利用3种凝固剂制作新鲜软质大豆干酪的工艺研究

以豆乳为原料,分别以葡萄糖酸内酯、氯化镁和木瓜蛋白酶为凝固剂制作新鲜软质大豆干酪。用正交试验法对发酵剂、凝固剂及食盐的添加量等参数进行优化,并将3种大豆干酪的主要理化指标及感官与牛奶新鲜软质干酪进行比较。结果表明,以葡萄糖酸内酯为凝固剂制备新鲜软质大豆干酪的最适工艺参数为发酵剂添加量0.020%、葡萄糖酸内酯添加量0.20%、食盐添加量1.0%;氯化镁为凝固剂的最适工艺参数为发酵剂添加量0.020%、氯化镁添加量0.20%、食盐添加量1.0%;木瓜蛋白酶为凝固剂的最适工艺参数为发酵剂添加量0.010%、CaCl2添加量0.02%、木瓜蛋白酶添加量0.05%、食盐添加量1.0%。3种大豆干酪的水分含量相近,木瓜蛋白酶大豆干酪感官得分最高,氯化镁大豆干酪的蛋白含量最高,而葡萄糖酸内酯大豆干酪的产率最高。与相同工艺下制作出的牛乳新鲜软质干酪相比,新鲜软质大豆干酪蛋白质含量与之相近,脂肪含量只有牛乳干酪的1/3,水分含量和出品率高于牛乳干酪,而感官评分上大豆干酪略低。新鲜软质大豆干酪可作为一种牛乳新鲜软质干酪的低脂保健型替代品。     

Effects of blends of camel and calf chymosin on proteolysis,residual coagulant activity,microstructure, and sensory characteristics of Beyaz peynir

Beyaz peynir, a white brined cheese, was manufactured using different blends of camel chymosin (100, 75, 50, 25, and 0%) with calf chymosin and ripened for 90 d. The purpose of this study was to determine the best mixture of coagulant for Beyaz peynir, in terms of proteolysis, texture, and melting characteristics. The cheeses were evaluated in terms of chemical composition, levels of proteolysis, total free amino acids, texture, meltability, residual coagulant activity, microstructure, and sensory properties during 90 d of ripening. Differences in the gross chemical composition were statistically significant for all types of cheeses. Levels of proteolysis were highly dependent on the blends of the coagulants. Higher proteolysis was observed in cheeses that used a higher ratio of calf chymosin. Differences in urea-PAGE and peptide profiles of each cheese were observed as well. Meltability values proportionally increased with the higher increasing levels of calf chymosin in the blend formula. These coagulants had a slight effect on the microstructure of cheeses. The cheese made with camel chymosin had a harder texture than calf chymosin cheese, and hardness values of all cheese samples decreased during ripening. The cheeses with a high ratio of calf chymosin had higher residual enzyme activity than those made with camel chymosin. No significant difference in sensory properties was observed among the cheeses. In conclusion, cheeses made with a high level of calf chymosin had a higher level of proteolysis, residual coagulant activity, and meltability. The cheeses also had a softer texture than cheeses made with a high content of camel chymosin. Camel chymosin may be used as a coagulant alone if low or limited levels of proteolysis are desired in cheese.     

Effect of camel chymosin on the texture,functionality, and sensory properties of low-moisture,part-skim Mozzarella cheese

The objective of this study was to compare the effect of coagulant (bovine calf chymosin, BCC, or camel chymosin, CC), on the functional and sensory properties and performance shelf-life of low-moisture, part-skim (LMPS) Mozzarella. Both chymosins were used at 2 levels [0.05 and 0.037 international milk clotting units (IMCU)/mL], and clotting temperature was varied to achieve similar gelation times for each treatment (as this also affects cheese properties). Functionality was assessed at various cheese ages using dynamic low-amplitude oscillatory rheology and performance of baked cheese on pizza. Cheese composition was not significantly different between treatments. The level of total calcium or insoluble (INSOL) calcium did not differ significantly among the cheeses initially or during ripening. Proteolysis in cheese made with BCC was higher than in cheeses made with CC. At 84 d of ripening, maximum loss tangent values were not significantly different in the cheeses, suggesting that these cheeses had similar melt characteristics. After 14 d of cheese ripening, the crossover temperature (loss tangent = 1 or melting temperature) was higher when CC was used as coagulant. This was due to lower proteolysis in the CC cheeses compared with those made with BCC because the pH and INSOL calcium levels were similar in all cheeses. Cheeses made with CC maintained higher hardness values over 84 d of ripening compared with BCC and maintained higher sensory firmness values and adhesiveness of mass scores during ripening. When melted on pizzas, cheese made with CC had lower blister quantity and the cheeses were firmer and chewier. Because the 2 types of cheeses had similar moisture contents, pH values, and INSOL Ca levels, differences in proteolysis were responsible for the firmer and chewier texture of CC cheeses. When cheese performance on baked pizza was analyzed, properties such as blister quantity, strand thickness, hardness, and chewiness were maintained for a longer ripening time than cheeses made with BCC, indicating that use of CC could help to extend the performance shelf-life of LMPS Mozzarella.     

