益生性植物乳杆菌对切达干酪挥发性风味形成的影响

将分离自西藏灵菇的益生性植物乳杆菌1-2通过在杀菌乳中添加活菌数8.0、9.0（lg（CFU/mL））和在排乳清后添加于凝乳块8.0（lg（CFU/g））的方式分别加入到切达干酪中,考察植物乳杆菌活菌数量、添加方式和成熟时间对干酪挥发性风味物质组成的影响。利用固相微萃取和气相色谱-质谱联用技术检测出对照组干酪的风味物质26种,益生菌干酪组风味物质30种,添加植物乳杆菌1-2可产生乙苯、十二烷、己醇和丙酮4种挥发性风味物质。成熟时间对干酪风味的影响最大,随成熟时间的延长,益生菌干酪组中苯含量显著增加,而对照组干酪在成熟12周时才检测到苯。益生菌添加量和添加方式对干酪挥发性风味的影响相似,丁酸受益生菌活菌数和添加方式的影响最大,益生菌干酪组成熟12周时,丁酸含量最高达对照组的3.96倍（P＜0.05）。在杀菌乳中添加益生菌活菌数8.0（lg（CFU/mL））组和9.0（lg（CFU/mL））组干酪中挥发性风味物质含量有显著差异,但在杀菌乳中添加高活菌数9.0（lg（CFU/mL））和在排乳清后添加低活菌数8.0（lg（CFU/g））于凝乳块中对干酪挥发性风味的形成具有相似的影响。本研究结果为改进益生菌干酪的加工工艺和风味品质提供了实验依据。     

不同体细胞数原料乳对契达干酪成熟过程中蛋白水解的影响

为探讨原料乳中体细胞数(SCC)对契达干酪成熟过程中蛋白质水解的影响,选择SCC分别是5.6×104(LSCC)、48.8×104(MSCC)、476.1(HSCC)×104 个/mL的原料乳制作契达(cheddar)干酪,得到LSCC、MSCC、HSCC组干酪,并对各组干酪成熟过程中蛋白质水解的各项指标进行了测定.结果显示3组干酪成熟过程中蛋白的水解产物不同,LSCC组干酪品质更好.     

不同体细胞数原料乳对UHT贮存期间蛋白和脂肪水解的影响

不同体细胞数(21.4×104mL-1,75.8×104mL-1,118.1×104mL-1和216.2×104mL-1)原料乳生产的4组UHT乳在37℃贮存84d,对其贮存期间的蛋白水解及脂肪水解进行研究。结果表明,4组UHT乳贮存期间的蛋白水解速率无显著性差异(P>0.05),原料乳体细胞数并未对蛋白水解造成影响;4组UHT乳贮存期间的脂肪水解速率具有显著性差异(P<0.005),原料乳体细胞数与脂肪水解速率间存在极明显的正相关(R=0.9886,P<0.05)。     

解淀粉芽孢杆菌GSBa-1凝乳酶在马苏里拉干酪中的应用

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。     

干酪乳杆菌和植物乳杆菌对广式腊肠品质的影响

将不同添加量的干酪乳杆菌(Lactobacillus casei)、植物乳杆菌(Lactobacillus plantarum)和混合两种菌接种到广式腊肠中,以不添加菌种的广式腊肠为对照,研究添加菌种后对腊肠水分、pH值、质构、色泽、感官以及风味的影响。结果表明:当干酪乳杆菌菌液浓度为1×106 CFU/mL、添加量为3%时,与对照组相比,水分含量增加,pH值降低,亮度、红度和黄度值均增加,弹性和内聚性都有所提高,且感官评分最优,在挥发性风味检测中,酯类物质含量增加,且产生己醛,表明接种干酪乳杆菌不会对腊肠的质构和感官产生不利影响,并且增加了腊肠的色泽和风味,改善了腊肠的品质。     

原料乳中干酪非发酵剂乳酸菌的研究

非发酵剂乳酸菌（NSLAB）是天然存在于原料乳中的一类独特的微生物,一般在干酪成熟过程中发挥作用;着重阐述了非发酵剂乳酸菌（NSLAB）的定义、分类状况,分析其对干酪风味形成、质构变化等的影响,提出了研究非发酵剂乳酸菌应注意的问题,为研究干酪的风味多样性提供科学思路。     

