海洋野生鱼酶解提取鱼油的工艺分析

海洋野生鱼与养殖鱼比较, 其鱼油中含更多的二十碳五烯酸（EPA）、二十二碳六烯酸（DHA）、脂溶性维生素等活性成分。为提高海洋野生鱼的利用价值, 以野生小带鱼为原料进行酶法提油工艺研究。分析了不同的温度, 时间, pH值等影响因素下的提取、萃取以及离心效果, 以响应面法确定了最佳的酶解工艺条件: 液固比为6、pH7.3、酶量1000 u/g原料、搅拌速度200 r/min、45oC酶解90 min; 最优萃取条件: 萃取剂100 mL(每20 g鱼糜原料)、pH4.0、40oC萃取25 min; 离心条件: 离心速度3000 r/min (1865 g)、离心时间10 min。上述工艺条件下提油率为79.90%。改进了传统的鱼油提取工艺, 在活性成分保护上有较大改善。     

Extraction of Pancreatic Lipase Inhibitor from Rice Germ

以米胚芽为原料,提取具有抑制胰脂肪酶活力的胚芽蛋白.经工艺优化得到提取条件为:原料颗粒60目,料液比1:6,pH 10.18,温度55℃,提取时间4h,水提后离心速度4 456 r·min-1,等电点沉降pH5.1,等电点沉降后离心速度3 692r·min-1.在此条件下提取得到的胰脂肪酶抑制剂的蛋白质纯度为60.7％.15.18 g/L的胚芽蛋白对30.1 U/mg的猪胰脂肪酶的平均抑制率达71.17％.     

米胚芽中胰脂肪酶抑制剂的提取工艺

以米胚芽为原料,提取具有抑制胰脂肪酶活力的胚芽蛋白。经工艺优化得到提取条件为:原料颗粒60目,料液比1∶6,pH 10.18,温度55℃,提取时间4h,水提后离心速度4 456r.min-1,等电点沉降pH 5.1,等电点沉降后离心速度3 692r.min-1。在此条件下提取得到的胰脂肪酶抑制剂的蛋白质纯度为60.7%。15.18g/L的胚芽蛋白对30.1U/mg的猪胰脂肪酶的平均抑制率达71.17%。     

一株高产纤维素酶菌的筛选与鉴定

利用刚果红脱色从森林腐木中筛选到一株高产纤维素酶菌,结合18S rRNA基因序列分析和菌株形态特性分析,确定该菌株为爪哇正青霉(Eupenicillium javanicum).通过研究粗酶提取时不同离心时间和离心转速对酶活的影响,确定采用3000r/min,15min离心条件下获得的粗酶测定CMC酶活,采用4000r/min,10min的离心条件下获得的粗酶测定FPA酶活和β-葡萄糖苷酶活.酶学性质初步研究显示,纤维素酶反应的最适pH值以5.0为宜;CMC酶最适酶解温度和酶解时间为60℃,15min;FPA和β-葡萄糖苷酶最适酶解温度和酶解时间均为50℃,20min.     

蕨麻愈伤组织原生质体制备条件的优化

以青海‘蕨麻4号’诱导培养的愈伤组织为材料,采用4因素3水平L9(34)正交实验,研究酶类组合、酶解时间、甘露醇浓度及离心速度等主要因素对蕨麻原生质体分离的影响,建立高效、稳定的蕨麻原生质体分离体系,为进一步通过原生质体融合、基因工程等方法对蕨麻进行品种改良奠定基础。结果表明:各因素对蕨麻原生质体产量的影响顺序为:酶类组合酶解时间甘露醇浓度离心速度;青海‘蕨麻4号’愈伤组织原生质体的最适酶解条件为:2.0%纤维素酶+0.75%果胶酶,40r/min振荡酶解10h,甘露醇浓度为0.5mol/L,离心转速为1 000r/min时原生质体的产量达最大(8.96×10~5 cells/g),活力为92.77%。     

纤维素酶提取红景天总黄酮的研究

以总黄酮为考察指标,确定纤维素酶提取红景天有效成分的最佳工艺.研究酶解条件对总黄酮浸出率的影响,并对不同提取方法的提取效果和粗提物的DPPH清除活性进行了比较.纤维素酶提取法的最佳工艺条件为:加酶量为1.95%(以原料干重计),液料比为70∶1(mL∶g),pH值为5.5,酶解温度为40℃,酶解时间为5 h,红景天总黄酮的浸出率为4.385%.酶解技术可明显提高红景天总黄酮的浸出率,粗提物得率高且DPPH清除活性较强.     

