Alternatively, Silva et al (2010) found different moisture (45 5

Alternatively, Silva et al. (2010) found different moisture (45.5–51.5 g/100 g), protein (26.9–59.6 g/100 g), and fat contents (36.6–48.2 g/100 g) and pH (5.99–7.13) values in Coalho cheese made from cow’s milk marketed in the Brazilian Northeast. Micelle structures of goat milk differ from cow milk in average Thiazovivin molecular weight diameter, hydration and mineralization. Average mineralization levels of micelles in goat are higher than in cow milk. There is an inverse relationship between the mineralization

of the micelle and its hydration, which also means that goat milk is less hydrated than cow milk (Park, Juárez, Ramos, & Haenlein, 2007) which explains the tenderness of cow cheese. The protein content of CCM and the pH values for CCM, CCGM and CGM significantly differed (P < 0.05) between the 1st and 28th day of storage. The pH values presented no significant differences (P > 0.05) among the different cheeses. Sheehan et al. (2009) observed a decrease in the pH values of semi-hard cheeses manufactured from a mixture of caprine and bovine milk during 150 days of cold storage. According to Sheehan et al. (2009), cow’s

milk presents pH values higher than those of goat’s milk after pasteurization and before the inoculation of the starter culture during the cheeses manufacture, results also observed for our study. The pH values of cheeses made from goat’s milk tend to decrease during the first thirty days of ripening, followed by an increase after this time, while the pH values of cheeses made from cow’s milk tend to decrease during OSI-744 ic50 the first sixty days of ripening, with a slight increase after this time (Mallatou, Pappas, & Voutsinas, 1994). Goat’s milk also presented a more pronounced alkalinity and buffering capacity in comparison to cow’s Galeterone milk, which is mainly related to the associated casein and phosphate systems (Galina, Osnaya,

Cuchillo, & Haenlein, 2007). Low pH values make calcium phosphate micelles more soluble increasing the loss of soluble calcium of whey during the draining of curdled milk (Park, 2006). Pappa et al. (2006) found a decrease in the protein content of ripened cheeses during storage regardless of the kind of milk (goat’s, ewe’s and cow’s) used in their production. Changes in the protein content of cheeses during storage have been related to protein hydrolysis and the production of water-soluble nitrogen compounds, which are released in the brine (Pintado et al., 2008). The moisture, salt and pH values of cheeses are related to the time of ripening because ripened cheeses present lower moisture, greater hardness, higher acidity and higher salt content than unripened cheeses (Freitas & Malcata, 2000). However since our cheeses were only slightly ripened few significant variations of such parameters were observed throughout storage time.

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