瑞士乳杆菌对契达干酪成熟期间所产ACE抑制肽的影响及其消化稳定性

为明确瑞士乳杆菌对契达干酪中血管紧张素转换酶（angiotensin-converting enzyme,ACE）抑制肽活性的影响,以蛋白质水解度和ACE抑制率为指标,与干酪乳杆菌组、鼠李糖乳杆菌组和空白组干酪进行对照,研究瑞士乳杆菌对干酪成熟期间蛋白质水解及ACE抑制活性的影响,并对ACE抑制活性最高时期的干酪进行消化稳定性研究。结果表明：成熟期间,3 组益生菌干酪的活菌数无明显差异（P＞0.05）,但均高于空白组;益生菌干酪的蛋白质水解程度和ACE抑制活性显著高于空白组（P＜0.05）,其中瑞士乳杆菌干酪的蛋白质水解程度最强,活性最高（79.71%）。模拟消化后,瑞士乳杆菌干酪活菌数降低14.30%,ACE抑制活性显著增加（P＜0.05）,达到86.06%,多肽质量浓度增加至2.81 mg/mL;研究不同分子质量超滤组分消化后的ACE抑制活性发现,其中大于10 kDa的多肽活性升高,小于10 kDa的活性下降。此外,添加瑞士乳杆菌不影响干酪的整体可接受性。因此,瑞士乳杆菌能促进干酪ACE抑制肽的产生并提高其活性,消化后活性的升高主要与大分子肽的降解有关。     

不同乳酸菌发酵对菠萝浆品质的影响

以菠萝浆为原料,添加干酪乳杆菌、植物乳杆菌和肠膜状明串珠菌单一或复配发酵,测定发酵24 h后的蛋白酶酶活、超氧化物歧化酶（SOD）酶活、总酚含量、DPPH自由基清除能力、挥发性物质及冻干成粉后的维生素C含量。结果表明,乳酸菌单一发酵效果整体上要好于复配发酵,干酪乳杆菌单独发酵可使菠萝浆的SOD酶活保持在97.70 U/g,总酚含量达到最高（0.51 mg没食子酸当量（GAE）/g）;植物乳杆菌单独发酵菠萝浆时蛋白酶活性最好（821.00 U/mL）,同时DPPH自由基清除能力最高,达到5.37 μmol Trolox当量（TE）/g;肠膜状明串珠菌单独发酵组的维生素C含量最高,为4.73 mg/g;菠萝浆经干酪乳酸菌和植物乳杆菌单独发酵后,鉴定出的挥发性成分分别达到29和28种。综上,选择干酪乳杆菌或植物乳杆菌单独发酵菠萝浆能获得较好的品质。     

辅助发酵剂加速Provolone干酪成熟的研究

将瑞士乳杆菌6024作为辅助发酵剂添加到Provolone干酪中,加速Provolone干酪成熟,研究了其对干酪游离氨基酸、游离脂肪酸、质构特性、电镜、风味物质的影响。结果表明,瑞士乳杆菌6024作为辅助发酵剂对干酪中游离脂肪酸质量分数没有显著影响,但能显著增加干酪游离氨基酸质量分数,60 d时达到对照组90 d时的质量分数,此时干酪的质构特性、微观结构、风味物质与对照组90 d时差异不显著。由此可知,瑞士乳杆菌6024作为辅助发酵剂可加速Provolone干酪的成熟,缩短成熟时间。     

解淀粉芽孢杆菌GSBa-1凝乳酶对羊奶干酪成熟特性的影响

为探究解淀粉芽孢杆菌GSBa-1凝乳酶制备的羊奶干酪(干酪B)成熟特性的变化,以采用商业凝乳酶和同批次羊奶制作的干酪(干酪A)为对照组,比较两组干酪在60d成熟期主要组分、质构特性、微生物指标及风味物质的变化。结果表明,两组干酪得率相差不大。成熟期间干酪的水分、蛋白质及脂肪含量呈先上升后下降趋势,干酪B始终高于干酪A;干酪游离氨基酸总量在成熟期间呈先下降后上升趋势,且干酪B中苯丙氨酸、天冬氨酸、异亮氨酸、甲硫氨酸、丝氨酸含量高于干酪A。成熟前期干酪B质构特性优于干酪A。干酪A成熟后乳酸乳球菌数量增加了(5.22±0.02)%,干酪B无显著变化(P>0.05)。成熟期内,两组干酪中挥发性风味物质种类和含量均增加,但干酪B中的壬酸、辛醇、2-庚酮、2-壬酮、二甲基砜使羊奶干酪风味独特、浓郁。因此,GSBa-1凝乳酶具备替代商业凝乳酶用于羊奶干酪生产的潜力,可对干酪风味的形成和品质的提升起到一定促进作用。     

