High-pressure processing enhances konjac glucomannan/zeaxanthin complex interactions: Implications for colorful plant-based gels

This study investigates the effects of high-pressure processing (HPP) on the physicochemical and structural properties of konjac glucomannan (KGM)/zeaxanthin (ZEA) composite-colored gel. Gels treated with varying pressures and holding times were analyzed, with untreated samples serving as the contro...

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Published inFood chemistry Vol. 484; p. 144356
Main Authors Wang, Ya, Ren, Hongfei, Sun, Xiaohua, Zhan, Ziyi, Zhang, Fusheng
Format Journal Article
LanguageEnglish
Published England Elsevier Ltd 30.08.2025
Subjects
Amorphophallus
Amorphophallus - chemistry
chewiness
crystal structure
enthalpy
food chemistry
Food Handling - instrumentation
Food Handling - methods
gels
Gels - chemistry
hardness
High-pressure processing
hydrogen
Hydrogen bonding
Hydrophobic interactions
hydrophobicity
Konjac glucomannan
konjac mannan
Mannans - chemistry
Plant Extracts - chemistry
Plant-based gels
Pressure
spectral analysis
thermal stability
water holding capacity
Xanthophylls - chemistry
Zeaxanthin
Konjac glucomannan
Zeaxanthin
Plant-based gels
Hydrophobic interactions
High-pressure processing
Hydrogen bonding
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Abstract This study investigates the effects of high-pressure processing (HPP) on the physicochemical and structural properties of konjac glucomannan (KGM)/zeaxanthin (ZEA) composite-colored gel. Gels treated with varying pressures and holding times were analyzed, with untreated samples serving as the control. The results indicate that HPP at 300 MPa for 15 min significantly improved pigment retention and water-holding capacity by 14.58 % and 1.02 %, respectively, while also enhancing gel hardness and chewiness. Structural analysis revealed that HPP increased enthalpy change (ΔH) and relative crystallinity by 44.83 % and 20.32 %, respectively, contributing to improved thermal stability. Spectroscopic analysis further confirmed that HPP strengthened hydrophobic and hydrogen bonding interactions within the complex, leading to the formation of a denser three-dimensional network structure. These findings highlight the potential of HPP as an effective approach to improve the stability and functionality of plant-based colored gels, providing valuable insights for the development of functional konjac gel products. [Display omitted] •HPP enhances ZEA retention and color stability in KGM gel.•Enhanced thermal and crystalline properties improve gel stability.•HPP promotes ordered aggregation and network densification of gel structure.•Hydrogen bonding and hydrophobic interaction reinforces gel structural stability.•The findings provide new insights to develop colorful plant-based foods.
AbstractList This study investigates the effects of high-pressure processing (HPP) on the physicochemical and structural properties of konjac glucomannan (KGM)/zeaxanthin (ZEA) composite-colored gel. Gels treated with varying pressures and holding times were analyzed, with untreated samples serving as the control. The results indicate that HPP at 300 MPa for 15 min significantly improved pigment retention and water-holding capacity by 14.58 % and 1.02 %, respectively, while also enhancing gel hardness and chewiness. Structural analysis revealed that HPP increased enthalpy change (ΔH) and relative crystallinity by 44.83 % and 20.32 %, respectively, contributing to improved thermal stability. Spectroscopic analysis further confirmed that HPP strengthened hydrophobic and hydrogen bonding interactions within the complex, leading to the formation of a denser three-dimensional network structure. These findings highlight the potential of HPP as an effective approach to improve the stability and functionality of plant-based colored gels, providing valuable insights for the development of functional konjac gel products. [Display omitted] •HPP enhances ZEA retention and color stability in KGM gel.•Enhanced thermal and crystalline properties improve gel stability.•HPP promotes ordered aggregation and network densification of gel structure.•Hydrogen bonding and hydrophobic interaction reinforces gel structural stability.•The findings provide new insights to develop colorful plant-based foods.