Influence of coagulant level on proteolysis and functionality of mozzarella cheeses made using direct acidification

Nonfat (0% fat), reduced-fat (11% fat), and control (19% fat) mozzarella cheeses were made using direct acidification to test the influence of three levels (0.25X, 1X, and 4X) of coagulant concentration on proteolysis, meltability and rheological properties of cheeses during 60 d of storage at 5 degrees C. Changes in meltability, level of intact alpha(s1)-casein and beta-casein (by capillary electrophoresis), 12.5% TCA-soluble nitrogen, and complex modulus were measured. There were differences in rate of proteolysis and functional properties as a function of fat content of the cheese, but some of these differences could be attributed to differences in moisture contents of the cheeses. As fat level decreased, the percent moisture-in-nonfat-substance of the cheeses also decreased. Cheeses with the lower fat contents (and consequently the lowest moisture-in-nonfat-substance content) had slower rates of proteolysis. Fat content influenced the complex modulus of the cheese, with the biggest effect occurring when fat content was reduced from 11 to 0%. Coagulant level had only a small effect on initial modulus. Cheeses became softer during storage, and the decrease in modulus was influenced by the level of coagulant. At 0.25X, there was very little decrease in modulus after 60 d, while at 1X and 4X coagulant levels the softening of the cheese was more evident. The influence of coagulant level and fat content on cheese melting was similar to their effects on complex modulus. In general, higher fat contents promoted more melting and so did higher coagulant levels. Melting increased during storage although very little change was observed in the nonfat cheese.     

Interaction between sodium chloride and texture in semi-hard Danish cheese as affected by brining time,dl-starter culture,chymosin type and cheese ripening

Reduced NaCl in semi-hard cheeses greatly affects textural and sensory properties. The interaction between cheese NaCl concentration and texture was affected by brining time (0–28 h), dl-starter cultures (C1, C2, and C3), chymosin type (bovine or camel), and ripening time (1–12 weeks). Cheese NaCl levels ranged from <0.15 to 1.90% (w/w). NaCl distribution changed during ripening; migration from cheese edge to core led to a more homogeneous NaCl distribution after 12 weeks. As ripening time increased, cheese firmness decreased. Cheeses with reduced NaCl were less firm and more compressible. Cheeses produced with C2 were significantly firmer than those produced with C1; cheeses produced with C3 had higher firmness and compressibility. In NaCl reduced cheese, use of camel chymosin as coagulant resulted in significantly higher firmness than that given using bovine chymosin. Overall, cheese NaCl content is reducible without significant textural impact using well-defined starter cultures and camel chymosin.     

The use of buttermilk as a raw material for cheese production

Buttermilk is dairy by‐product of butter production. The study aimed to analyse the quality properties of commercial buttermilk and its usefulness as a raw material for Quark cheese production. Within the study, 6 kinds of buttermilk were tested and used for cheese production. Evaluation of cheese quality included physico‐chemical, rheological and sensory analyses. Buttermilk properties were varied and corresponded with the diversification of cheese characteristics. Production yield was 17.2–22.7%, water content 68.1–75.8% and pH 4.09–4.43. The texture was diversified; however, all samples had good sensory quality. The research has shown that buttermilk is a good raw material for cheese production.     

植物油脂替代动物油脂 在再制奶油干酪中的应用

以奶油干酪为基料,研究不同植物油脂替代动物油脂在再制奶油干酪中的应用。测定干酪样品的质构、色度、油脂析出性、融化性及感官评定,并进行比较分析。实验结果表明,添加橄榄油和小麦胚芽油的干酪硬度和涂抹性与对照组相近(P>0.05);添加橄榄油、小麦胚芽油、油茶籽油和米糠油的干酪粘聚力与对照组接近,减少了15.23%~26.68%;添加橄榄油和油茶籽油的干酪粘合性与对照组相差19.68%、33.16%,差异显著(P<0.05)。添加油茶籽油、橄榄油、米糠油、小麦胚芽油和亚麻籽油的干酪色度与对照组十分相近(P>0.05)。在油脂析出性上,添加玉米油、米糠油、橄榄油、油茶籽油和南瓜籽油的实验组品质均得到了改善。添加橄榄油、亚麻籽油的样品组在融化性能上与对照组差异不显著(P>0.05),仅减少了1.15%和1.85%。添加油茶籽油、橄榄油、小麦胚芽油的样品组受到认可,得分高于对照组。综上,橄榄油组与对照组在各项指标上相似度最高,是较好的替代油脂。     