Effect of somatic cell count on Prato cheese composition

The objective of this research was to evaluate the effect of 2 levels of somatic cell counts (SCC) in raw milk on Prato cheese composition, protein and fat recovery, cheese yield, and ripening. A 2 × 6 factorial design with 3 replications was performed in this study: 2 levels of SCC and 6 levels of storage time. Initially, 2 groups of dairy cows were selected to obtain low (<200,000 cells/ mL) and high (>600,000 cells/mL) SCC in milks that were used to manufacture 2 vats of cheese: 1) low SCC and 2) high SCC. Milk, whey, and cheese compositions were evaluated; clotting time was measured; and cheese yield, protein recovery, and fat recovery were calculated. The cheeses were evaluated after 5, 12, 19, 26, 33, and 40 d of ripening according to pH, moisture, pH 4.6 soluble nitrogen, 12% trichloroacetic acid soluble nitrogen as a percentage of total nitrogen, and firmness. High-SCC milk presented significantly higher total protein and nonprotein nitrogen and lower true protein and casein concentrations than did low-SCC milk, indicating an increased whey protein content and a higher level of proteolysis. Although the pH of the milk was not affected by the somatic cell level, the cheese obtained from high-SCC milk presented significantly higher pH values during manufacture and a higher clotting time. No significant differences in cheese yield and protein recovery were observed for these levels of milk somatic cells. The cheese from high-SCC milk was higher in moisture and had a higher level of proteolysis during ripening, which could compromise the typical sensory quality of the product.     

原料乳体细胞数不同对契达干酪产出量、质构及感官的影响

用体细胞数(SCC)分别是5.6×104,48.8×104,476.1×104 mL-1的原料乳制作契达干酪,得到LSCC,MSCC,HSCC组干酪。从干酪真正产出量来看:LSCC组>MSCC组>HSCC组(P<0.05)。在干酪成熟过程中,质构与SCC在P<0.01的水平下负相关,其中硬度、剪切力相关系数分别为0.5482和1.3977。感官评定结果表明,HSCC组干酪有酸味,且组织状态软而粘。同时对干酪成熟过程中的水溶性氮和脂解进行了测定,其结果是:WSN/TN与SCC在P<0.01水平下线性相关,相关系数为0.4261;HSCC组干酪的FFA在P<0.05的水平下显著高于LSCC和MSCC组干酪,且FFA与SCC在P<0.0001的水平下正相关。     

Texture,flavor, and sensory quality of buffalo milk Cheddar cheese as influenced by reducing sodium salt content

The adverse health effects of dietary sodium demand the production of cheese with reduced salt content. The study was aimed to assess the effect of reducing the level of sodium chloride on the texture, flavor, and sensory qualities of Cheddar cheese. Cheddar cheese was manufactured from buffalo milk standardized at 4% fat level by adding sodium chloride at 2.5, 2.0, 1.5, 1.0, and 0.5% (wt/wt of the curd obtained). Cheese samples were ripened at 6 to 8°C for 180 d and analyzed for chemical composition after 1 wk; for texture and proteolysis after 1, 60, 120, and 180 d; and for volatile flavor compounds and sensory quality after 180 d of ripening. Decreasing the salt level significantly reduced the salt-in-moisture and pH and increased the moisture-in-nonfat-substances and water activity. Cheese hardness, toughness, and crumbliness decreased but proteolysis increased considerably on reducing the sodium content and during cheese ripening. Lowering the salt levels appreciably enhanced the concentration of volatile compounds associated with flavor but negatively affected the sensory perception. We concluded that salt level in cheese can be successfully reduced to a great extent if proteolysis and development of off-flavors resulted by the growth of starter and nonstarter bacteria can be controlled.     

