Upreti P, McKay L L, Metzger L E
MN-SD Dairy Foods Research Center, Department of Food Science and Nutrition, University of Minnesota, St. Paul 55108, USA.
J Dairy Sci. 2006 Feb;89(2):429-43. doi: 10.3168/jds.S0022-0302(06)72107-5.
Cheddar cheese ripening involves the conversion of lactose to glucose and galactose or galactose-6-phosphate by starter and nonstarter lactic acid bacteria. Under ideal conditions (i.e., where bacteria grow under no stress of pH, water activity, and salt), these sugars are mainly converted to lactic acid. However, during ripening of cheese, survival and growth of bacteria occurs under the stressed condition of low pH, low water activity, and high salt content. This forces bacteria to use alternate biochemical pathways resulting in production of other organic acids. The objective of this study was to determine if the level and type of organic acids produced during ripening was influenced by calcium (Ca) and phosphorus (P), residual lactose, and salt-to-moisture ratio (S/M) of cheese. Eight cheeses with 2 levels of Ca and P (0.67 and 0.47% vs. 0.53 and 0.39%, respectively), lactose at pressing (2.4 vs. 0.78%), and S/M (6.4 vs. 4.8%) were manufactured. The cheeses were analyzed for organic acids (citric, orotic, pyruvic, lactic, formic, uric, acetic, propanoic, and butyric acids) and residual sugars (lactose, galactose) during 48 wk of ripening using an HPLC-based method. Different factors influenced changes in concentration of residual sugars and organic acids during ripening and are discussed in detail. Our results indicated that the largest decrease in lactose and the largest increase in lactic acid occurred between salting and d 1 of ripening. It was interesting to observe that although the lactose content in cheese was influenced by several factors (Ca and P, residual lactose, and S/M), the concentration of lactic acid was influenced only by S/M. More lactic acid was produced in low S/M treatments compared with high S/M treatments. Although surprising for Cheddar cheese, a substantial amount (0.2 to 0.4%) of galactose was observed throughout ripening in all treatments. Minor changes in the levels of citric, uric, butyric, and propanoic acids were observed during early ripening, whereas during later ripening, a substantial increase was observed. A gradual decrease in orotic acid and a gradual increase in pyruvic acid content of the cheeses were observed during 12 mo of ripening. In contrast, acetic acid did not show a particular trend, indicating its role as an intermediate in a biochemical pathway, rather than a final product.
切达干酪的成熟过程涉及到由发酵剂和非发酵剂乳酸菌将乳糖转化为葡萄糖、半乳糖或6-磷酸半乳糖。在理想条件下(即细菌在无pH值、水分活度和盐分压力的情况下生长),这些糖主要转化为乳酸。然而,在奶酪成熟过程中,细菌是在低pH值、低水分活度和高盐含量的压力条件下存活和生长的。这迫使细菌使用替代生化途径,从而产生其他有机酸。本研究的目的是确定奶酪成熟过程中产生的有机酸的水平和类型是否受钙(Ca)、磷(P)、残留乳糖以及盐与水分比(S/M)的影响。制作了8种奶酪,其钙和磷含量有2个水平(分别为0.67%和0.47%与0.53%和0.39%)、压制时的乳糖含量(2.4%与0.78%)以及S/M(6.4与4.8)。在48周的成熟过程中,使用基于高效液相色谱的方法分析奶酪中的有机酸(柠檬酸、乳清酸、丙酮酸、乳酸、甲酸、尿酸、乙酸、丙酸和丁酸)和残留糖(乳糖、半乳糖)。不同因素影响了成熟过程中残留糖和有机酸浓度的变化,将对此进行详细讨论。我们的结果表明,乳糖的最大降幅和乳酸的最大增幅发生在加盐和成熟第1天之间。有趣的是,尽管奶酪中的乳糖含量受多种因素(钙和磷、残留乳糖以及S/M)影响,但乳酸浓度仅受S/M影响。与高S/M处理相比,低S/M处理产生了更多的乳酸。尽管对于切达干酪来说令人惊讶,但在所有处理的整个成熟过程中都观察到了大量(0.2%至0.4%)的半乳糖。在成熟早期观察到柠檬酸、尿酸、丁酸和丙酸水平有微小变化,而在成熟后期观察到大幅增加。在12个月的成熟过程中,观察到奶酪中乳清酸逐渐减少,丙酮酸含量逐渐增加。相比之下,乙酸没有呈现出特定趋势,这表明其作为生化途径中的中间产物而非最终产物的作用。