酶法辅助乙醇优选牡丹种皮总黄酮

研究适合于以牡丹种皮为原料提取总黄酮的方法,对其提取方法工艺条件进行优化。考察了酶种类、浓度、酶解孵育温度、孵育时间和pH值等因素对提取工艺的影响,并在单因素实验基础上,利用正交实验法进行工艺优化。考察结果表明在果胶酶0.05 mg·mL^-1、酶解孵育温度45℃、pH4.5条件下进行酶解孵育180 min后,总黄酮得率最高可达74.839 mg·g^-1,相对于乙醇提取法牡丹种皮总黄酮得率显著提高。     

马铃薯渣中膳食纤维提取工艺的优化

目的：以马铃薯渣为原料,探究提取马铃薯渣中膳食纤维的最佳工艺条件。方法：通过生物法 酶法、超声波裂解、高速剪切等技术提取马铃薯渣中所含的膳食纤维,通过单因素试验和正交试验分析试验数据。 结果：提取膳食纤维的最佳工艺条件为酶解pH为5、酶解温度45℃、酶添加量30U/g、酶解2.5h。结论：本研究膳食纤维的提取率达25.87%,并测得持水力和膨胀力分别为7.1g/g、7.5mL/g,该工艺条件可有效提取马铃薯渣中的膳食纤维。     

玉米、小麦、水稻原生质体制备条件优化

玉米Zea mays L.、小麦Triticum aestivum L.、水稻Oryza sativaL.是三大重要粮食作物,对其原生质体制备条件的优化具有重要意义.以玉米(综3)、小麦(中国春)、水稻(日本晴)10日龄幼苗为材料,研究了叶肉细胞原生质体分离过程中的酶浓度、酶解时间和离心力大小等因素对产量和活力的影响.结果表明:酶浓度和酶解时间对原生质体产量影响显著,随着酶解液浓度和酶解时间的提高,原生质体产量增加,但细胞碎片同时增多.水稻经真空处理后,原生质体产量大幅度提高.通过正交实验设计得出如下结果:玉米叶肉细胞原生质体分离的最佳条件为:纤维素酶1.5％,离析酶0.5％,50 r/min酶解7h,100×g离心2 min收集,原生质体产量为7×106/g FW;小麦叶肉细胞原生质体分离的最佳条件为:纤维素酶1.5％,离析酶0.5％,50 r/min酶解5h,100×g离心2 min收集,原生质体产量为6×106/g FW;水稻叶肉细胞原生质体分离的最佳条件为:纤维素酶2.0％,离析酶0.7％,50 r/min酶解7h,1 000×g离心2 min收集,得到的原生质体产量为6×106/g FW.通过二乙酸荧光素染色发现原生质体活力均在90％以上.用PEG-Ca2+介导法将含有绿色荧光蛋白的质粒转化入原生质体,转化率可达50％ ～80％.     

纤维素酶-超声波协同提取黑木耳黑色素工艺及其抗氧化活性分析

黑色素是黑木耳的主要活性成分之一,在黑木耳的药理活性上发挥着重要作用。为了提高黑木耳黑色素的提取得率,实验采用正交法和响应面法对纤维素酶-超声波协同提取黑木耳黑色素的提取工艺进行了优化,并对最优条件下提取的黑木耳黑色素体外抗氧化活性进行了分析。实验结果表明,纤维素酶-超声波协同提取黑木耳黑色素的最优条件为:酶添加量12mg,酶解温度40℃,酶解pH 5.0,酶解时间120min,NaOH浓度1.27mol/L,料液比1:40,超声功率300W,超声时间52min,超声温度60℃。在最优条件下,黑木耳黑色素提取得率可达到10.48%,相比于实验设置的未添加纤维素酶的超声波组黑色素提取得率提高了12.93%。抗氧化结果表明,采用纤维素酶-超声波协同提取的黑色素相比于未加纤维素酶提取的黑色素清除ABTS、DPPH和羟基自由基的能力更强。研究结果为黑木耳黑色素的高效提取及其产品的应用开发奠定了基础。     

