改性硅藻土对脂肪酶固定化研究

以改性硅藻土为载体,采用吸附法对脂肪酶进行固定化。对固定化条件进行优化。得到较佳的固定化条件:固定化时间为4h;温度为40℃;pH值为7.5;固定化酶在40℃下保温2h后酶活损失很小,固定化酶重复性达到最佳状态。     

磁性纳米粒子的制备及脂肪酶的固定化

建立了以纳米级磁性粒子为载体固定化脂肪酶的方法,优化了脂肪酶的固定化条件,考察了固定化酶的性质. 制备的磁性载体平均粒径20 nm,具有超顺磁性,分散和再分散效果好. 固定化酶的最适吸附时间为60 min,酶用量:载体量为1:1,固定化酶的酶活达到718 U/g. 结果表明,经纳米磁性粒子固定化后,脂肪酶得到活化,固定化酶比活为游离酶的1.8倍. 同时,固定化脂肪酶的pH稳定性显著提高.     

纳米晶镁铝水滑石固定化脂肪酶性质研究

以阴离子型层状材料纳米晶镁铝水滑石为载体通过直接吸附对脂肪酶进行固定,考察了各因素对酶固定化的影响,优化了固定化条件.研究表明,脂肪酶的较优固定化条件为载体用量0.32 g/mL(720 U/mL酶液),30～35℃,pH值7.5,负载6～7 h,制得的固定化酶表观酶活达725 U/g.游离酶和固定化酶的水解活化能分别为5.45 kJ/mol和16.31 kJ/mol,游离酶和固定化酶的表观失活活化能分别为20.28 kJ/mol和29.02 kJ/mol,固定化酶较游离酶稳定.     

固定酶法催化合成生物柴油Ⅰ.大孔树脂固定化脂肪酶的制备

研究了用于生物柴油酶催化的大孔树脂固定化脂肪酶的制备过程,考察和优化了脂肪酶固定化方法及条件。结果表明,采用大孔树脂D3520作载体,以载体涂布法固定化脂肪酶的最适固定化条件为:酶用量为酶∶树脂=0.16∶1(质量比),吸附时间1~3 h,pH值范围为9.0~9.4,固定化温度40℃。酶活力可达91.49 U/g,酶活回收率约为54%。     

改性硅藻土固定化脂肪酶催化蓖麻油制备生物柴油

采用改性硅藻土做为载体,用吸附法对脂肪酶进行固定化,对固定条件进行优化,利用固定化脂肪酶催化蓖麻油制备生物柴油,考察反应时间、温度、醇油比及酶用量对转化率的影响和固定化脂肪酶催化合成生物柴油的稳定性。研究表明,硅烷化试剂添加量0.4%、温度30℃和时间4~6 h时固定化脂肪酶的活性最高,在醇油比为9:1,固定化酶用量为蓖麻油质量的4%,温度为60℃,反应时间为10 h的条件下,生物柴油的产率最高,经过3个批次的反应后,其产率都在40%以上,该固定化酶催化合成生物柴油有良好的工业化前景。     

Burkholderic cepecia 1003产海因酶固定化条件

海因酶是利用海因酶法制备手性氨基酸的关键酶。采用Eupergit C、Eupergit C250 L及其氨基化后的载体作为固定化介质,对酶液pH值、蛋白浓度、固定化时间以及EDC用量等参数对海因酶固定化过程的影响进行研究,并在实验范围内,得到了上述参数的最优值。研究表明,环氧基载体的最适固定化条件为:酶液pH值为7.0,酶液蛋白质量浓度为0.4 mg/mL,固定化时间为20 h;氨基载体最适固定化条件为:酶液pH值为8.0,酶液蛋白质量浓度为0.4 mg/mL,固定化时间为10 h,EDC用量:Eupergit C(NH2)为70μL,Eupergit C250 L(NH2)为120μL。其中以Eupergit C250 L为固定化载体,海因酶的活性回收率可高达87%,且固定化酶的稳定性也较好,酶活半衰期长达2 500 h左右,具有较好的稳定性。     

树脂吸附法固定Candida rugosa脂肪酶

Candida rugosa脂肪酶具有优良的催化性能,对其进行固定化可以很方便地实现酶的回收和再利用。采用南开大学化工厂生产的4种阴离子交换树脂和4种大孔吸附树脂为载体,对来源于Candida rugosa的脂肪酶进行了吸附固定化,结果表明,以大孔吸附树脂AB-8为载体的固定酶比活性最高。固定化酶制备过程中缓冲液的最适宜pH值为7.2,最佳固定化时间为1 h,载体和酶的最佳质量配比为10∶1。与游离酶相比,固定化后酶活损失大约30%,但稳定性平均约提高60%。     

