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Effect of high‐pressure homogenization on Ca<sup>2+</sup>‐induced gel formation of soybean <scp>11 S</scp> globulin

Bingyu Sun, Xuelian Gu, Fengqiujie Wang, Linlin Liu, Yuyang Huang, Yuan Gao, Mingshou Lü, Ying Zhu, Yanguo Shi, Xiuqing Zhu

2022Journal of the Science of Food and Agriculture12 citationsDOI

Abstract

Abstract Background High‐pressure homogenization (HPH) is commonly used as a non‐thermal processing technique for soybean and soy protein products, and the preparation of soy protein gel products often requires the synergistic effect of HPH and heat treatment. The dissociative association behavior of 11 S is the key to the protein gel formation state. In this study, therefore, 11 S thermal gels were prepared by high‐pressure homogenization and co‐induction (90 °C, 30 min) (adding Ca 2+ to promote gel formation before heat treatment), and the effects of different high‐pressure homogenization pressures (0–100 MPa) and co‐treatment on the dissociative association behavior of 11 S protein, gel properties, and microstructure of 11 S gels were investigated. Results The results showed that HPH at higher pressures led to the breaking of disulfide bonds of aggregates and disrupted non‐covalent interactions in protein aggregates, leading to collisions between protein aggregates and the reduction of large protein aggregates. High‐pressure homogenization treatment at 60 MPa improved the gel properties of 11 S more. The HPH combined with heating changed the binary and tertiary structure of 11 S soy globulin and enhanced the hydrophobic interaction between 11 S molecules, thus improving the gel properties of 11 S. The change in intermolecular forces reflected the positive effect of HPH treatment on the formation of denser and more homogeneous protein gels. Conclusion In conclusion, high‐pressure homogenization combined with heating can improve the properties of 11 S gels by changing the structure of 11 S protein, providing data and theoretical support for soy protein processing and its further applications. © 2022 Society of Chemical Industry.

Topics & Concepts

Homogenization (climate)ChemistrySoy proteinCovalent bondMicrostructureSoybean ProteinsChromatographyChemical engineeringHomogeneousHigh pressureDisulfide bondBiophysicsCrystallographyOrganic chemistryFood scienceBiochemistryThermodynamicsPhysicsEngineeringBiologyEcologyBiodiversityProteins in Food SystemsMicrobial Inactivation MethodsProtein Hydrolysis and Bioactive Peptides