Harte Federico M, Gurram Subba Rao, Luedecke Lloyd O, Swanson Barry G, Barbosa-Cánovas Gustavo V
Biological Systems Engineering Department, Washington State University, Pullman, WA 99164-6120, USA.
J Dairy Res. 2007 Nov;74(4):452-8. doi: 10.1017/S0022029907002762. Epub 2007 Oct 26.
High hydrostatic pressure disruption of casein micelle isolates was studied by analytical ultracentrifugation and transmission electron microscopy. Casein micelles were isolated from skim milk and subjected to combinations of thermal treatment (85 degrees C, 20 min) and high hydrostatic pressure (up to 676 MPa) with and without whey protein added. High hydrostatic pressure promoted extensive disruption of the casein micelles in the 250 to 310 MPa pressure range. At pressures greater than 310 MPa no further disruption was observed. The addition of whey protein to casein micelle isolates protected the micelles from high hydrostatic pressure induced disruption only when the mix was thermally processed before pressure treatment. The more whey protein was added (up to 5 g/l) the more the protection against high hydrostatic pressure induced micelle disruption was observed in thermally treated samples subjected to 310 MPa.
通过分析超速离心和透射电子显微镜研究了酪蛋白胶粒分离物的高静水压破坏。从脱脂乳中分离出酪蛋白胶粒,并在添加和不添加乳清蛋白的情况下,对其进行热处理(85℃,20分钟)和高静水压(高达676兆帕)的组合处理。在250至310兆帕的压力范围内,高静水压促使酪蛋白胶粒发生广泛破坏。在压力大于310兆帕时,未观察到进一步的破坏。仅当混合物在压力处理前进行热处理时,向酪蛋白胶粒分离物中添加乳清蛋白才能保护胶粒免受高静水压诱导的破坏。添加的乳清蛋白越多(高达5克/升),在经受310兆帕的热处理样品中观察到的针对高静水压诱导的胶粒破坏的保护作用就越大。