胡麻籽分离蛋白的乳化及凝胶特性研究

为促进胡麻籽分离蛋白在食品工业中的应用,研究了pH、盐浓度、蛋白质浓度等因素对其乳化特性的影响,并利用TA-XT2i质构仪研究的胡麻籽分离蛋白的凝胶特性.结果发现在0.1%～0.7%范围内,随着蛋白质浓度的增加,乳化活力和乳化稳定性快速提升;当蛋白质浓度高于0.7%以后,乳化特性指标变化趋于平缓;在pH 4.0时,胡麻籽分离蛋白的乳化活力和乳化稳定性最差,降低或升高pH均有利于乳化活性逐渐增强;低浓度的NaCl(0.1 mol/L)能提高胡麻籽分离蛋白的乳化活力;但NaCl的添加对胡麻籽分离蛋白乳化稳定性有明显的损伤作用.质构分析表明10%的胡麻分离蛋白凝胶比较柔软,具有良好的弹性、内聚性、胶着性、咀嚼性和回复性.     

不同因素对白果蛋白持油性、持水性和起泡性的影响

以白果蛋白为研究对象,研究温度对其持油性、持水性和pH值、NaCl、蔗糖对其起泡性的作用规律。结果表明:当温度达到40℃时,白果蛋白持油性达到最大值(3.32%),当温度达到45℃时,持水性达到最大值2.97%;当NaCl浓度为0～0.4mol/L时,白果蛋白的起泡能力和泡沫稳定性与NaCl浓度呈正相关,当NaCl浓度高于0.6mol/L时,过高的离子强度使白果蛋白的起泡能力和泡沫稳定性降低;蔗糖的加入将大幅度提高白果蛋白的泡沫稳定性,而对起泡能力提高幅度较小;pH值对白果蛋白的起泡能力和泡沫稳定性影响较大,当pH值为3～11时,起泡性较差,当pH值小于3时,起泡能力和泡沫稳定性与pH值呈负相关,当pH值大于11时,起泡能力和泡沫稳定性与pH值呈正相关,当pH值等于13时达到最高值。     

脱酚棉籽分离蛋白功能特性研究

为拓宽棉籽蛋白在食品领域应用范围,对棉籽分离蛋白基本功能性质进行分析,结果显示,本试验条件下所得棉籽分离蛋白(CPI)属酸溶性蛋白质,在酸性条件下(pH1～4)溶解性较好(30%～50%),在近中性溶液中溶解性较差,仅20%左右;乳化性受pH值、离子强度和CPI浓度影响不显著;乳化能力较低,但所得乳状液非常稳定;起泡性受pH值、离子强度和CPI浓度等因素影响很大,在中性pH下最高;添加NaCl对CPI溶液起泡能力影响不大,但会显著影响CPI溶液泡沫稳定性,随NaCl浓度增加,溶液泡沫稳定性急剧降低。粘度分析表明,CPI溶液属典型非牛顿流体,有"剪切变稀"和"热变稀"特征。     

马铃薯淀粉废水蛋白的功能特性

以碱提酸沉法制备的马铃薯淀粉废水蛋白为原料,分别考察了pH值、NaCl浓度和温度对蛋白功能特性（溶解性、持水能力、乳化性及乳化稳定性、起泡性及泡沫稳定性）的影响。结果表明,pH值、NaCl浓度和温度对蛋白的功能特性产生不同程度的影响。在等电点（pH 4.0）时,马铃薯蛋白表现出最低的溶解性、持水性、乳化性、乳化稳定性及起泡性,而泡沫稳定性最好。在较低NaCl浓度（＜0.2 mol/L）时,蛋白溶解性、持水能力、乳化性和乳化稳定性随NaCl浓度的增加而提高,而高浓度的NaCl（＞0.2 mol/L）对上述性质具有抑制作用;蛋白的起泡性和泡沫稳定性在NaCl浓度为0.4 mol/L时具有最大值。在4～80 ℃范围内,蛋白质的各项功能性质随温度的升高均呈现先增加后降低的趋势,且溶解性、持水性、乳化稳定性、起泡性及泡沫稳定性在40 ℃时最佳,乳化性在60 ℃最佳。     