藜麦-小麦混合粉面团特性及藜麦馒头加工工艺

探讨不同比例的藜麦全粉对高筋小麦粉面团流变学特性的影响,确定藜麦全粉馒头中最佳的藜麦全粉添加比例并进行馒头加工工艺的优化。通过混合实验仪和吹泡仪对面团流变学特性进行测定,以馒头的感官评价和质构特性为评价指标,对藜麦全粉馒头的酵母添加量、发酵时间和醒发时间进行优化。结果表明：藜麦全粉馒头的最佳藜麦全粉添加量为15%;当酵母添加量0.75%、发酵时间100 min、醒发时间15 min时,藜麦全粉馒头的感官评价总分达到最高值86.58,比容达到最高值3.02 mL/g,同时,硬度、咀嚼性和胶着性分别达到最低值9.76、45.53 N和6.66 N。     

Use of powdered vegetable coagulant in the manufacture of ewe's milk cheeses

A powdered vegetable coagulant obtained from the cardoon Cynara cardunculus and characterised as free of viable micro‐organisms, soluble and stable without the need for preservatives was evaluated, and compared with crude aqueous extract, in batches of Los Pedroches cheese, by determining various chemical, biochemical, microbiological and sensory parameters. Parameters were monitored over 3 months of ripening. High casein hydrolysis was observed after 2 days of ripening. The soluble nitrogen values reached at the end of ripening were over 34% of the total nitrogen in cheeses produced with both types of coagulant. For most parameters studied, no differences were observed between the two types of coagulant, although higher counts were observed for some microbiological groups in cheeses produced with crude aqueous extracts. The sensory quality of cheeses was practically identical with both types of coagulant. © 2002 Society of Chemical Industry     

大豆-坚果奶酪类似物的制备及其性质研究

该研究采用大豆乳、腰果乳及巴旦木蛋白为原料制备一种奶酪类似物,目的是确定最佳工艺配方以制备出高品质的大豆-坚果奶酪类似物,然后评价其理化性质、感官特性、储藏稳定性和消化特性。研究结果显示：具有最佳品质的大豆-坚果奶酪类似物基本配方为（皆为质量分数）：腰果乳50.00%,大豆乳50.00%;并以植物乳质量为基准,依次添加植物油3.09%（椰子油与葵花籽油比例为7:3）、巴旦木蛋白2.01%、TG酶0.33%、柠檬酸0.10%、乳酸0.10%;以凝乳质量为基准,添加胶体1.08%、蔗糖4.00%。大豆-坚果奶酪类似物硬度值0.88 N、整体感官评分7.71分,可以与商品化动物奶酪相媲美。此外,随着储藏时间增加其硬度值从0.94 N增加到1.15 N,无明显变硬和析水现象。体外消化结果显示其蛋白电泳条带在肠道消化180 min后全部消失,游离脂肪酸释放速率为60%。因此,制备的大豆- 坚果奶酪类似物营养价值高,具有较佳的感官品质,储藏稳定性好且蛋白易于消化,能够作为动物奶酪的替代物以满足人们对奶酪的需求。     

Yield,changes in proteolysis,and sensory quality of Prato cheese produced with different coagulants

The objective of this research was to compare the effect of 2 fungal proteases, one that is already commercially established as a milk-clotting agent and another produced at the laboratory scale, on Prato cheese composition, protein and fat recovery, yield, and sensory characteristics. Cheeses were produced according to the traditional protocol, using protease from the fungus Thermomucor indicae-seudaticae N31 and commercial coagulant from Rhizomucor spp. as clotting agents. A 2 × 6 factorial design with 3 replications was performed: 2 levels of coagulants and 6 levels of storage time. After 5, 12, 19, 33, 43, and 53 d of refrigerated storage (12°C), cheeses were monitored for proteolysis, firmness, and casein degradation by capillary electrophoresis. Sensory acceptance was evaluated after 29 d of manufacturing. The different coagulants did not statistically affect Prato cheese composition, protein and fat recovery, and yield. Both cheeses presented good sensory acceptance. Proteolysis increased and firmness decreased for both cheeses during the storage time, as expected for Prato cheese. Caseins were well separated by capillary electrophoresis and the results showed, with good resolution, that the cheeses exhibited similar protein hydrolysis profile. Both cheeses presented good sensory acceptance. The gathered data showed that the protease from T. indicae-seudaticae N31 presented similar action compared with the commercial enzyme, indicating its efficiency as clotting agent for Prato cheese manufacture.     

