L. V. Pirova Department of Technology of Milk and Meat Production, Bila Tserkva National Agrarian University
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RESULTS AND DISCUSSION
Recently, crossbreeding, as an element of commercial herds improvement, has been studied mainly from the point of view of its influence on productive and reproductive features, qualitative composition of milk and duration of economic use of cows. Furthermore, the study of protein and mineral composition of crossbred cows’ milk, which is mostly local or continental, was not carried out in full. Currently, there is no information about the influence of crossbreeding on the protein composition of the cows of the Holstein breed with the Jersey, Montbeliarde or Brown Swiss breeds. However, Decow et al. (2007) noted that the first generation of Holstein and Jersey crosses was marked by higher levels of fat, protein, and lower somatic cells. These factors level the difference in productivity, which was somewhat higher in purebred Holstein cows. This is to some extent coincides avoid we in which the crossbred cows of the first generation of UBS with Brown Swiss breeds cows synthesized more fat+protein per lactation, and had a higher indicator of theoretically possible yield of rennet cheese than of pure-breed ones. Pure UBS and URS cows produced 106.45 and 218.36 kg more milk than crossbred analogues per 305 days of lactation, thereby emphasizing the potential loss of some milk volume associated with crossbreeding (Table 1). At the same time, the mass fraction of fat and protein were higher at crossbred cows by 0.08 and 0.15% at the crossbreed of UBS with Brown Swiss breeds and by 0.16 and 0.22% at the crossbred cows of the URS with Montbeliarde breeds, respectively. Also, the synthesis of fat+protein was 7.04 kg more UBS and Brown Swiss breeds and 8.74 kg more at URS and Montbeliarde crossbred cows. Research results by Heins and Hansen (2012), who studied the influence of the crossbreeding cows of Holstein and Montbeliarde breeds on productivity, the qualitative composition of milk and calf crop in 6 commercial California herds, reported that during 305 days of lactation the crossbred cows synthesized less fat and protein by 3% than purebred Holstein cows. The authors recommend to use this combination of crossbreeding for increasing of the annual calf delivery, reducing of the risks associated with the severity of calving and improvement of the udder shape and to use it in herds with average productivity. Our studies do not inconsistent with the above mentioned, as at the crosses of the URS with Montbeliarde breeds, when we have observed the results of fat and protein by 1.96% higher and by 1.49% higher than of theoretically possible yield of rennet cheese than pure-breed analogues. An important indicator which marks the value of milk as a feedstock for food production is its mineral composition (Cashman, 2006; Patra et al., 2008; Claeys et al., 2014). The major mineral elements of milk are biologically significant constituents that are necessary for normal development and livelihoods (Stawars et al., 2007; Cofani et al., 2012; Gürbay et al., 2012). The number of major mineral elements in milk is an important indicator of its biological activity. They are essential for the development of the aroma – they form bacteria that produce aromatic substances that are involved in the creation of the aroma of cultured milk foods, sour cream butter, as well as in the formation of a picture in cheese (Schöne et al., 2009; Rafiq et al., 2016). In addition, they are part of the buffer systems of milk and casein micelles. The most important major mineral elements of milk are calcium and phosphorus. They are contained in an easily digestible form and harmoniously balanced among themselves (Tripathi et al., 1999; Moreno-Montoro et al., 2015). The physiological and biochemical role of Ca and P is very important in human nutrition, especially for children, in the processing of feed stock and plays a pivotal role in the dispensing of 240
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