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以天然马苏里拉干酪为目标,以干酪融化后特性(融化性、油脂析出率、拉伸性和褐变性)、感官、微观结构为指标,研究原辅料对再制马苏里拉干酪融化后品质特性的影响。结果表明:选择比例为1∶1(m/m,下同)的成熟度为3个月切达干酪和马苏里拉干酪,配合比例为1∶4色拉油和奶油进行再制马苏里拉干酪的制作,既保证了再制干酪所需的质构,同时也赋予产品特有的风味;添加量为1.3%的乳化盐和2.0%的柠檬酸能提供再制干酪所需的乳化性和合理的p H值,产品的加工特性最佳。 相似文献
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对分离自酒曲的1 株解淀粉芽孢杆菌GSBa-1发酵所产凝乳酶进行研究,该酶凝乳活力高而蛋白水解活力低,纯酶凝乳活力可达1.46×106 SU/g;使用该凝乳酶和商品凝乳酶制作马苏里拉干酪,并对干酪理化成分、成熟过程中pH值和微生物指标及干酪成熟前后质构特性、游离脂肪酸、可溶性蛋白、风味和干酪性能等指标进行对比分析。结果显示,理化成分上菌株凝乳酶与商品凝乳酶制作的干酪相接近(P<0.05)。干酪在成熟过程中,发酵剂存活数先增加后减少,但其差异不大;菌株凝乳酶制作的干酪pH 4.6可溶性蛋白含量较多,干酪的游离氨基酸总量(76 mg/100 g)也高于商品凝乳酶制作的干酪游离氨基酸总量(55.3 mg/100 g);菌株凝乳酶制作的干酪质构特性优于商品凝乳酶制作的干酪;电镜结果显示,菌株凝乳酶制作的干酪内部网状结构更充实;菌株凝乳酶具有稍强的蛋白水解活力,导致其制作的干酪风味物质种类多于商品凝乳酶制作的干酪,风味物质更加丰富。干酪样品的保形性和拉丝性实验测定结果显示,2 种凝乳酶制作的干酪性能差异不大(P>0.05);对2 种凝乳酶制作的干酪进行感官评定,其总评分相接近。以上结果表明,解淀粉芽孢杆菌GSBa-1凝乳酶在一定程度上可代替小牛凝乳酶应用于马苏里拉干酪的生产。 相似文献
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近年来,植物基干酪受到广泛关注。以玉米醇溶蛋白、水和椰子油为原料,干酪的功能特性(拉伸性、熔化性、油脂析出性)为评价指标,经单因素和正交试验确定玉米醇溶蛋白基马苏里拉干酪的最佳配比为玉米醇溶蛋白∶水∶椰子油=3∶3∶2(质量比)。最佳配方所得玉米醇溶蛋白基马苏里拉干酪的拉伸性、熔化性分别为市售天然马苏里拉干酪和市售植物基马苏里拉干酪的1.4、10.8倍和1.8、1.4倍。硬度、黏着性、弹性与市售天然马苏里拉干酪相近。试验所得玉米醇溶蛋白基马苏里拉干酪有良好的功能特性和质构特性,具有广阔的市场应用前景。 相似文献
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为了探究甲醇芽孢杆菌(Bacillus methanolicus)凝乳酶在马苏里拉干酪加工中的应用,分别以使用甲醇芽孢杆菌凝乳酶、混合酶制剂(含质量分数10%甲醇芽孢杆菌凝乳酶和90%商品凝乳酶)制作的马苏里拉干酪作为实验组,以商品凝乳酶干酪作为对照组,测定不同组别干酪成熟期间的蛋白水解特性、质构、风味和微观结构变化,研究甲醇芽孢杆菌凝乳酶对马苏里拉干酪加工特性的影响。结果表明,实验组干酪在成熟过程中pH值(4.6~5.3)、微生物数量(8.80~9.68(lg(CFU/g)))与对照组无显著差异(P>0.05);实验组干酪水分质量分数(混合酶干酪为(43.21±1.17)%、甲醇芽孢杆菌凝乳酶干酪为(46.15±0.94)%)均显著高于对照组((41.08±1.04)%),得率(混合酶干酪为(9.27±0.17)%、甲醇芽孢杆菌凝乳酶干酪为(9.46±0.16)%)也显著高于对照组((8.98±0.13)%)(P<0.05);且实验组干酪的蛋白水解特性(pH 4.6时可溶性蛋白、酪蛋白水解程度和游离氨基酸质量分数)以及风味物质种类和相对含量等指标也优于对照组干酪。但是实验组中甲醇芽孢杆菌凝乳酶干酪保形性相对欠佳,感官评定得分偏低,混合酶干酪与对照组质构及感官基本得分一致,因此甲醇芽孢杆菌凝乳酶可以作为商品酶的部分代替品应用于干酪的生产中。 相似文献
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目的分析水牛α_(S1)-酪蛋白多态性对马苏里拉干酪品质的影响。方法以α_(S1)-酪蛋白AB型、α_(S1)-酪蛋白BB型和混合组水牛乳样为原料分别制成全脂马苏里拉干酪,比较3组水牛乳样和干酪在组成、功能特性和微观结构等方面的差异。结果α_(S1)-酪蛋白AB型水牛乳在脂肪、蛋白质和总固形物含量上显著高于BB型。制成马苏里拉干酪后,AB型干酪的蛋白质含量显著高于BB型和混合组干酪。BB型和AB型干酪在硬度、咀嚼性和胶黏性上显著高于混合组。结论不同基因型α_(S1)-酪蛋白水牛乳的乳成分存在差异,α_(S1)-酪蛋白多态性与水牛乳马苏里拉干酪的组成、质构和融化特性等存在显著关联。 相似文献
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Mozzarella干酪生产工艺的优化 总被引:19,自引:8,他引:19
选择了影响Mozzarella干酪生产的3个关键因素:热缩温度、堆酿pH值和热烫拉伸温度;采用三因素二次通用旋转组合设计,以干酪的实际产率、pH值为4.6可溶性N,质量分数为12%的TCA可溶性N和感官评定值为指标,进行综合评定。优选出Mozzarella干酪的最优工艺参数为:热缩温度38℃,堆酿pH值为5.25,热烫拉伸温度58℃。在这一条件下,生产的干酪产率及综合质量最好。同时探讨了3个因子对以上4个指标的影响,为生产不同用途的Mozzarella干酪提供了一定的理论依据。 相似文献
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描述一种用于生产Mozzarella干酪的单螺杆拉伸机的设计,包括理论分析、机械设计以及试验论证.该拉伸机可以实现对凝乳颗粒的可控加热与拉伸,同时,为了直接获得直径20 mm~30mm的干酪块,在拉伸机出口处安装了小孔均匀分布的挤出板,使小尺寸的干酪块冷却时间缩短.该机试制的样品符合美国农业部关于Mozzarella干酪产品的标准. 相似文献
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ABSTRACT: Mozzarella cheeses were made with a single culture (SC) or a mixed culture (MC) using 1x or 6x of cheese coagulants chymosin or Cryphonectria parasitica (CP). Melt area increased only by approximately 80% in cheeses made with SC against 230% in the cheeses made with MC after 30 d of storage. Soluble nitrogen was also higher in MC cheeses as compared to SC cheeses. Both the elastic (G') and the viscous (G") modulus decreased with storage. Decrease in both moduli was greater in the MC cheeses at 6× enzyme level compared to SC cheeses at 1× enzyme level. The synergism between coagulating enzyme and starter culture was beneficial, which improved melt and flow of Mozzarella cheese and had profound effects on the viscoelastic properties of Mozzarella cheese. 相似文献