超声波协同复合酶法提取姬松茸多糖

研究了超声波协同复合酶法提取姬松茸多糖的最佳工艺条件。采用均匀设计法分别考察不同时间、pH值、温度、酶浓度、固液比对纤维素酶、果胶酶以及木瓜蛋白酶酶解反应的影响,并研究三种酶联合使用时的加酶方式以及超声波协同提取时的最佳条件。结果表明,超声波协同复合酶法可显著提高姬松茸多糖的提取率,其最佳提取条件为：超声波作用20min,分步加酶法（先加果胶酶：pH值3．8、温度50℃、时间90min、加酶量7000U／g、固液比1：45;然后加纤维素酶：pH值3．6、温度75℃、时间120min、加酶量150U／g、固液比1：45;最后加木瓜蛋白酶：pH值3．6、温度75℃、时间120min、加酶量20000U／g、固液比1：45）,多糖提取率达到14．51％。     

脂肪酶二步法催化鱼油下脚料富集DHA

采用Pseudomonas sp．脂肪酶水解,Geotrichum sp．脂肪酶选择性酯化的两步法显著提高游离脂肪酸（FFA）中二十二碳六烯酸（DHA）的含量。通过筛选合适的底物醇,优化水解和选择性酯化反应条件达到富集DHA的目的。结果表明月桂醇为选择性酯化的最适底物醇。确定的最佳水解条件：4g反应底物,m（水）／m（粗鱼油）=1,1000 U Pseudomonas sp．脂肪酶,40℃,搅拌速度200r／min,反应24h;最佳酯化条件：3g反应底物,n（FFA）／n（醇）=1／2,1000 U固定化Geotrichum sp．脂肪酶,1g正己烷,30℃,200r／min搅拌,反应20h。经过水解和一次选择性酯化反应后,DHA含量从原料粗鱼油中的18．9％提纯到72．8％;经二次选择性酯化后,DHA含量上升到92％。脂肪酶水解-选择性酯化的两步法是富集DHA的有效方法。     

正交试验法优化桑叶多糖提取工艺

以脱除黄酮的桑叶为原料,采用热水浸提法提取桑叶多糖,研究了提取温度、提取时间、料液比、水溶液pH和提取次数对桑叶多糖得率的影响,通过正交实验优化了提取工艺条件。结果表明,在提取次数为2次条件下,桑叶多糖最佳提取工艺条件为提取温度100℃、提取时间4 h、提取液pH7、料液比(原料:提取液,g/mL)1:30,多糖得率为2.74%。该工艺稳定,桑叶多糖得率高,易于工业化生产。     

Fish oil and neurovascular control in humans

The antihypertensive influence of fish oil is controversial, and the mechanisms remain unclear. Because the inverse relation between fish oil and hypertension appears to be partially dependent on the degree of hypertension, we tested the hypothesis that fish oil would elicit more dramatic reductions in mean arterial pressure (MAP) and muscle sympathetic nerve activity (MSNA) in prehypertensive (PHT) compared with normotensive (NT) subjects. Resting MAP, MSNA, and heart rate (HR) were examined before and after 8 wk of fish oil (9 g/day; 1.6 g eicosapentaenoic acid and 1.1 g docosahexaenoic acid) or placebo (olive oil; 9 g/day) in 38 NT (19 fish oil; 19 placebo) and 29 PHT (15 fish oil; 14 placebo) volunteers. Fish oil did not alter resting MAP, MSNA, or HR in either NT (80 ± 1 to 80 ± 1 mmHg; 11 ± 2 to 10 ± 1 bursts/min; 71 ± 2 to 71 ± 2 beats/min) or PHT (88 ± 2 to 87 ± 1 mmHg; 11 ± 2 to 10 ± 2 bursts/min; 73 ± 2 to 73 ± 2 beats/min) subjects. When NT and PHT groups were consolidated, analysis of covariance confirmed that pretreatment resting MAP was not associated with changes in MSNA after fish oil. In contrast, pretreatment resting HR was correlated with changes in MSNA (r = 0.47; P = 0.007) and MAP (r = 0.42; P < 0.007) after fish oil but not placebo. In conclusion, fish oil did not alter sympathetic neural control in NT or PHT subjects. However, our findings suggest that fish oil is associated with modest sympathoinhibition in individuals with higher resting heart rates, a finding that is consistent with a recent meta-analysis examining the relations among fish oil, HR, and the risk of cardiovascular disease.     