鹌鹑蛋功能特性及其影响因素

测定了鹌鹑蛋乳化性、起泡性、持水性等功能特性,并探讨了蔗糖、温度、pH值、氯化钠等因素对蛋白起泡性及其稳定性和蛋黄乳化性的影响。结果表明,鹌鹑蛋白的起泡性为7.33%,泡沫稳定性为63.49%,乳化性为41.51%,持水性约17.14%;鹌鹑蛋黄的起泡性为10%,泡沫稳定性为59.73%,乳化性为46.82%;鹌鹑全蛋液的起泡性为11%,泡沫稳定性为63.95%,乳化性为43.99%,持水性约18.28%。蔗糖能在一定范围内提高泡沫稳定性,适当加热可改善蛋白起泡性,蛋白起泡性随NaCl增加而有较大幅度提高。鹌鹑蛋黄乳化性随蔗糖浓度增大而提高,10～60℃内随温度升高而提高,加入氯化钠能明显提高蛋黄乳化性。pH值对蛋白起泡性和泡沫稳定性、蛋黄乳化性的影响均呈动态变化。     

葡萄籽蛋白的起泡性和泡沫稳定性研究

以葡萄籽为原料,首先采用碱提酸沉法提取葡萄籽蛋白,然后测定了其等电点,最后研究了蛋白浓度、pH值、NaCl浓度以及蔗糖浓度对葡萄籽蛋白的起泡性和泡沫稳定性的影响。结果表明：葡萄籽蛋白干粉得率为8.0%,干粉中蛋白质含量为70.11%,蛋白的等电点为pI=3.8;各因素对葡萄籽蛋白的起泡性和泡沫稳定性均有不同程度的影响。     

复合米糠蛋白-卵白蛋白的起泡特性及相关机理分析

考察复合米糠蛋白（rice bran protein,RBP）-卵白蛋白（ovalbumin,OVA）的起泡特性,并分析在特定pH值与NaCl浓度下溶液与泡沫中不同蛋白质的物化性质,以阐述两种蛋白之间相互作用对起泡特性的影响。结果表明,在pH 4.0条件下,两种蛋白质在起泡能力上可以产生协同作用,且当RBP-OVA质量比为3:1时,添加1% NaCl后RBP-OVA复合蛋白的起泡能力和泡沫稳定性均显著增加;而在pH 7.0、无NaCl的情况下两种蛋白在起泡特性上没有表现出特别明显的协同作用,当添加1% NaCl后二者在起泡能力方面反而表现出一定的拮抗作用。通过对pH 4.0、1% NaCl条件下溶液与泡沫中蛋白质的物化性质进行分析可知,因两种蛋白质在物化性质方面具有一定的互补性,可通过蛋白质之间的相互作用从不同的物化性质角度改善RBP-OVA复合蛋白的起泡能力与泡沫稳定性。     

酱油沉淀控制酶解制备高起泡蛋白的研究

研究了pH值、蛋白浓度、水解度对酱油沉淀蛋白控制酶解制备起泡蛋白的影响,并探讨了黄原胶的添加对酱油沉淀蛋白泡沫性质的改善效果。结果表明:酱油沉淀蛋白的起泡性随着pH值的升高而提高,但沉淀蛋白水解物的起泡性呈现相反的变化趋势,其在pH 5时起泡性和泡沫稳定性最佳,酶解3h水解物的起泡性和泡沫稳定性分别达到59.00%和43.55%;当黄原胶添加量为0.05%～0.1%时,能显著提高沉淀蛋白水解物的泡沫稳定性,但添加量过大会影响起泡性。在pH 5时,添加0.05%的黄原胶,3h水解物的起泡性和泡沫稳定性可达到54.00%和81.81%。以粘度、表面疏水性、ζ-电位为指标探讨了影响酱油沉淀蛋白泡沫性质的机理,蛋白泡沫性质的呈现与它们的综合效应有关。     

