Department of Animal Sciences and Industry, Food Science Institute, Kansas State University, Manhattan 66506.
Department of Animal Sciences and Industry, Food Science Institute, Kansas State University, Manhattan 66506.
J Dairy Sci. 2021 Apr;104(4):4094-4107. doi: 10.3168/jds.2020-19409. Epub 2021 Jan 21.
Milk protein concentrate (MPC) is a preferred ingredient to provide nutritional and functional benefits in various dairy and food products. Altering the protein configuration and protein-protein interactions in MPC can provide a novel functionality and may open doors for new applications. The fibrilization process converts the globular structure of whey proteins to fibrils and consequently increases viscosity and water holding capacity compared with the native protein structure. The objective of the current work was to selectively convert the whey proteins in MPC as fibrils. For this purpose, simulated control model MPC was prepared by combining solutions of micellar casein concentrate (MCC) and milk whey protein isolate (mWPI) to give casein and whey protein in an 80:20 ratio. The mWPI solution was converted to fibrils by heating at low pH, neutralized, and combined with MCC solution similar to control model MPC and termed "fibrillated model MPC." Thioflavin T fluorescence value, transmission electron microscopy, and gel electrophoresis confirmed the fibril formation and their survival after neutralization and mixing with MCC. Further, the fibrillated mWPI showed significantly higher viscosity and consistency coefficient than nonfibrillated mWPI. Similarly, fibrillated model MPC showed significantly higher viscosity and consistency coefficient compared with control model MPC. Hence, the fibrillated model MPC can be used as ingredient to increase viscosity. Heat coagulation time was found to be significantly higher for control model MPC compared with fibrillated model MPC.
浓缩乳蛋白(MPC)是一种在各种乳制品和食品中提供营养和功能性益处的首选成分。改变 MPC 中的蛋白质结构和蛋白质-蛋白质相互作用可以提供新的功能,并为新的应用打开大门。纤维形成过程将乳清蛋白的球状结构转化为纤维,从而与天然蛋白质结构相比增加了粘度和持水能力。目前工作的目的是选择性地将 MPC 中的乳清蛋白转化为纤维。为此,通过将胶束酪蛋白浓缩物(MCC)和乳清蛋白分离物(mWPI)的溶液组合来制备模拟对照 MPC,以使酪蛋白和乳清蛋白的比例为 80:20。通过在低 pH 值下加热将 mWPI 溶液转化为纤维,然后中和,并与 MCC 溶液混合类似于对照 MPC,并称为“纤维状模型 MPC”。硫黄素 T 荧光值、透射电子显微镜和凝胶电泳证实了纤维的形成及其在中和和与 MCC 混合后的存活。此外,纤维状 mWPI 表现出明显高于非纤维状 mWPI 的更高粘度和稠度系数。同样,与对照模型 MPC 相比,纤维状模型 MPC 表现出明显更高的粘度和稠度系数。因此,纤维状模型 MPC 可用作增加粘度的成分。与纤维状模型 MPC 相比,对照模型 MPC 的热凝结时间明显更高。
