Milling of buckwheat hull to cell-scale: Influences on the behaviors of protein and starch in dough and noodles

[Display omitted] •Cell-scale fiber increased protein aggregation and starch gelatinization rate.•Cell-scale fiber decreased gluten malleability and starch thermal stability.•Fiber addition weakened the interaction between water and macromolecules.•Cell- and tissue-scale fiber differently affected s...

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Published inFood chemistry Vol. 423; p. 136347
Main Authors Wang, Lijuan, Tang, Hanqi, Li, Yang, Guo, Zicong, Zou, Liang, Li, Zaigui, Qiu, Ju
Format Journal Article
LanguageEnglish
Published England Elsevier Ltd 15.10.2023
Subjects
Buckwheat
Cooking
deformation
dietary fiber
dough
Fagopyrum - chemistry
Flour - analysis
food chemistry
gelatinization
gluten
Glutens - chemistry
Insoluble dietary fiber
Noodle quality
noodles
Particle size
product quality
Protein structure
rheology
starch
Starch - chemistry
texture
viscoelasticity
LF-NMR
Particle size
DF
TPA
tan δ
Buckwheat
G
IDF
WA
C1–C2
C3–C4
C3–C2
C5–C4
β
Insoluble dietary fiber
SDF
FTIR
SEM
CLSM
Protein structure
WAI
Noodle quality
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Abstract [Display omitted] •Cell-scale fiber increased protein aggregation and starch gelatinization rate.•Cell-scale fiber decreased gluten malleability and starch thermal stability.•Fiber addition weakened the interaction between water and macromolecules.•Cell- and tissue-scale fiber differently affected spatial orderliness of protein.•Milling fiber to cell scale was conducive to improve the dough and noodle quality. Superfine grinding of insoluble dietary fiber (IDF) is a promising method to improve the product quality by regulating the interaction between protein and starch. In this study, the effects of buckwheat-hull IDF powder, at cell-scale (50–10 μm) and tissue-scale (500–100 μm), on the dough rheology and noodle quality were investigated. Results showed that cell-scale IDF with higher exposure of active groups increased the viscoelasticity and deformation resistance of the dough, due to the aggregation of protein–protein and protein-IDF. Compared with the control sample, the addition of tissue-scale or cell-scale IDF significantly increased the starch gelatinization rate (β, C3-C2) and decreased the starch hot-gel stability. Cell-scale IDF increased the rigid structure (β-sheet) of protein, thus improving the noodle texture. The decreased cooking quality of cell-scale IDF-fortified noodles was related to the poor stability of rigid gluten matrix and the weakened interaction between water and macromolecules (starch and protein) during cooking.
AbstractList Superfine grinding of insoluble dietary fiber (IDF) is a promising method to improve the product quality by regulating the interaction between protein and starch. In this study, the effects of buckwheat-hull IDF powder, at cell-scale (50–10 μm) and tissue-scale (500–100 μm), on the dough rheology and noodle quality were investigated. Results showed that cell-scale IDF with higher exposure of active groups increased the viscoelasticity and deformation resistance of the dough, due to the aggregation of protein–protein and protein-IDF. Compared with the control sample, the addition of tissue-scale or cell-scale IDF significantly increased the starch gelatinization rate (β, C3-C2) and decreased the starch hot-gel stability. Cell-scale IDF increased the rigid structure (β-sheet) of protein, thus improving the noodle texture. The decreased cooking quality of cell-scale IDF-fortified noodles was related to the poor stability of rigid gluten matrix and the weakened interaction between water and macromolecules (starch and protein) during cooking.
[Display omitted] •Cell-scale fiber increased protein aggregation and starch gelatinization rate.•Cell-scale fiber decreased gluten malleability and starch thermal stability.•Fiber addition weakened the interaction between water and macromolecules.•Cell- and tissue-scale fiber differently affected spatial orderliness of protein.•Milling fiber to cell scale was conducive to improve the dough and noodle quality. Superfine grinding of insoluble dietary fiber (IDF) is a promising method to improve the product quality by regulating the interaction between protein and starch. In this study, the effects of buckwheat-hull IDF powder, at cell-scale (50–10 μm) and tissue-scale (500–100 μm), on the dough rheology and noodle quality were investigated. Results showed that cell-scale IDF with higher exposure of active groups increased the viscoelasticity and deformation resistance of the dough, due to the aggregation of protein–protein and protein-IDF. Compared with the control sample, the addition of tissue-scale or cell-scale IDF significantly increased the starch gelatinization rate (β, C3-C2) and decreased the starch hot-gel stability. Cell-scale IDF increased the rigid structure (β-sheet) of protein, thus improving the noodle texture. The decreased cooking quality of cell-scale IDF-fortified noodles was related to the poor stability of rigid gluten matrix and the weakened interaction between water and macromolecules (starch and protein) during cooking.
