and Se speciation better, which could be used for daily Se supplementation for Se-deficient people. © 2022 Society of Chemical Industry.

Analysis and Research on Starch Content and Its Processing, Structure and Quality of 12 Adzuki Bean Varieties.

Investigating starch properties of different adzuki beans provides an important theoretical basis for its application. A comparative study was conducted to evaluate the starch content, processing, digestion, and structural quality of 12 adzuki bean varieties. The variation ranges of the 12 adzuki bean varieties with specific analyzed parameters, including the amylose/amylopectin (AM/AP) ratio, bean paste rate, water separation rate, solubility, swelling power and resistant starch (RS) content level, were 5.52-39.05%, 44.7-68.2%, 45.56-54.29%, 6.79-12.07%, 11.83-15.39%, and 2.02-14.634%, respectively. The crystallinity varied from 20.92 to 37.38%, belonging to type BC(The starch crystal type is mainly type C, supplemented by type B). In correlation analysis, red and blue represent positive and negative correlation, respectively. Correlation analysis indicated that the termination temperature of adzuki bean starch was positively correlated with AM/AP ratio. Therefore, the higher the melting temperature, the better the freeze-thaw stability. The 12 varieties were divided into Class I, Class II, and Class III by cluster analysis, based on application field. Class I was unsuitable for the diabetics' diet; Class II was suitable for a stabilizer; and Class III was suitable for bean paste, mixtures, and thickeners. The present study could provide a theoretical basis for their application in the nutritional and nutraceutical field.

Release and conformational changes in allergenic proteins from wheat gluten induced by high hydrostatic pressure.

The gluten proteins of wheat are major causative agents of harmful immune responses. This study investigated the effects of high hydrostatic pressure (200, 300, 400, and 500 MPa), treatment time (5-25 min) and protein concentration (1%-5% protein weight/volume) on the structures underlying the allergenicity wheat gluten. The results showed that a combination of 400 MPa, 20 min treatment time and 3% protein reduced the wheat gluten allergenicity by 72.2%. Moreover, a Western blotting showed that the allergenicity of 26, 28, 48, 68 kDa and high molecular weight glutenin was sharply reduced. Fourier infrared spectroscopy and surface hydrophobicity indicated that gluten molecules aggregated after HHP treatment. Intermolecular forces indicated that gluten aggregated mainly through hydrophobic interactions and disulfide bonds but not by hydrogen bonds after HHP treatment. These results suggest that structural changes contributed to the reduction of wheat gluten allergenicity and that HHP may enhance safety for susceptible individuals.