Utilization of front-face fluorescence spectroscopy for analysis of process cheese functionality

The purpose of this study was to evaluate the feasibility of front-face fluorescence spectroscopy (FFFS) to predict the meltability of process cheese spreads or products. Twenty-seven commercial samples from 3 manufacturers were used in this study. Each sample was analyzed using dynamic stress rheometry, which was used to calculate the meltability index (temperature at tandelta = 1). Additionally, fluorescence spectra of tryptophan (excitation: 290 nm; emission: 305 to 400 nm) were collected on each sample at 20 degrees C using a front-face accessory. Fluorescence spectrum for each sample consisted of an average of 36 scans (6 scans performed on 6 replicates). The spectral data set consisted of normalized and mean-centered spectra from all the samples. Multivariate statistical analysis was used to correlate spectral data with cheese meltability index as measured by dynamic stress rheometry. A prediction model was developed using partial least square regression and was calibrated using a cross-validation method. A correlation coefficient of 0.93 was obtained between fluorescence spectra and cheese meltability. The regions 335 to 350 nm and 385 to 400 nm had the highest correlation to cheese meltability. A negative correlation between the peak height of tryptophan (335 to 350 nm) and cheese meltability index was observed. This correlation may be due to presence of tryptophan residues in a more hydrophobic environment in stronger emulsions as compared with a more polar environment in weak emulsions. These results indicate that the melt properties of process cheese spreads or products are related to molecular structure that can be measured using FFFS. Hence, FFFS can be used as an analysis technique to predict process cheese meltability.     

Study of organic acids, volatile fraction and caseins of a new Halloumi-type cheese during ripening in whey brine

Organic acids, fat hydrolysis, volatile compounds and sensory characteristics of a new brine cheese which combines characteristics of Halloumi and Feta cheeses during its ripening in whey brine (100g NaCl L⁻¹) were studied. Thermotolerant protease of Mucor miehei as a coagulant enzyme and a mixture of thermotolerant starter cultures Enterococcus faecium 0165 (0.5% w/w) and Lactobacillus casei 80 10D were used. Good quality new Halloumi-type cheese was produced with higher proteolysis than traditional Halloumi cheese kept in whey brine. The volatile compounds identified comprised alcohols, aldehydes, ketones, acids, esters, hydrocarbons and sulphur compounds. Ethanol was the dominant volatile compound determined. Lactic acid was the dominant acid produced; its concentration increased during ripening, reaching a maximum value of 9929 mg kg⁻¹ at day 30. Acetic acid was also found in high amounts, which increased during cheese ripening. Lipolysis of cheese was not intense. The most abundant acids of the mature cheese were palmitic, oleic and acetic acid. The Halloumi-type cheese scored higher in the sensory analysis when fresh than did the mature cheese.     

Exploring the milk-clotting properties of a plant coagulant from the berries of S. elaeagnifolium var. Cavanilles

Solanum elaeagnifolium (trompillo or silverleaf nightshade) is an endemic plant from the northeast of Mexico and southwest of United States. This plant is considered as a weed with negative impact on agriculture and livestock production. Nevertheless, in some places of Chihuahua, Mexico, the berries of this plant have been used for decades in the manufacture of artisanal filata-type asadero cheese. The milk-clotting enzyme of S. elaeagnifolium has been scarcely studied; for this reason, the aim of this work was to explore some properties of this plant coagulant. Protein extracts (PEs) from ripe berries of S. elaeagnifolium were characterized by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and assessed for milk-clotting activity. In addition, milk gels and miniature fresh-type cheeses manufactured with the plant coagulant were analyzed for their texture properties. The PE from the berries of S. elaeagnifolium contained 8 proteins with molecular weights from 22 to 62 kDa. Some bands observed in the PE had similar molecular weights as reported for aspartic proteinases such as chymosin. The extracts from the berries of S. elaeagnifolium had lower milk-cloting activities than observed with rennin or chymosin, but this plant coagulant produced firm gels under acidic conditions. The mini-cheeses manufactured with this coagulant were softer than cheeses manufactured with rennin or chymosin. For this reason, the coagulant from the ripe berries of S. elaeagnifolium could be suitable not only for the manufacture of filata-type cheeses but also for the manufacture of soft cheeses such as cream cheese. PRACTICAL APPLICATION: Silverleaf nightshade (trompillo) is a plant that grows in northern Mexico and the southwestern United States. This plant is considered a weed with negative impact on agriculture and livestock production. However, the ripe berries of this plant have been used by ancient Pima Indians as a substitute of rennin in making cheese. In this work, it was observed that this plant coagulant had lower activity and produced softer cheeses than did rennin or chymosin. For this reason, the coagulant from berries of S. elaeagnifolium could be used for the manufacture of soft cheeses such as cream cheese.     