Proteolysis and texture of hard ewes' milk cheese during ripening as affected by somatic cell counts

Ewes' milk samples with low (<500,000 ml(-1)), medium (1,000,000-1,500,000 ml(-1)) and high (> 2,500,000 ml(-1)) somatic cell counts (SCC) were used to manufacture hard ewes' cheese using the Zamorano cheese manufacturing protocol. Cheeses that had been ripened for 1, 2 and 3 months were used to obtain isoelectric ovine casein that was analysed by capillary electrophoresis. The texture of the cheeses during ripening was determined instrumentally using the Warner-Bratzler maximum shear force and assessed for sensory qualities by consumers using hedonic tests. The study revealed that the pH value and the lactose content of the milk were affected by high SCC and that the coagulation properties were dependent on the somatic cell content. The protein and moisture contents of the cheeses were unaffected by SCC but a significant increase of pH with ripening time were observed in high-SCC cheeses. The results also pointed to a significant increase in proteolysis related to SCC levels, showing that intact casein, both alphas1 and beta-casein, decreased as the SCC of milk increased, and that the proteolytic fragments, mainly I-alphas1, increased with SCC levels. Significant differences in texture were found among the samples, the cheeses made with high levels of SCC being significantly less compact at each ripening time. The differences in texture were detected by the consumers, who reported defects in cheeses made with high levels of SCC. Indeed, high SCC cheeses were significantly less well accepted.     

Somatic cell recovery by microfiltration technologies: A novel strategy to study the actual impact of somatic cells on cheese matrix

The actual impact of the somatic cells in the dairy technology is still ill-defined, because the increase in milk somatic cell count, usually correlated with mastitis factors, impairs the raw milk composition, through mainly unwanted proteolysis and lipolysis. This study used microfiltration technologies for recovering high quantity of somatic cells and for clarifying their role in cheese quality. Three series of Swiss-type cheeses were manufactured by adding 0 (control), 4 × 10⁵ and 9 × 10⁵ somatic cells mL⁻¹. These cells were traced for the first time during the cheese making process by using adapted flow cytometry and real-time quantitative PCR. Proteolysis and lipolysis indices were measured throughout ripening time. Only a weak increase in lipolysis (+28%) and proteolysis (+8%) was observed in the highest somatic cell count cheese, despite 73% of the cells trapped within the cheeses. Our approach gives a new view of somatic cell role in cheese milk alteration.     

Effect of somatic cell count in goat milk on yield, sensory quality, and fatty acid profile of semisoft cheese

This study investigated the effect of somatic cell count (SCC) in goat milk on yield, free fatty acid (FFA) profile, and sensory quality of semisoft cheese. Sixty Alpine goats without evidence of clinical mastitis were assigned to 3 groups with milk SCC level of <500,000 (low), 500,000 to 1,000,000 (medium), and 1,000,000 to 1,500,000 (high) cells/mL. Thirty kilograms of goat milk with mean SCC levels of 410,000 (low), 770,000 (medium), and 1,250,000 (high) cells/mL was obtained for the manufacture of semisoft cheese for 2 consecutive weeks in 3 lactation stages. The composition of milk was analyzed and cheese yield was recorded on d 1. Cheese samples on d 1, 60, and 120 were analyzed for total sensory scores, flavor, and body and texture by a panel of 3 expert judges and were also analyzed for FFA. Results indicated that milk composition did not change when milk SCC varied from 214,000 to 1,450,000 cells/mL. Milk with higher SCC had a lower standard plate count, whereas coliform count and psychrotrophic bacteria count were not affected. However, milk components (fat, protein, lactose, casein, and total solids) among the 3 groups were similar. As a result, no significant differences in the yield of semisoft goat cheeses were detected. However, total sensory scores and body and texture scores for cheeses made from the high SCC milk were lower than those for cheeses made from the low and medium SCC milks. The difference in milk SCC levels also resulted in diverse changes in cheese texture (hardness, springiness, and so on) and FFA profiles. Individual and total FFA increased significantly during ripening, regardless the SCC levels. It is concluded that SCC in goat milk did not affect the yield of semisoft cheese but did result in inferior sensory quality of aged cheeses.     

