Peptide gelation contributes to the tenderness and viscoelasticity of candy abalone

Dried abalones are precious products, in which candy abalone is the most treasured one, owing to its unique taste. After rehydration and simmering, the core part tastes extraordinarily tender and viscoelastic, just like a soft candy which may almost melt in mouth. However, the reason for this has ye...

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Veröffentlicht in:	European food research & technology 2024-06, Vol.250 (6), p.1865-1879
Hauptverfasser:	Mo, Yaxian, Ma, Jiaqi, Zhang, Xinyu, Zhao, Guanghua, Zang, Jiachen
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Sprache:	eng
Schlagworte:	Agriculture Analytical Chemistry Biotechnology Chemistry Chemistry and Materials Science Confectionery Drying Electrophoresis Food Science Forestry Hydrogels Hydrogen bonding Hydrogen bonds Hydrophobicity Mass spectrometry Mass spectroscopy Molecular dynamics Original Paper Peptides Polyacrylamide Proteins Rehydration Rheological properties Self-assembly Sodium dodecyl sulfate Sodium lauryl sulfate Transmission electron microscopy Viscoelasticity
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description	Dried abalones are precious products, in which candy abalone is the most treasured one, owing to its unique taste. After rehydration and simmering, the core part tastes extraordinarily tender and viscoelastic, just like a soft candy which may almost melt in mouth. However, the reason for this has yet to be elucidated. The purpose of this study is to research the formation mechanism of the candy-like core in candy abalone. First of all, we characterized the viscoelasticity, microstructure and protein changes of candy abalone during the simmering process. The texture results indicated that the springiness and adhesiveness of candy abalone showed an increase. Scanning and transmission electron microscopy suggested that myofibrillar protein in candy abalone formed a dense three-dimensional network hydrogel structure. Sodium dodecyl sulfate–polyacrylamide gel electrophoresis revealed such a hydrogel structure might be derived from the degradation of the myofibrillar protein during the drying process. Also, we identified degraded peptides mainly stemmed from paramyosin by mass spectrometry. Moreover, molecular dynamics simulation revealed that the hydrogen bonds and hydrophobic interactions are mainly responsible for the self-assembly of peptides during the rehydration and simmering stages. Different from reported protein hydrogels, the rheological and morphological properties of the formed peptide hydrogels in candy abalone have significant changes. In this study, we found that the myofibrillar protein of fresh abalone degraded into peptides during the drying process, which further cross-linked to form a peptide hydrogel during the rehydration and simmering stages, thereby producing a unique viscoelastic candy-like core in candy abalone. Graphical abstract
doi_str_mv	10.1007/s00217-024-04523-x
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After rehydration and simmering, the core part tastes extraordinarily tender and viscoelastic, just like a soft candy which may almost melt in mouth. However, the reason for this has yet to be elucidated. The purpose of this study is to research the formation mechanism of the candy-like core in candy abalone. First of all, we characterized the viscoelasticity, microstructure and protein changes of candy abalone during the simmering process. The texture results indicated that the springiness and adhesiveness of candy abalone showed an increase. Scanning and transmission electron microscopy suggested that myofibrillar protein in candy abalone formed a dense three-dimensional network hydrogel structure. Sodium dodecyl sulfate–polyacrylamide gel electrophoresis revealed such a hydrogel structure might be derived from the degradation of the myofibrillar protein during the drying process. Also, we identified degraded peptides mainly stemmed from paramyosin by mass spectrometry. Moreover, molecular dynamics simulation revealed that the hydrogen bonds and hydrophobic interactions are mainly responsible for the self-assembly of peptides during the rehydration and simmering stages. Different from reported protein hydrogels, the rheological and morphological properties of the formed peptide hydrogels in candy abalone have significant changes. In this study, we found that the myofibrillar protein of fresh abalone degraded into peptides during the drying process, which further cross-linked to form a peptide hydrogel during the rehydration and simmering stages, thereby producing a unique viscoelastic candy-like core in candy abalone. 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subjects	Agriculture Analytical Chemistry Biotechnology Chemistry Chemistry and Materials Science Confectionery Drying Electrophoresis Food Science Forestry Hydrogels Hydrogen bonding Hydrogen bonds Hydrophobicity Mass spectrometry Mass spectroscopy Molecular dynamics Original Paper Peptides Polyacrylamide Proteins Rehydration Rheological properties Self-assembly Sodium dodecyl sulfate Sodium lauryl sulfate Transmission electron microscopy Viscoelasticity
title	Peptide gelation contributes to the tenderness and viscoelasticity of candy abalone
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