三维有序大孔硅材料载体固定化脂肪酶研究

以聚苯乙烯胶体晶体为模板制备三维有序大孔硅材料(3DOM-SiO_2),以其作为载体来固定脂肪酶。分别考察了脂肪酶加入量、反应体系pH、固定反应时间对固定化效果的影响。结果表明,3DOM-SiO_2材料固定脂肪酶的最佳酶液加入量为200 mL/g,固定化最适宜pH为7.0,最佳反应时间为5 h。固定化的脂肪酶在催化性能上与游离脂肪酶相比优势明显,最适宜反应温度提高到40℃左右,并且酶活随温度变化率低,热稳定性明显提高;脂肪酶固定化后对pH的敏感度降低,适应范围更宽,催化反应的最适pH为8.0;固定化脂肪酶重复使用8次后,相对酶活保持在62%。由此可见,3DOMSiO_2材料是固定脂肪酶的优良载体,在酶固定化领域应用前景广阔。     

CALB脂肪酶的固定化及其拆分2-辛醇的研究

以AB-8、HZ-841、HZ-802三种大孔树脂做载体,采用物理吸附法,制备出固定化南极假丝酵母脂肪酶(CALB),并用其进行了拆分2-辛醇的研究。其中AB-8树脂做载体拆分效果最佳,其蛋白吸附量为37.94 mg/g树脂,吸附率94.86%,转酯化酶活3 000 U/g固定化酶,对映体选择性E=104。单因素优化实验得到的最佳拆分条件为:温度40℃,加酶量2.67 g/L,底物醇浓度3.76 mol/L。在该条件下,产物转化率可达50%,e.ep为97.8%。固定化pH在5.0~9.0内对拆分效果无显著影响。     

以凹土颗粒稳定的乳液为模板制备复合微球固定化酶

以凹土颗粒稳定的Pickering乳液为模板聚合有机/无机复合微球,并以此为载体固定化脂肪酶,当脂肪酶浓度为0.020wt％,固定化温度为45 ℃及pH=7.4的条件下,固定化效果较好,酶活达到最大.脂肪酶固定化后显示出较好的热稳定性、储存稳定性,重复使用三次后酶活仍与游离酶的初始酶活相近.从而为酶的固定化的提供了一条新的途径.     

Immobilization of Candida rugosa lipase on modified natural wool fibers

A method has been developed to immobilize lipase from Candida rugosa on modified natural wool fibers by means of graft copolymerization of poly ethylacrylate in presence of potassium persulphate and Mohr’s salt redox initiator. The activities of free and immobilized lipase have been studied. FTIR spectroscopy, scanning electron microscopy, and the Bradford method were used to characterize lipase immobilization. The efficiency of the immobilization was evaluated by examining the relative enzymatic activity of free enzyme before and after the immobilization of lipase. The results showed that the optimum temperature of immobilized lipase was 40 °C, which was identical to that of the free enzyme, and the immobilized lipase exhibited a higher relative activity than that of free lipase over 40 °C. The optimal pH for immobilized lipase was 8.0, which was higher than that of the free lipase (pH 7.5), and the immobilization resulted in stabilization of enzyme over a broader pH range. The kinetic constant value (km) of immobilized lipase was higher than that of the free lipase. However, the thermal and operational stabilities of immobilized lipase have been improved greatly.     

Immobilization of hydrophobic lipase derivatives on to organic polymer beads

A simple and effective method of lipase immobilization is described. Lipase from Candida rugosa was first modified with several hydrophobic modifiers before being adsorbed on to organic polymer beads. The soluble hydrophobic lipase derivatives adsorbed more strongly on to the various polymers as compared with the native lipase. The optimal adsorption temperature of the native and modified lipases on all the polymers was 40°C. The optimal pH of adsorption was between 6 and 7. Lipase immobilized in this manner produced high catalytic recoveries which were affected by the type of modifiers, degree of modification and type of supports used. Monomethoxypolyethylene glycol (1900) activated with p-nitrophenyl chloroformate was found to be the best modifier of the enzyme at 95% modification, for adsorption to the polymers. Increasing the degree of modification of the enzyme increased the activity which was immobilized. Generally, both native and hydrophobic lipase derivatives showed higher specific activities when immobilized on polar polymers compared with non-polar polymers.     