微小毛霉凝乳酶的分离纯化研究

研究微小毛霉(HL-1)凝乳酶的分离纯化条件及方法。研究酶的最适浸提温度、酶的浸提pH值和最适浸提时间,探讨离子浓度、加水量对浸提效率的影响,利用高速冷冻离心法、有机溶剂沉淀法,膜分离法和层析法等对粗酶液进行了分离。利用光谱法对纯化样品进行检测。酶的最适浸提温度为30℃;最适pH为6.0;浸提10 h活力最高;1%的氯化钠有利于酶的分离,加水比例为15时有利于提取,在10 000 r/min下离心10min澄清效果最好,95%的酒精沉淀效果最好,利用0.2μm的微滤膜可除去发酵液中的菌体,8 000的超滤膜可拦截凝乳酶蛋白,S300的填料可有效分离凝乳酶,纯度达95%以上。     

Potential of Thraustochytrids to Partially Replace Fish Oil in Atlantic Salmon Feeds

The replacement of fish oil with a dried product made from thraustochytrid culture, a marine microorganism, in canola-oil-based diets for Atlantic salmon was investigated. Salmon (37 g) were fed for 51 days on diets containing only canola oil, canola oil and fish oil, or canola oil and the thraustochytrid. There were no significant differences in final weight (106.1 ± 1.1 g), weight gain (69.6 ± 1.1 g), feed consumption (16.5 ± 0.2 mg dry matter g^-1 d^-1), feed efficiency ratio (1.15 ± 0.03 g ^g-1), or productive protein value (51.2% ± 1.7%) between the diets. Nor were there any significant differences in whole-body chemical composition, organ somatic indices, or measures of immune function. However, following transfer to seawater and 2 challenges with Vibrio anguillarum, cumulative mortality was significantly lower in fish fed some fish oil than in those fed the 2 diets containing no fish oil. In conclusion, the thraustochytrid had no detrimental effects on the performance of salmon but, at the current inclusion of 10%, failed to confer the same effect as fish oil under challenging conditions.     

高温湿热酸法破壁提取法夫酵母胞内虾青素

法夫酵母是一种能积累虾青素的红酵母, 对其进行破壁是当前虾青素工业化提取生产的瓶颈工艺。研究在高温湿热条件下,低浓度盐酸对法夫酵母破壁而提取其胞内虾青素的工艺。探讨了不同破壁温度、盐酸浓度、液料比与破壁处理时间等因素对法夫酵母破壁后虾青素及类胡萝卜素提取率的影响, 确定了高温湿热酸法破壁提取虾青素的最佳条件为: 饱和蒸汽压力 0.1 MPa (121°C), 盐酸浓度0.5 mol/L, 液料比 (V/W)30 mL/g, 破壁时间2 min。在最佳条件下进行中试放大实验, 可得到虾青素与类胡萝卜素的提取率分别为: (84.8±3.2)%, (93.3±2)%。经优化后的新破壁工艺安全高效, 不会有毒性残留, 具有良好的工业应用前景。     

Erucic acid production using porcine pancreas lipase: Enhancement by mixed surfactants

Application of mixed surfactants coupled with statistical optimization in lipase catalyzed oil hydrolysis is presented for the first time in this study. Selective hydrolysis of brown mustard oil to erucic acid by porcine pancreas lipase was enhanced by mixed surfactants comprising of an oil-soluble nonionic surfactant (Span 80) and a watersoluble nonionic surfactant (Tween 80). The production of erucic acid was maximized using statistically designed experiments and subsequent analysis of their result by response surface methodology. The most significant variables were enzyme concentration and concentration of Tween 80. Small changes in pH and concentration of Span 80 also produced a significant change in the production of erucic acid. Temperature and speed of agitation were insignificant variables and were fixed at 35oC and 900 rpm, respectively. Under these conditions, the optimal combination of other variables were pH 9.65, 2.13 mg/g enzyme in oil, 9.8 × 10⁻³ M Span 80 (in oil), and 4 × 10⁻³ M Tween 80 (in buffer). These conditions led to formation of 99.69% of the total erucic acid in 1.25 h. Interaction of enzyme concentration with pH significantly affected erucic acid production.