Invited review: Plasmin protease in milk: current knowledge and relevance to dairy industry

Plasmin is by far the predominant and most completely studied endogenous protease in bovine milk. Plasmin-induced proteolysis can have either beneficial or detrimental effects on the texture and flavor of dairy products, depending on the extent of hydrolysis and type of dairy product. In cheese, the breakdown of protein can help develop desirable flavors and texture during ripening, whereas in pasteurized milk and ultra-high-temperature milk, proteolysis causes undesirable gelation. Plasmin is part of a complex protease-protease inhibitor system in milk that consists of active and inactive forms of the enzyme, activators, and inhibitors. Considerable research has been done to isolate and characterize components of the plasmin system, determine how they interact, develop and compare quantitation methods, and determine how they are affected by cow characteristics, processing conditions, other milk components, storage conditions, and bacterial proteases. Considerable research has focused on enhancing or minimizing the activity of plasmin system components. The intent has been to control protease activity in casein and whey fractions, depending on the final food or ingredient application. Controlling the activity of plasmin has a great potential to improve dairy product quality and reduce their processing costs.     

Flavor of Cheddar Cheese: A Chemical and Sensory Perspective

Considerable knowledge has been accumulated on the biochemical processes occurring during ripening of Cheddar cheese, which in turn has major consequences on flavor and texture development. The present review outlines major metabolic pathways and agents involved in the modification of milk constituents in Cheddar cheese ripening. Mechanisms of volatile flavor and off‐flavor production and recent developments in the analysis, both sensory and instrumental, of Cheddar flavor and flavor compounds are also detailed here.     

Ripened Semihard Cheese Covered with Lard and Dehydrated Rosemary (Rosmarinus officinalis L.) Leaves: Processing,Characterization, and Quality Traits

This study aimed to establish a manufacturing protocol and to characterize semihard cheese covered with lard and rosemary during ripening. After the manufacturing protocol was defined, the cheeses were produced with pasteurized and raw milk from Holstein cows, with and without (control) coating, and then ripened for 60 d. During this period the physicochemical properties, color, proteolysis, texture profile, and sensory acceptance were performed. The early‐ripening cheeses differed from the others in terms of color and moisture content. Multivariate statistical analysis separated chesses in groups differentiated by the effects of heat treatment of milk and ripening period. The ripened cheeses obtained from raw milk were sensorially more preferred. The coating gave the final products higher moisture content and favored color and texture characteristics. Consumer testing showed that the cheese obtained from raw milk and coated with lard and rosemary was the most preferred (acceptance of 82%) due to the specific coating of rosemary (aroma and flavor). This product has potential to add value and to diversify the production of semihard cheeses.     

Effect of milk centrifugation and incorporation of high-heat-treated centrifugate on the composition,texture, and ripening characteristics of Maasdam cheese

This study investigated the effect of centrifugation (9,000 × g, 50°C, flow rate = 1,000 L/h), as well as the incorporation of high-heat-treated (HHT) centrifugate into cheese milk on the composition, texture, and ripening characteristics of Maasdam cheese. Neither centrifugation nor incorporation of HHT centrifugate into cheese milk had a pronounced effect on the compositional parameters of any experimental cheeses, except for moisture and moisture in nonfat substance (MNFS) levels. Incorporation of HHT centrifugate at a rate of 6 to 10% of the total milk weight into centrifuged milk increased the level of denatured whey protein in the cheese milk and also increased the level of MNFS in the resultant cheese compared with cheeses made from centrifuged milk and control cheeses; moreover, cheese made from centrifuged milk had ～3% higher moisture content on average than control cheeses. Centrifugation of cheese milk reduced the somatic cell count by ～95% relative to the somatic cell count in raw milk. Neither centrifugation nor incorporation of HHT centrifugate into cheese milk had a significant effect on age-related changes in pH, lactate content, and levels of primary and secondary proteolysis. However, the value for hardness was significantly lower for cheeses made from milk containing HHT centrifugate than for other experimental cheese types. Overall, centrifugation appeared to have little effect on composition, texture, and ripening characteristics of Maasdam cheese. However, care should be taken when incorporating HHT centrifugate into cheese milk, because such practices can influence the level of moisture, MNFS, and texture (particularly hardness) of resultant cheeses. Such differences may have the potential to influence subsequent eye development characteristic, although no definitive trends were observed in the present study and further research on this is recommended.