假丝酵母99-125脂肪酶促酯化合成生物柴油的研究

1 INTRODUCTION Biodiesel, that is long-chain fatty acid short-chain alcohol esters (methyl, ethyl, propyl and butyl ester), is produced by esterification of fatty acids or inter- esterification of oils and fats. These fatty acid alcohol esters are not only used as important industrial addi- tives and surfactants, but also used for biofuel. The biodiesel is a biodegradable, environmental friendly, renewable substitute of diesel fuel[1]. The traditional production of biodiesel is by chem- i…     

<Emphasis Type="Italic">Penicillium</Emphasis> sp. ZD-Z1 chitosanase immobilized on DEAE cellulose by cross-linking reaction

Chitosanase obtained fromPenicillium sp.ZD-Z1 was immobilized on DEAE cellulose with glutaraldehyde by cross-linking reaction. The optimal conditions of immobilization were as follows: 0.1 g DEAE cellulose was treated with 5 ml 5% glutaraldehyde solution; then 2.3 mg chitosanase was immobilized on the carrier. The optimal temperature and pH was 60 °C and 4.0, and the K _m value was 18.87 g/L. Under optimal conditions, the activity of immobilized enzyme is 1.5 U/g, and the recovery of enzyme activity is 81.3%. After immobilization, the optimal temperature and K _m value increased (from 50 °C to 60 °C, from 2.49 g/L to 18.87 g/L), whereas the optimal pH was reduced (from 5.0 to 4.0). The enzyme activity loss was less than 20% after 10 times batch reaction; the immobilized enzyme showed good operation stability.     

The effect of immobilization on the hydrolytic/interesterification activity of lipase from Rhizopus niveus

Lipase from Rhizopus niveus was immobilized by physical adsorption on Celite 545 and glass beads. The results showed that the highest immobilization efficiency and specific hydrolytic activity of 96% and 9.2 meq/mg protein/min, respectively, were obtained with Celite as the carrier. However, the specific hydrolytic activity of lipase adsorbed on glass beads by acetone precipitation was similar to that obtained by the Celite carrier, although the protein loading capacity was relatively low. The results showed that lipase immobilized on glass beads exhibited similar activity profiles with respect to reaction time, different enzyme concentrations, and water content, using trimyristin and tripalmitin as substrates, to those obtained with the free enzyme. In contrast, the immobilized lipase on Celite exhibited a considerably lower hydrolytic activity. However, the results also showed that the lipase activities of the free enzyme and the immobilized Celite enzyme were similar when the more hydrophilic triolein was used as the substrate. The interesterification of a mixture of tripalmitin and trimyristin or triolein was carried out using both the free and immobilized enzymes. The results indicated that the hydrolytic activity of lipase was similar in both cases for the first 24 h, after which it decreased dramatically. These findings suggest that at this late stage an equilibrium between the hydrolytic and interesterification reactions was reached.     

磁性琼脂糖复合微球固定化纤维素酶的研究

以磁性琼脂糖复合微球为载体,采用物理吸附法,制备出磁性固定化纤维素酶。确定了固定化工艺条件：ｐＨ２－２,吸附时间８ ｈ,酶用量为１５０ ｍｇ／ｇ 微球,在最佳固定化条件下,磁性固定化酶的活力为１９１－７ Ｕ／ｇ 微球,蛋白载量为１００ ｍｇ／ｇ 微球,比活为１－９ Ｕ／ｍｇ 蛋白,活性回收率为７３－１ ％ 。并对磁性固定化酶的理化性质进行了研究：磁性固定化酶的最适温度（５５ ℃） 与天然酶相同,最适ｐＨ（５－０）较天然酶提高１－０ 个单位,磁性固定化酶Ｋｍ 值（４－１×１０ －３ｇ／Ｌ）较天然酶Ｋｍ值（７－８×１０－３ ｇ／Ｌ） 小,热稳定性较天然酶有所提高,磁性固定化酶重复使用１０ 次,其相对活性保持在６０ ％ 。     

脂肪酶固定化研究和应用

采用硅藻土作载体,进行了脂肪酶的固定化。利用固定化酶选择性催化1-苯乙醇与乙酸乙烯酯的转酯化反应,得到R-乙酸苯乙酯,进行1-苯乙醇的拆分。实验考察了不同吸附方法固定化酶的效果,确定效果最好的固定方法为载体涂布法,并对该法的固定化条件进行了优化。制备的固定化酶的转酯比活比游离酶提高了14．3倍。固定化没有改变酶的选择性．对映体过剩值仍大于98％。初步探讨了固定化酶和游离酶的反应过程。