Auldist Martin J, Johnston Keith A, White Nicola J, Fitzsimons W Paul, Boland Michael J
Drexel Ltd., Private Bag 3123, Hamilton, New Zealand.
J Dairy Res. 2004 Feb;71(1):51-7. doi: 10.1017/s0022029903006575.
Twenty-nine multiparous cows of each of the Jersey and Friesian breeds, all kappa-casein AB phenotype, were grazed together and managed identically. On three occasions during 10 d in spring (early lactation), milk was collected from all cows at four consecutive milkings and bulked according to breed. On a separate occasion, milk samples were also collected from each cow at consecutive a.m. and p.m. milkings to form one daily sample per cow. The bulked milks (800-1000 l per breed on each occasion) were standardized to a protein:fat (P:F) ratio of 0.80, and 350 l from each breed was made into Cheddar cheese. The solids content of the remaining Friesian milk was then increased by ultrafiltration to a solids concentration equal to that of the Jersey milk. This solids-standardized Friesian milk and a replicate batch of P:F standardized Jersey milk were made into two further batches of Cheddar cheese in 350-l vats. Compared with Friesian milk, Jersey milk had higher concentrations of most milk components measured, including protein, casein and fat. There were few difference in milk protein composition between breeds, but there were differences in fat composition. Friesian milk fat had more conjugated linoleic acid (CLA) than Jersey milk fat. Jersey milk coagulated faster and formed firmer curd than Friesian milk. Concentrations of some milk components were correlated with coagulation parameters, but relationships did not allow prediction of cheesemaking potential. Jersey milk yielded 10% more cheese per kg than Friesian milk using P:F standardized milk, but for milks with the same solids concentration there were no differences in cheese yield. No differences in cheese composition between breeds were detected. Differences in cheesemaking properties of milk from Jerseys and Friesians were entirely related to the concentrations of solids in the original milk.
选取了29头经产泽西牛和29头经产弗里生牛,所有牛均为κ-酪蛋白AB表型,将它们放在一起放牧并进行相同的管理。在春季10天内(泌乳早期)的三个不同时间,在连续四次挤奶时从所有奶牛采集牛奶,并按品种进行混合。在另一个单独的时间,还在上午和下午连续挤奶时从每头奶牛采集牛奶样本,以形成每头奶牛的每日样本。每次混合后的牛奶(每个品种每次800 - 1000升)被标准化为蛋白质:脂肪(P:F)比为0.80,然后从每个品种中取出350升制成切达干酪。然后通过超滤将剩余弗里生牛奶的固体含量提高到与泽西牛奶相同的固体浓度。这种固体标准化的弗里生牛奶和一批P:F标准化的泽西牛奶重复样本在350升的大桶中制成另外两批切达干酪。与弗里生牛奶相比,泽西牛奶中所测的大多数乳成分浓度更高,包括蛋白质、酪蛋白和脂肪。不同品种之间乳蛋白组成差异不大,但脂肪组成存在差异。弗里生牛奶脂肪中的共轭亚油酸(CLA)比泽西牛奶脂肪中的多。与弗里生牛奶相比,泽西牛奶凝固更快,形成的凝乳更坚实。一些乳成分的浓度与凝固参数相关,但这些关系无法预测奶酪制作潜力。使用P:F标准化牛奶时,每千克泽西牛奶制成的奶酪比弗里生牛奶多10%,但对于固体浓度相同的牛奶,奶酪产量没有差异。未检测到不同品种之间奶酪组成的差异。泽西牛和弗里生牛所产牛奶在奶酪制作特性上的差异完全与原奶中的固体浓度有关。