米糠蛋白的起泡特性及其泡沫微观形态

考察pH值和NaCl浓度对米糠蛋白起泡特性及泡沫微观形态的影响,并对二者之间的内在关系进行阐述。结果表明,当米糠蛋白溶液中不添加NaCl、pH?4时起泡能力较差,但泡沫稳定性可达最大值（88.3±7.3）%,而当溶液的pH值偏离4时起泡能力增加,在pH10和12条件下起泡能力分别可达（73.3±0）%和（168.9±10.2）%,泡沫稳定性分别为（74.7±2.5）%和（68.5±2.1）%;另外在米糠蛋白溶液pH值为4和7条件下分别添加1%的NaCl后,可显著提高起泡能力至（77.8±3.8）%和（90.0±5.8）%。米糠蛋白泡沫的微观形态随时间变化规律说明,不同pH值条件下起始阶段气泡的直径大小分布与泡沫稳定性相关,而当添加NaCl后米糠蛋白起泡能力和泡沫稳定性的改变则与气泡数量和平均面积二者的综合效应有关。     

卵白蛋白起泡性影响因素研究

为研究影响卵白蛋白起泡性的因素,考察氯化钠、大豆分离蛋白、蔗糖、卡拉胶、温度和pH值对卵白蛋白起泡特性的影响。结果表明,在一定浓度范围内,NaCl、大豆分离蛋白均可改善卵白蛋白起泡力,蔗糖、卡拉胶均可改善卵白蛋白的泡沫稳定性。在40~50℃温度范围内可提高卵白蛋白起泡性;卵白蛋白在等电点附近起泡性差,在pH 7.0~8.0时起泡性较理想。     

苦杏仁蛋白的功能特性

采用稀盐溶液浸提及等电点盐析相结合的方法提取制备苦杏仁蛋白,研究pH值、NaCl浓度、蛋白质量浓度和温度等因素对苦杏仁蛋白功能特性(溶解性、持水性、吸油性、乳化性及乳化稳定性、起泡性及起泡稳定性)的影响。结果表明：在等电点pI附近时,苦杏仁蛋白的溶解性、持水性、乳化性及乳化稳定性、起泡性最差;在较低NaCl浓度范围内(0～0.8mol/L)提高NaCl浓度可促进蛋白溶解性、乳化性及乳化稳定性、起泡性及起泡稳定性的提高,而较高的NaCl浓度对蛋白功能特性提高具有抑制作用;当蛋白质量浓度达到一定水平时(3～4g/100mL),蛋白功能特性(乳化性及乳化稳定性、起泡性及起泡稳定性)提高趋于平缓;在适宜的温度范围内,提高温度可有效提高苦杏仁蛋白各项功能特性,但当温度继续上升,各项功能特性持续降低。     

桑叶蛋白的功能特性研究

采用超声波辅助提取结合盐酸沉析法提取桑叶蛋白,研究pH值、离子强度、蔗糖质量浓度和温度对桑叶蛋白功能特性的影响。结果表明：远离其等电点时,桑叶蛋白具有良好的持水性、溶解度、乳化性及乳化稳定性、起泡性;桑叶蛋白的持水性、溶解度和起泡性与NaCl浓度(0～1.0mol/L)呈正相关,而过高的离子强度(NaCl浓度高于0.6～0.8mol/L)会使桑叶蛋白的乳化性和乳化稳定性下降;蔗糖的加入会增加桑叶蛋白的持水性,但会降低其溶解度和起泡性,对桑叶蛋白的乳化性和乳化稳定性影响不大;桑叶蛋白的吸油性和起泡性与温度(4～80℃)呈正相关,持水性、溶解度、乳化性及乳化稳定性于60℃时最好。     

Properties of Biopolymers from Cross-linking Whey Protein Isolate and Soybean 11S Globulin

Biopolymers were prepared by cross-linking whey protein isolate (WPI) and soybean 11S using transglutaminase. Electrophoretic pattern, solubility, emulsification, hydrophobicity and foaming properties of the biopolymers were determined. SDS-PAGE showed bands corresponding to high-molecular-weight components (MW>200 kDa). Biopolymer solubility was > 90% at pH 3 and below, and at pH 7 and above. Emulsifying properties of biopolymers were lower than those of WPI. The foaming capacity of the biopolymers (23.6 mL) and WPI/11S mixture (22.7 mL) were similar to that of egg albumin (20.3 mL). The foaming stability of the biopolymers (122 min) was higher than that of WPI/11S mixture (33.7 min), and was similar to that of egg albumin (132 min).     

