Improving Freeze-Thaw Stability of Soybean Protein Emulsion by Irradiation-Assisted Grafting Reaction

被引:0
|
作者
Wang Y. [1 ]
Zhang A. [1 ]
Wang L. [1 ]
Zhou G. [1 ]
Xu N. [1 ]
Wang X. [1 ]
机构
[1] School of Food Science, Northeast Agricultural University, Harbin
来源
Xu, Ning (xuningneau@163.com); Wang, Xibo (wangxibo@neau.edu.cn) | 1600年 / Chinese Chamber of Commerce卷 / 41期
关键词
Emulsion; Freeze-thaw stability; Grafting reaction; Radiation; Soy protein isolate;
D O I
10.7506/spkx1002-6630-20190527-325
中图分类号
学科分类号
摘要
Irradiation technology was used to assist the grafting reaction between soybean protein isolate (SPI) and maltose(M) to improve the freeze-thaw stability of SPI emulsion. The effects of SPI concentration, m(SPI)/m(M) ratio, and irradiation dose on the grafting degree, browning degree and creaming index of modified products were studied. It was found that under the conditions: SPI concentration of 4%, m(SPI)/m(M) ratio of 4: 1 and radiation dose of 7.5 kGy, the creaming index of modified SPI was decreased by 23.58%, 29.9% and 31.2%, respectively, after 1, 2 and 3 freeze-thaw cycles when compared with intact SPI. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) confirmed the grafting reaction between SPI and maltose. The oil release rate of the modified SPI emulsion after freezing and thawing was significantly improved when compared with SPI emulsion. Optical microscopy observation also confirmed that the optimized SPI microstructure was more stable. This study suggested that irradiation could enhance the grafting reaction to improve the freeze-thaw stability of SPI emulsion, which will provide a new integrative protein modification approach. © 2020, China Food Publishing Company. All right reserved.
引用
收藏
页码:135 / 140
页数:5
相关论文
共 26 条
  • [1] WANG X B, CHI Y J., Microwave-assisted phosphorylation of soybean protein isolates and their physicochemical properties, Czech Journal of Food Sciences, 36, pp. 99-107, (2012)
  • [2] CHEN L, CHEN J S, REN J Y, Et al., Modifications of soy protein isolates using combined extrusion pre-treatment and controlled enzymatic hydrolysis for improved emulsifying properties, Food Hydrocolloids, 25, 5, pp. 887-897, (2011)
  • [3] SHEPHERD R, ROBERTSON A, OFMAN D., Dairy glycoconjugate emulsifiers: casein-maltodextrins, Food Hydrocolloids, 14, 4, pp. 281-286, (2000)
  • [4] MARTINEZ K D, FARIAS M E, PILOSOF A M R., Effects of soy protein hydrolysis and polysaccharides addition on foaming properties studied by cluster analysis, Food Hydrocolloids, 25, 7, pp. 1667-1676, (2011)
  • [5] DIFTIS N G, BILIADERIS C G, KIOSSEOGLOU V D., Rheological properties and stability of model salad dressing emulsions prepared with a dry-heated soybean protein isolate-dextran mixture, Food Hydrocolloids, 19, 6, pp. 1025-1031, (2005)
  • [6] MU M F, PAN X Y, YAO P, Et al., Acidic solution properties of β-casein-graft-dextran copolymer prepared through Maillard reaction, Journal of Colloid and Interface Science, 301, 1, pp. 98-106, (2006)
  • [7] FARKAS J, MOHACSI-FARKAS C., History and future of food irradiation, Trends in Food Science & Technology, 22, 2, pp. 121-126, (2011)
  • [8] SOLIMAN E A, FURUTA M., Influence of γ-irradiation on mechanical and water barrier properties of corn protein-based fi lms, Radiation Physics & Chemistry, 78, 7, pp. 651-654, (2009)
  • [9] WU Y, WANG Y, REN G, Et al., Improvement of fish meal replacements by soybean meal and soy protein concentrate in golden pompano diet through γ-ray irradiation[J], Aquaculture Nutrition, 22, 4, pp. 873-880, (2016)
  • [10] PEDNEKAR M, DAS A K, RAJALAKSHMI V, Et al., Radiation processing and functional properties of soybean (glycine max), Radiation Physics and Chemistry, 79, 4, pp. 490-494, (2010)
123