益生菌发酵乳模拟胃肠液环境下抗氧化活性

为间接评价益生菌发酵乳在人体内的抗氧化活性,分别采用嗜热链球菌（Streptococcus thermophilus）、德氏乳杆菌保加利亚亚种（Lactobacillus delbrueckii subsp. bulgaricus）、动物双歧杆菌（Bifidobacterium）BB12及嗜酸乳杆菌（Lactobacillus acidophilus）制备SL、SL+BB12、SL+LA三种发酵乳,并对其冷藏过程中模拟胃肠液环境下对ABTS、DPPH自由基的清除能力进行了测定。结果表明,三种发酵乳随冷藏时间的延长其抗氧化活性都逐渐降低,添加菌种BB12和LA的发酵乳抗氧化活性下降的幅度小于SL发酵乳,在相同的冷藏时间下模拟胃肠液环境后抗氧化活性都较原发酵乳降低,但添加益生菌BB12和LA发酵乳在模拟胃肠液环境下抗氧化活性高于SL发酵乳,其中BB12高于LA。SL、SL+BB、SL+LA发酵乳冷藏7 d时对ABTS自由基最大清除率分别为46.21%、58.54%、51.99%,对DPPH自由基最大清除率分别为42.17%、53.34%、49.48%。     

Mozzarella干酪提取液的抗菌活性

Mozzarella干酪中酪蛋白抗菌肽对人体有非常重要的作用。为了研究酪蛋白提取液的抑菌作用,对成熟期为40 d、50 d和60 d的Mozzarella干酪,分别用无菌蒸馏水、醋酸-醋酸钠缓冲溶液和TCA提取法制备干酪提取液,探讨了干酪提取液对大肠杆菌、枯草芽孢杆菌、酵母菌和黑曲霉的抑制作用。结果显示,不同成熟期Mozzarella干酪的提取液对大肠杆菌、枯草芽孢杆菌和酵母菌均有一定的抑制作用。成熟期为40 d的Mozzarella干酪,用无菌蒸馏水提取出的提取液对大肠杆菌的抑菌性最强;成熟期为60 d的Mozzarella干酪,用TCA提取法提取出的提取液对枯草芽孢杆菌、酵母菌和黑曲霉的抑菌性最强。     

不同菌种组合Mozzarella干酪成熟过程中水溶性提取液的抑菌及抗氧化活性研究

为研究不同的菌种组合及不同的成熟期对Mozzarella干酪成熟过程中形成的水溶性抑菌、抗氧化物质的影响,采用无菌蒸馏水作为提取溶剂,采用滤纸片法对水溶性提取液抑制大肠杆菌、枯草芽孢杆菌、金黄色葡萄球菌、霉菌以及酵母的特性进行了测定。同时对提取液在体外对DPPH自由基的清除率、提取液的还原力进行了测定,提取液对老鼠体内的抗氧化特性也进行了测定。结果表明:提取液的抑菌、抗氧化效果随菌种、成熟时间的不同而不同,对细菌的抑制效果好于真菌。AB+LH组合Mozzarella干酪在成熟60 d时提取液的抑菌效果均好于其它组合Mozzarella干酪,成熟40 d的AB+LA组合Mozzarella干酪提取液对DPPH清除率最大为67.76%,成熟50 d的AB组合Mozzarella干酪提取液的还原力最大为1.23,提取液在小鼠体内也具有一定的抗氧化活性。     

Mozzarella干酪的研制

以新鲜牛乳为主要原料,通过干酪制造条件的优化研究,确定了制造Mozzarella干酪的工艺流程及主要参数,实验表明,新鲜牛乳经标准化使得酪蛋白与脂肪之比为0．84,然后加入发酵剂和凝乳酶,凝乳形成后,经切割,排乳清,并在热水中拉伸,盐渍即到成品,产品的平均脂肪和水分的含量分别为22．82％和50．74％,达到了Mozzarella干酪的质量要求。     