Influence of carboxymethylcellulose on the physicochemical,rheological and sensory attributes of a low‐fat Domiati cheese

The physicochemical, rheological and sensory attributes of a low‐fat Domiati cheese produced using carboxymethylcellulose (CMC), a hydrocolloid, at 0.4, 0.6, 0.8 and 1% (w?w) were examined during the ripening period. Results indicated that, as the carboxymethylcellulose content of cheese milk increased, cheese yield and moisture of low‐fat Domiati cheese significantly increased but the protein, salt and fat values significantly decreased. Rheological parameters were significantly lower in cheeses made with CMC. With regard to the sensory properties of the cheeses, low‐fat Domiati cheese made with 1% (w?w) CMC recorded the highest scores for sensory attributes.     

Influence of the technological properties of vegetable rennet (Cynara cardunculus) on the physicochemical,sensory and rheological characteristics of ‘Torta del Casar’ cheese

The purpose of this work was to investigate the influence of technological properties of vegetable rennet (Cynara cardunculus) on the characteristics of ‘Torta del Casar’ cheese to establish the parameters that can be useful for quality control of this coagulant. The physicochemical, microbial, texture and sensory properties of the cheeses were evaluated and correlated to clotting and proteolytic activities of the vegetable rennets used for their manufacture. The level of in vitro degradation of α‐casein and κ‐casein/β‐casein degradation ratio was found to be good tools to predict the effect of vegetable rennet on the rheological properties of these cheeses.     

Influence of residual milk-clotting enzyme and proteolysis on melting properties of soft cheese

In this work, we assessed the influence of coagulant residual activity and primary proteolysis on Cremoso Argentino cheese melting properties. For that purpose, we made Cremoso soft cheeses using different amounts of coagulant, and also obtained samples in which milk-clotting enzyme was inactivated. Primary proteolysis correlated with residual activity of coagulant in early stages of cheese ripening; however, it was similar in all cheeses after 30 days. The hydrolysis of caseins did not significantly affect the melting ability of the cheeses, expressed as the area increase after heating samples under standardized conditions. Samples with similar proximate composition showed some changes in meltability; those seemed related to pH evolution during ripening.     

Influence of milk-clotting enzyme concentration on the alphas1-casein hydrolysis during soft cheeses ripening.

We studied the influence of the dose of milk-clotting enzyme on alphas1-CN degradation, soluble nitrogen production, and sensory profile for an Argentinean soft cheese: Cremoso Argentino. Five different types of cheeses were produced: 1) control cheeses with normal technology, 2) cheeses with inactivated milk-clotting enzyme, 3) cheeses with inactivated milk-clotting enzyme, without starter (acidified with glucono delta lactone), 4) cheeses with a half dose of milk-clotting enzyme, and 5) cheeses with a double dose of milk-clotting enzyme. Proteolysis was assessed by isoelectric focusing electrophoresis of the insoluble fraction at pH 4.6, followed by densitometric quantification. Soluble nitrogen at pH 4.6, expressed as a percentage of total nitrogen and defined as ripening index was also performed. A sensorial panel evaluated the cheeses at the end of ripening. The hydrolysis level of alphas1-CN depended on the milk-clotting enzyme dose used in cheese making. Cheeses without active coagulant did not show degradation at the end of ripening, while cheeses with half and whole doses showed proportional degradations to coagulant dose. Cheese with a double dose of coagulant did not show higher alphas1-CN hydrolysis than normal cheese. No difference was found between cheeses with and without microbiological starter, indicating that the selected culture, composed of thermophilic strains, was unable to attack the whole casein. A high linear correlation was found between ripening index and the relation Sensorial characteristics of cheeses agree with objective analysis. Cheeses without active coagulant were hard and crumbly, while cheeses with normal dose were soft and creamy.