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硬质干酪加工工艺的研究 总被引:8,自引:0,他引:8
以鲜牛乳为原料,研究了硬质干酪的制造工艺,确定了发酵剂;凝乳酶;氯化钙的添加量和成熟条件等主要工艺参数,并探讨了影响凝乳酶活力的主要因素. 相似文献
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为评价干酪成熟过程中形成的活性肽及存活的发酵剂菌种对人体的抗氧化作用,对不同菌种组合Mozzarella干酪的蒸馏水、pH4.6醋酸缓冲液和12%三氯乙酸(TCA)提取液在模拟胃肠液环境下对DPPH自由基的清除率以及还原力进行测定。结果表明,所有不同菌种组合Mozzarella干酪的不同溶剂提取液在模拟胃肠液的环境下具有一定的抗氧化活性,并且模拟肠液的抗氧化活性大大低于模拟胃液环境,活性下降最高达88.35%。添加干酪乳杆菌(Lactobacillus casei)LPC-37的3号Mozzarella干酪提取液在模拟胃肠液环境下的抗氧化活性高于其他Mozzarella干酪,其水、pH4.6醋酸缓冲液、12%TCA提取液在模拟肠液环境下对DPPH清除率分别为73.96%、30.28%、70.27%,还原力分别为0.37、0.18、0.18。 相似文献
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MARÍA LAURA OLIVARES SUSANA E. ZORRILLA AMELIA C. RUBIOLO 《Journal of texture studies》2009,40(3):300-318
The viscoelastic properties of mozzarella cheese using a creep/recovery test considering different sampling directions (parallel and perpendicular to protein fiber orientation), test temperatures (20, 30 and 40C) and ripening times (1, 8, 15, 29 and 36 days) were studied. Creep data were interpreted by a Burger model of four parameters. A semiempirical approach was proposed to obtain the contribution of each main compliance to the total deformation of the system. Creep tests at different temperatures allowed gaining a better understanding of changes that occur in the cheese matrix during heating and ripening. Sampling direction did not affect any of the parameters studied. Finally, it was clearly observed that cheese matrix behaves as a quite different physicochemical system depending on temperature. Therefore, it is recommended to carry out the rheological tests at different temperatures to evaluate appropriately the viscoelastic properties of mozzarella cheese.
Mozzarella cheese must have certain characteristics to be used on pizzas and on other prepared foods that use the cheese in melted state. The protein chains in the mozzarella curds coalesce into large strands that are oriented in the direction of stretching. For this reason, mozzarella cheese has an anisotropic structure. Therefore, it is relevant to determine the effect of protein fiber orientation on the rheological properties. Valuable information may be obtained through the creep/recovery test of mozzarella cheese samples to study its rheological properties and to explain molecular mechanisms that occur during ripening or melting processes considering sampling direction. 相似文献
PRACTICAL APPLICATIONS
Mozzarella cheese must have certain characteristics to be used on pizzas and on other prepared foods that use the cheese in melted state. The protein chains in the mozzarella curds coalesce into large strands that are oriented in the direction of stretching. For this reason, mozzarella cheese has an anisotropic structure. Therefore, it is relevant to determine the effect of protein fiber orientation on the rheological properties. Valuable information may be obtained through the creep/recovery test of mozzarella cheese samples to study its rheological properties and to explain molecular mechanisms that occur during ripening or melting processes considering sampling direction. 相似文献