Superfine grinding of insoluble dietary fiber (IDF) is a promising method to improve the product quality by regulating the interaction between protein and starch. In this study, the effects of buckwheat-hull IDF powder, at cell-scale (50-10 μm) and tissue-scale (500-100 μm), on the dough rheology and noodle quality were investigated. Results showed that cell-scale IDF with higher exposure of active groups increased the viscoelasticity and deformation resistance of the dough, due to the aggregation of protein-protein and protein-IDF. Compared with the control sample, the addition of tissue-scale or cell-scale IDF significantly increased the starch gelatinization rate (β, C3-C2) and decreased the starch hot-gel stability. Cell-scale IDF increased the rigid structure (β-sheet) of protein, thus improving the noodle texture. The decreased cooking quality of cell-scale IDF-fortified noodles was related to the poor stability of rigid gluten matrix and the weakened interaction between water and macromolecules (starch and protein) during cooking.Superfine grinding of insoluble dietary fiber (IDF) is a promising method to improve the product quality by regulating the interaction between protein and starch. In this study, the effects of buckwheat-hull IDF powder, at cell-scale (50-10 μm) and tissue-scale (500-100 μm), on the dough rheology and noodle quality were investigated. Results showed that cell-scale IDF with higher exposure of active groups increased the viscoelasticity and deformation resistance of the dough, due to the aggregation of protein-protein and protein-IDF. Compared with the control sample, the addition of tissue-scale or cell-scale IDF significantly increased the starch gelatinization rate (β, C3-C2) and decreased the starch hot-gel stability. Cell-scale IDF increased the rigid structure (β-sheet) of protein, thus improving the noodle texture. The decreased cooking quality of cell-scale IDF-fortified noodles was related to the poor stability of rigid gluten matrix and the weakened interaction between water and macromolecules (starch and protein) during cooking.
Superfine grinding of insoluble dietary fiber (IDF) is a promising method to improve the product quality by regulating the interaction between protein and starch. In this study, the effects of buckwheat-hull IDF powder, at cell-scale (50-10 μm) and tissue-scale (500-100 μm), on the dough rheology and noodle quality were investigated. Results showed that cell-scale IDF with higher exposure of active groups increased the viscoelasticity and deformation resistance of the dough, due to the aggregation of protein-protein and protein-IDF. Compared with the control sample, the addition of tissue-scale or cell-scale IDF significantly increased the starch gelatinization rate (β, C3-C2) and decreased the starch hot-gel stability. Cell-scale IDF increased the rigid structure (β-sheet) of protein, thus improving the noodle texture. The decreased cooking quality of cell-scale IDF-fortified noodles was related to the poor stability of rigid gluten matrix and the weakened interaction between water and macromolecules (starch and protein) during cooking.
ArticleNumber 136347
Author Tang, Hanqi
Qiu, Ju
Guo, Zicong
Li, Yang
Li, Zaigui
Zou, Liang
Wang, Lijuan
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Keywords LF-NMR
Particle size
DF
TPA
tan δ
Buckwheat
G
IDF
WA
C1–C2
C3–C4
C3–C2
C5–C4
β
Insoluble dietary fiber
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Noodle quality
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Snippet [Display omitted] •Cell-scale fiber increased protein aggregation and starch gelatinization rate.•Cell-scale fiber decreased gluten malleability and starch...
Superfine grinding of insoluble dietary fiber (IDF) is a promising method to improve the product quality by regulating the interaction between protein and...
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StartPage 136347
SubjectTerms Buckwheat
Cooking
deformation
dietary fiber
dough
Fagopyrum - chemistry
Flour - analysis
food chemistry
gelatinization
gluten
Glutens - chemistry
Insoluble dietary fiber
Noodle quality
noodles
Particle size
product quality
Protein structure
rheology
starch
Starch - chemistry
texture
viscoelasticity
Title Milling of buckwheat hull to cell-scale: Influences on the behaviors of protein and starch in dough and noodles
URI https://dx.doi.org/10.1016/j.foodchem.2023.136347
https://www.ncbi.nlm.nih.gov/pubmed/37207513
https://www.proquest.com/docview/2816765193
https://www.proquest.com/docview/3154150142
Volume 423
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