Amino acid composition,foaming, emulsifying properties and surface hydrophobicity of mustard protein isolate as affected by pH and NaCl

Amino acid composition, protein hydrophobicity, foaming and emulsifying properties of mustard protein isolate at pH 3, 5, 7 and in 0.05 and 0.1 m NaCl were studied. Glutamic (19.18 ± 0.30%) and aspartic (7.49 ± 0.11%) acids were the dominants. Foaming ability was enhanced by NaCl. Time to reach 75 mL foam was 23% higher in water than in NaCl. Drained volume after 10 min was concentration dependent and was the lowest in 0.05 and 0.1 m NaCl at protein concentration of 2.5% and 5%. The emulsifying properties were pH and concentration dependent, and the best results were obtained at pH 3, corresponding to the highest positive charge density of the protein surface. The highest emulsion stability (90.22 ± 3.52%) was obtained in 0.05 m NaCl and 5% protein concentration, whereas the lowest (63.00 ± 1.06%) was in water at all protein concentrations. Protein hydrophobicity was low and depended of pH but not of NaCl.     

Solubility and functional properties of sesame seed proteins as influenced by pH and/or salt concentration

The protein content, solubility and functional properties of a total protein isolate prepared from sesame seeds (Kenana 1 cultivar) as a function of pH and/or NaCl concentration were investigated. The protein content of the seed was found to be 47.70%. The minimum protein solubility was at pH 5 and the maximum was at pH 3. The emulsifying capacity, activity and emulsion stability as well as foaming capacity and foam stability were greatly affected by pH levels and salt concentrations. Lower values were observed at acidic pH and high salt concentration. The protein isolate was highly viscous and dispersable at pH 9 with water holding capacity of 2.10 ml H₂O/g protein, oil holding capacity of 1.50 ml oil/g protein and bulk density of 0.71 gm/ml.     

Isolation and characterization of protein isolated from defatted cashew nut shell: Influence of pH and NaCl on solubility and functional properties

This work reports the isolation of protein from defatted cashew nut shell (CNS), with the crude protein product containing 91.07% protein. Under its natural conditions, the solubility of this protein isolate is comparable (74.02%) to that of mustard green meal protein. The solubility of the protein isolate decreases with decreasing pH, with the minimum solubility observed at its isoelectric point (pH 3). The water holding capacity, oil holding capacity, foaming capacity, foam stability, emulsifying capacity and emulsion stability were found to be 2.56 cm³ H₂O/g protein, 4.28 cm³ oil/g protein, 76.88%, 70.98%, 62.0% and 79.0%, respectively. The profiles of these functional properties were determined with varying pH values and NaCl concentrations, and improved properties were observed in the alkaline pH range and in the presence of NaCl. Electrophoretic analysis showed that the high molecular weight protein globulin was the major protein in the protein isolate.     

不同提取方法及因素对亚麻蛋白功能性质的影响

通过单因素和正交试验优化高速剪切、超声酶解两步水解黄精工艺,并用黄精水解液和糯米混合发酵酿制新型黄精黄酒。结果表明,黄精原料高速剪切工艺参数为剪切时间50 min、剪切pH 2、剪切速率14 000 r/min、料液比1∶50（g∶mL）;黄精滤渣水解工艺参数为纤维素酶添加量2%、超声功率200 W、料液比1∶20（g∶mL）、超声时间60 min。在此优化条件下,黄精多糖溶出率达52.5%,水解率为81.3%。黄精水解液与糯米结合发酵的新型黄精黄酒呈淡黄色、清亮透明、酸甜适中,具有黄精中药原有的特殊香味;其中,经检测新型黄精黄酒多糖含量为5.01 mg/mL,远高于传统黄精黄酒、传统黄酒。