4.7 Article

Effects of globular and flexible structures on the emulsifying and interfacial properties of mixed soy proteins

期刊

FOOD HYDROCOLLOIDS
卷 127, 期 -, 页码 -

出版社

ELSEVIER SCI LTD
DOI: 10.1016/j.foodhyd.2022.107539

关键词

Soy protein; Emulsion; Structure; Interfacial shear rheology; Stability

资金

  1. National Natural Sci-ence Foundation of China [31901818]
  2. Open Project Pro-gram of State Key Laboratory of Food Science and Technology, Jiangnan University [SKLF-KF-201910]

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In a mixed protein system, the composition and conformation of different proteins affect the emulsifying and interfacial properties. This study investigated the structural and functional properties of mixed proteins using fi-conglycinin and hydrolysates of glycinin (GH) as representative proteins. The results showed that as the GH content increased, the amount of fi-sheet decreased while a-helix, fi-turn, and random coil contents increased. In addition, the elastic modulus decreased and the linear viscoelastic region (LVR) slightly increased with increasing GH content. The mixed soy proteins exhibited lower deformation and the optimal emulsion was formed with a ratio of 1:1 (GH-50%).
In mixed protein system, the emulsifying and interfacial properties are affected by the composition and conformation of different proteins. To clarify the underlying mechanism, fi-conglycinin and hydrolysates of glycinin (GH) were used as globular and flexible proteins, and the structural and functional properties of mixed proteins with different ratios were investigated. As GH content increased, the amount of fi-sheet decreased significantly, whereas a-helix, fi-turn, and random coil contents increased, which indicated the intramolecular structural flexibility of mixed soy protein was slightly reduced, whereas the intermolecular structural flexibility improved substantially. Interfacial shear rheology was used to assess the linear and nonlinear behavior of mixed soy proteins at the interface. As GH content increased, the elastic modulus was decreased while the width of the linear viscoelastic region (LVR) was slightly increased. For all samples, when small strain amplitudes were at 1-10% (within the LVR), the shape of the elastic Lissajous plots was perfectly elliptical. The elliptical shape changed to circular as strain increased. Compared with single 7S, the mixed soy proteins showed reduced levels of deformation in the elliptical shape, which were likely due to the greater resistance of the gelatinous network and its ability to resist permanent deformation. The particle size, zeta-potential, interfacial protein adsorption fraction, microstructure, and stability of emulsions formed of mixed soy proteins were also studied. Results showed that emulsion formed of mixed soy proteins with a ratio of 1:1 (GH-50%) was optimal. This study could potentially aid in the application of proteins with different structures and interfacial properties in emulsion.

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