This study investigates the effects of high-pressure processing (HPP) on the physicochemical and structural properties of konjac glucomannan (KGM)/zeaxanthin (ZEA) composite-colored gel. Gels treated with varying pressures and holding times were analyzed, with untreated samples serving as the control. The results indicate that HPP at 300 MPa for 15 min significantly improved pigment retention and water-holding capacity by 14.58 % and 1.02 %, respectively, while also enhancing gel hardness and chewiness. Structural analysis revealed that HPP increased enthalpy change (ΔH) and relative crystallinity by 44.83 % and 20.32 %, respectively, contributing to improved thermal stability. Spectroscopic analysis further confirmed that HPP strengthened hydrophobic and hydrogen bonding interactions within the complex, leading to the formation of a denser three-dimensional network structure. These findings highlight the potential of HPP as an effective approach to improve the stability and functionality of plant-based colored gels, providing valuable insights for the development of functional konjac gel products.This study investigates the effects of high-pressure processing (HPP) on the physicochemical and structural properties of konjac glucomannan (KGM)/zeaxanthin (ZEA) composite-colored gel. Gels treated with varying pressures and holding times were analyzed, with untreated samples serving as the control. The results indicate that HPP at 300 MPa for 15 min significantly improved pigment retention and water-holding capacity by 14.58 % and 1.02 %, respectively, while also enhancing gel hardness and chewiness. Structural analysis revealed that HPP increased enthalpy change (ΔH) and relative crystallinity by 44.83 % and 20.32 %, respectively, contributing to improved thermal stability. Spectroscopic analysis further confirmed that HPP strengthened hydrophobic and hydrogen bonding interactions within the complex, leading to the formation of a denser three-dimensional network structure. These findings highlight the potential of HPP as an effective approach to improve the stability and functionality of plant-based colored gels, providing valuable insights for the development of functional konjac gel products.
This study investigates the effects of high-pressure processing (HPP) on the physicochemical and structural properties of konjac glucomannan (KGM)/zeaxanthin (ZEA) composite-colored gel. Gels treated with varying pressures and holding times were analyzed, with untreated samples serving as the control. The results indicate that HPP at 300 MPa for 15 min significantly improved pigment retention and water-holding capacity by 14.58 % and 1.02 %, respectively, while also enhancing gel hardness and chewiness. Structural analysis revealed that HPP increased enthalpy change (ΔH) and relative crystallinity by 44.83 % and 20.32 %, respectively, contributing to improved thermal stability. Spectroscopic analysis further confirmed that HPP strengthened hydrophobic and hydrogen bonding interactions within the complex, leading to the formation of a denser three-dimensional network structure. These findings highlight the potential of HPP as an effective approach to improve the stability and functionality of plant-based colored gels, providing valuable insights for the development of functional konjac gel products.
This study investigates the effects of high-pressure processing (HPP) on the physicochemical and structural properties of konjac glucomannan (KGM)/zeaxanthin (ZEA) composite-colored gel. Gels treated with varying pressures and holding times were analyzed, with untreated samples serving as the control. The results indicate that HPP at 300 MPa for 15 min significantly improved pigment retention and water-holding capacity by 14.58 % and 1.02 %, respectively, while also enhancing gel hardness and chewiness. Structural analysis revealed that HPP increased enthalpy change (ΔH) and relative crystallinity by 44.83 % and 20.32 %, respectively, contributing to improved thermal stability. Spectroscopic analysis further confirmed that HPP strengthened hydrophobic and hydrogen bonding interactions within the complex, leading to the formation of a denser three-dimensional network structure. These findings highlight the potential of HPP as an effective approach to improve the stability and functionality of plant-based colored gels, providing valuable insights for the development of functional konjac gel products.
ArticleNumber 144356
Author Wang, Ya
Ren, Hongfei
Sun, Xiaohua
Zhang, Fusheng
Zhan, Ziyi
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  fullname: Ren, Hongfei
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  organization: College of Food Science, Southwest University, Chongqing 400715, China
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Keywords Konjac glucomannan
Zeaxanthin
Plant-based gels
Hydrophobic interactions
High-pressure processing
Hydrogen bonding
Language English
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Snippet This study investigates the effects of high-pressure processing (HPP) on the physicochemical and structural properties of konjac glucomannan (KGM)/zeaxanthin...
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SubjectTerms Amorphophallus
Amorphophallus - chemistry
chewiness
crystal structure
enthalpy
food chemistry
Food Handling - instrumentation
Food Handling - methods
gels
Gels - chemistry
hardness
High-pressure processing
hydrogen
Hydrogen bonding
Hydrophobic interactions
hydrophobicity
Konjac glucomannan
konjac mannan
Mannans - chemistry
Plant Extracts - chemistry
Plant-based gels
Pressure
spectral analysis
thermal stability
water holding capacity
Xanthophylls - chemistry
Zeaxanthin
Title High-pressure processing enhances konjac glucomannan/zeaxanthin complex interactions: Implications for colorful plant-based gels
URI https://dx.doi.org/10.1016/j.foodchem.2025.144356
https://www.ncbi.nlm.nih.gov/pubmed/40267683
https://www.proquest.com/docview/3194255711
https://www.proquest.com/docview/3242044880
Volume 484
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