4种Mozzarella干酪在不同成熟期提取液的抗菌活性

为了研究4种Mozzarella干酪在不同成熟期提取液的抗菌活性,以抑菌圈直径为指标,通过TCA制备4种Mozzarella干酪在成熟期40,50,60d的提取液,探讨提取液对黑曲霉、酵母菌、枯草芽孢杆菌和大肠杆菌的抗菌性以及比较抗菌性的强弱。结果显示,不同干酪在不同成熟期的提取液的抗菌活性不同,干酪2和干酪4随着成熟期的延长对黑曲霉、酵母菌、枯草芽孢杆菌和大肠杆菌的抗菌性呈下降的趋势,说明成熟期越长,干酪2和干酪4的提取液所含的抗菌物质越少。干酪2在成熟40d和干酪3在成熟60d时的提取液对黑曲霉的抑制作用最强;干酪1在成熟60d时的提取液对酵母菌的抑制作用最强;干酪2在成熟40d时的提取液对枯草芽孢杆菌的抑制作用最强;干酪3在成熟60d时的提取液对大肠杆菌的抑制作用最强。     

红枣核桃酸奶的贮藏品质及胃肠液环境下抗氧化研究

以红枣、核桃、新鲜牛奶为主要原料制备红枣核桃酸奶,以不添加红枣汁与核桃粉的同批鲜奶自制普通酸奶为对照,分别测定不同贮藏时期红枣核桃酸奶和对照酸奶的理化指标,以及两种酸奶在贮藏期和胃、肠液模拟环境下对DPPH、ABTS自由基的清除能力。结果表明,贮藏期间红枣核桃酸奶在活菌数、酸度以及抗氧化能力方面均显著优于对照酸奶(P<0.05),持水力低于对照酸奶(P<0.05),且贮藏21 d后,红枣核桃酸奶的DPPH和ABTS自由基清除率分别为88.65%、72.46%,对照酸奶为53.10%、69.44%。然而,两种酸奶经延长冷藏时间或在胃肠液环境处理后均会导致自由基清除能力降低,但红枣核桃酸奶在总体上仍然优于对照酸奶。因此,红枣核桃酸奶是一种新型的功能性乳品。     

Mozzarella干酪的研究进展

本文对Mozzarella干酪的分类、特征及国内外发展现状做了简要的介绍,重点对加工工艺对干酪品质的影响做了综述,为我国干酪的研究提供一些思路。     

红枣核桃酸奶的贮藏品质及胃肠液环境下抗氧化研究

以红枣、核桃、新鲜牛奶为主要原料制备红枣核桃酸奶,以不添加红枣汁与核桃粉的同批鲜奶自制普通酸奶为对照,分别测定不同贮藏时期红枣核桃酸奶和对照酸奶的理化指标,以及两种酸奶在贮藏期和胃、肠液模拟环境下对DPPH、ABTS自由基的清除能力。结果表明,贮藏期间红枣核桃酸奶在活菌数、酸度以及抗氧化能力方面均显著优于对照酸奶(P<0.05),持水力低于对照酸奶(P<0.05),且贮藏21 d后,红枣核桃酸奶的DPPH和ABTS自由基清除率分别为88.65%、72.46%,对照酸奶为53.10%、69.44%。然而,两种酸奶经延长冷藏时间或在胃肠液环境处理后均会导致自由基清除能力降低,但红枣核桃酸奶在总体上仍然优于对照酸奶。因此,红枣核桃酸奶是一种新型的功能性乳品。     

模拟Mozzarella干酪工艺参数优化的研究

模拟Mozzarella干酪是一种类似天然干酪的产品。为使其品质更接近于天然Mozzarella干酪,研究了以干酪的质构、融化性、拉伸性和油脂析出性为指标,对生产工艺中的几个关键工艺参数进行优化。结果表明,融化温度、搅拌时间和搅拌速度对模拟Mozzarella干酪未融化时的物理特性和融化时的主要功能特性都有极显著性影响(P<0.01);融化温度为85℃,搅拌时间(加柠檬酸前)为5min,搅拌速度为250r/min时加工的模拟干酪的品质最接近于天然Mozzarella干酪。因此,在模拟Mozzarella干酪的加工工艺中选择融化温度85℃,搅拌时间5min,搅拌速度250r/min。      

Mozzarella干酪成熟过程中菌相变化规律的研究

为了研究Mozzarella干酪成熟过程中发酵剂菌种对干酪成熟的影响,本试验制作了模拟干酪,并以此为试验模型,分析了全脂Mozzarella干酪成熟过程中菌群的变化规律。结果表明:发酵剂乳酸菌是Mozzarella干酪成熟过程中的主要菌群,而且球菌在干酪成熟过程中占绝对优势;NSLAB对Mozzarella干酪成熟的作用不大。由于采用了真空包装,Mozzarella干酪中的杂菌数始终保持在很低的水平〔大肠菌群≤60MPN/100g,酵母霉菌≤45lg(cfu/g)〕,并且对干酪的成熟无影响。在Mozzarella干酪成熟过程中,乳糖含量逐渐下降,随着乳酸菌的自溶,使LDH增加,对干酪后期的成熟产生积极影响。     

