Characterization of Polyphenol Composition and Starch and Protein Structure in Brown Rice Flour, Black Rice Flour and Their Mixtures

The study investigates the structural and chemical properties of brown rice flour (WRF), black rice flour (BRF) and their mixtures in ratios of 25%, 50% and 75% to provide reference information for the gluten-free bakery industry. BRF contains higher concentrations of proteins, lipids, total mineral...

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Bibliographic Details
Published in:Foods 2024-06, Vol.13 (11), p.1592
Main Authors: Uivarasan, Alexandra, Lukinac, Jasmina, Jukić, Marko, Šelo, Gordana, Peter, Anca, Nicula, Camelia, Mihaly Cozmuta, Anca, Mihaly Cozmuta, Leonard
Format: Article
Language:English
Subjects:
amide I band in proteins
Amylose
Analysis
Anthocyanin
Anthocyanins
Antioxidants
Chemical composition
Chemical properties
color analysis
Dietary minerals
Flavonoids
Flour
Food
FTIR spectra deconvolution
Functional foods & nutraceuticals
Glucose
Gluten
Gluten-free diet
Glycemic index
Iodine
Isoflavones
Lipids
Mixtures
Nutritive value
Optical activity
Phenolic acids
Phenols
Pigmentation
Polyphenols
Protein composition
Protein structure
Proteins
reflectance spectra deconvolution
Rice
Spectra
Starch
starch crystallinity
Wavelengths
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Summary:The study investigates the structural and chemical properties of brown rice flour (WRF), black rice flour (BRF) and their mixtures in ratios of 25%, 50% and 75% to provide reference information for the gluten-free bakery industry. BRF contains higher concentrations of proteins, lipids, total minerals, crude fiber, total polyphenols, proanthocyanidins and flavonoids than WRF. A higher amylose content in BRF than in WRF resulted in flour mixtures with slower starch digestion and a lower glycemic response depending on the BRF ratio added. Differences in the chemical composition of WRF and BRF led to improved composition of the flour mixtures depending on the BRF ratio. The presence of anthocyanidins and phenolic acids in higher concentrations in the BRF resulted in a red-blue color shift within the flour mixtures. The deconvoluted FTIR spectra showed a higher proportion of α-helixes in the amide I band of BRF proteins, indicating their tighter folding. An analysis of the FTIR spectra revealed a more compact starch structure in BRF than in WRF. By processing reflection spectra, nine optically active compound groups were distinguished in rice flour, the proportion in BRF being 83.02% higher than in WRF. Due to co-pigmentation, the bathochromic shift to higher wavelengths was expressed by the proanthocyanins and phenolic acids associated with the wavelengths 380 nm to 590 nm and at 695 nm. Anthocyanins, protein-tannin complexes, methylated anthocyanins and acylated anthocyanins, associated with wavelengths 619, 644 and 668 nm, exhibited a hypsochromic effect by shifting the wavelengths to lower values. This research represents a first step in the development of rice-based products with increased nutritional value and a lower glycemic index.
ISSN:2304-8158
2304-8158
DOI:10.3390/foods13111592