不同发酵剂对Mozzarella干酪品质的影响

采用嗜热链球菌和嗜热乳杆菌作为Mozzarella干酪的发酵剂，研究单一嗜热链球菌发酵剂与嗜热链球菌和嗜热乳杆菌组成的混合发酵剂对Mozzarella干酪品质的影响。结果表明，混合菌作发酵剂制得的干酪品质优于用单一嗜热链球菌作发酵剂的干酪。     

原料乳热处理条件对Mozzarella干酪品质的影响

采用3×3拉丁方试验设计,3个奶酪槽中原料乳热处理条件分别设为未杀菌,63℃(30min)杀菌,72℃(15s)杀菌。研究干酪加工中原料乳热处理条件对Mozzarella干酪的品质的影响。结果表明,未杀菌乳制干酪的蛋白水解、硬度及弹性与杀菌乳制干酪的蛋白水解、硬度及弹性值具显著差异(p<0.05),未杀菌乳制干酪的蛋白水解显著增加,弹性及硬度显著降低;63℃(30min)及72℃(15s)不同杀菌温度处理的乳制得的干酪之间蛋白水解、硬度及弹性无显著差异;不同热处理乳制干酪之间的融化性和油脂析出性在统计学上无显著差异。     

Effects of Starter Culture and Coagulating Enzymes on Viscoelastic Behavior and Melt of Mozzarella Cheese

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.     

Rheology and melt characterization of low-fat and full fat Mozzarella cheese made from microfluidized milk

Microfluidization of cheese milk at different temperatures and pressures altered the meltability and rheological properties of Mozzarella cheese. Pasteurized milks, standardized to 1.0 (low-fat (LF)) or 3.2 (full fat (FF)) g fat/100 g milk, heated to 10, 43, or 54 °C, and then microfluidized at pressures of 34, 103, or 172 MPa, were used to manufacture Mozzarella cheese. Cheeses made from nonmicrofluidized milks served as controls. During the hot water step, only control cheeses and cheeses made with milk microfluidized at 10 °C could be stretched while all others had short curds that did not fuse together. Cheese responses to different stresses (heat, compression, torsion, and oscillatory shear) were measured after 1 and 6 weeks of storage. FF cheeses made with the control milks and milks processed at 10 °C/34 MPa or 10 °C/103 MPa were softer and less rigid, and had the lowest visco-elastic properties and the highest meltabilities of all the cheeses. Microfluidization of the cheese milk did not improve the melt or rheology of LF cheeses. Microfluidization of milk with fat in the liquid state at higher pressures resulted in smaller lipid droplets that altered the component interactions during the formation of the cheese matrix and resulted in LF and FF Mozzarella cheeses with poor melt and altered rheology.     

提高成熟温度加快Mozzarella干酪成熟的研究

制作2批Mozzarella干酪A和B，分别在4℃(A)和7℃(B)下成熟，观察其在成熟期间的变化及测定可溶性N的含量等指标，可知在7℃下成熟的干酪在制作后30d的蛋白水解性、功能特性等和4℃下成熟50d的干酪无显著差异，而和7℃下成熟50d的干酪有显著差异。说明成熟温度显著影响干酪的蛋白水解性。在7℃下贮藏的Mozzarella干酪成熟30d可达到4℃下贮存50d的成熟度，即将成熟温度从4℃提高到7℃，可将成熟期缩短20d左右。     

Mozzarella cheese: 40 years of scientific advancement

An overview is presented of selected advances in the science of mozzarella cheese during the past 40 years. This is not intended to be a comprehensive review but rather to focus on several key milestones in the ongoing quest to understand the physicochemical basis for cheese structure and function. In keeping with the theme of this symposium, this paper highlights the pivotal role that Professor P. F. Fox had in shaping my understanding of mozzarella structure–function and the direction of my research during the past decade. The unfolding of mozzarella science has ebbed and flowed, with significant advances being made early on that were not fully recognized until much later.