交联酶聚集体与仿生硅化技术结合制备固定化脂肪酶

将交联酶聚集体(CLEAs)与仿生硅化技术相结合,制备了交联脂肪酶Candidasp.99-125杂化生物催化剂.以京尼平为交联剂,在最佳条件下制得的脂肪酶CLEAs的酶活达771U/g,回收率达75%;保护剂聚乙烯亚胺(PEI)与Candidasp.99-125脂肪酶共沉淀制备P/CLEAs,其酶活达897U/g,回收率约88%;利用PEI的诱导作用,在P/CLEAs表面形成氧化硅涂层,制得的脂肪酶CLEAs(Coated-CLEAs)显示出良好的稳定性,特别是其抗蛋白酶水解能力、有机溶剂耐受能力、重复使用性能等方面明显提高.     

壳聚糖固定化碱性脂肪酶的研究

以蟹壳为原料提取壳聚糖,用戊二醛作交联剂,将碱性脂肪酶固定于壳聚糖上。同时探讨了一定量干壳聚糖载体与交联剂浓度、给酶量等关系的最适固定化酶条件,并对固定化酶的热稳定性、操作稳定性、米氏常数、最适温度、离子强度的影响以及使用半衰期等理化性质进行探讨。     

碳酸钙固定化猪胰脂肪酶的制备及活性研究

本文利用市售普通碳酸钙(general calcium carbonate,GCC)作为猪胰脂肪酶(PPL)固定化的载体材料,研究了不同固定化条件对所制备的固定化酶活性的影响.结果显示PPL固定化于GCC上的最佳制备工艺为:将20 mL酶液与1.50 g GCC放入置于摇床内的三角瓶中,摇床温度设为40℃,摇床转速设为...     

固定化脂肪酶催化合成生物柴油

固定化脂肪酶催化合成生物柴油;转酯反应;固定化脂肪酶;菜籽油;甲醇;生物柴油     

海藻酸钠固定化根霉脂肪酶的制备及其性质

 研究了以海藻酸钠为载体,用包埋法制备固定化德氏根霉(Rhizopus delemar)脂肪酶的条件. 将酶粉和海藻酸钠溶于pH 5.0的HAc-NaAc缓冲溶液,用注射器将此混合液滴入到0.05 mol/L无菌CaCl2溶液中,静置固化45 min, 经过滤、洗涤和干燥后得到球状固定化酶. 固定化酶的活力回收约为34.1%. 酶学性质研究表明,此固定化酶的热稳定性较好. 游离酶在 60 ℃下保温1 h已完全丧失活力,而固定化酶在100 ℃下保温1 h仅损失36.2%的活力,在100 ℃下保温6 h仍可保持46.8%的酶活力. 酶经固定化后,其橄榄油水解反应的最适温度由40 ℃上升至90 ℃, Km值由13.8 mg/ml下降为8.1 mg/ml. 常见有机溶剂对固定化酶的活力影响较小. 将该固定化脂肪酶用于非水溶剂中正戊酸异戊酯的合成,重复使用6次后,固定化酶仍保持95%的酶活力.     

黑曲霉脂肪酶的耦合固定化及特性

研究了吸附-絮凝耦合的方法固定脂肪酶的工艺条件.结果表明:在33℃下,用0.03mol/L的磷酸二氢钾?氢氧化钠缓冲液控制体系pH为7.0,酶与树脂(质量比1∶8)作用吸附1h后,用0.2mL絮凝剂聚丙烯酰胺(w(PAM)=0.5%)处理,得到活力较高的固定化脂肪酶.固定化酶最适pH9.0,最适温度为45℃,活力为405U/g,酶活回收率可以达到40%.固定化脂肪酶制备简便,可重复使用,稳定性较高.     

多孔材料固定化脂肪酶的研究进展

在有机合成中,脂肪酶是一种符合绿色化学理念、能显著提高催化效率和对生化工业具有重要意义的生物催化剂,它的研究和应用涉及很多领域.然而,在众多有机反应中,脂肪酶容易受水、温度、 pH值、酶液浓度、底物浓度、酶的激活剂或抑制剂等许多因素的影响,导致失活,产率降低.为了解决这一问题,酶的固定化技术引起了广大科研工作者的浓厚兴趣,并发现了很多酶的固定化载体.其中,多孔材料类固定化载体颇受青睐,它具有孔隙率高、比表面积大、相对密度低、吸附性能较佳、渗透性能较好和精确的分子识别功能等优点.实验证明,多孔材料固定化酶比游离酶的应用效果更佳,多次循环利用后仍旧保持较高的酶活性.我们主要对多孔材料在固定化脂肪酶方面的应用和固定化酶的催化效果做了一个总结,多孔材料主要包括纳米多孔材料、大配体多孔材料、碳骨架多孔材料、氧化硅骨架多孔材料、聚合物类多孔材料等.     

非水相中固定化脂肪酶催化性能的研究

以离子交换树脂为载体,用离子交换吸附法固定化脂肪酶,对影响固定化过程的各种因素进行了考察,确定了最优条件。得到的固定化酶催化合成月桂酸月桂醇酯,考查了在不同lgP值有机溶剂中的催化反应,异辛烷为最佳反应介质,最佳水含量为8％,最佳酸醇摩尔比为1：2,最适催化温度为55℃,得到的活化能Eα为19．00kJ／mol。     

有机相中蚕丝固定化脂肪酶催化酯化反应性能研究

研究了有机相中蚕丝固定化脂肪酶催化酶化反应的催化活性。考究了有机溶剂,底物、反应温度,ＰＨ值和体系含水量等因素对固定化脂肪酶催化活性的影响。结果表明,以异辛烷为有机溶剂,在反应温度为５０℃ＰＨ值为７．４时,酶催化活性最好。     

Control of calcium carbonate polymorphism and morphology through biomimetic mineralization by means of nanotechnology

In vitro biomimetic mineralization by means of nanotechnology allows the formation of calcium carbonate polymorphs at low temperatures (<25 degrees C) under a CO(2) atmosphere of 500-1500 ppm. A two-dimensional zinc-ion ordered array (zinc array), which acts as an active-site mimic of carbonic anhydrase, has been prepared by immersing the self-organized monolayer of 3-(2-imidazolin-1-y)propyltriethosilane on mica (ImSi substrate) into aqueous zinc solution. The zinc array mounted on the ImSi substrate catalyzed the conversion from CO(2) to HCO(3) (-), and accelerated the formation of calcium carbonate. In situ X-ray diffraction data of the formed calcium carbonate on the poly(L-aspartate)-coated chitin substrate (pAsp substrate), with calcium ion-recognition sites, demonstrated that the interaction between the zinc array and pAsp substrates formed both vaterite and calcite at low temperature (15 degrees C) and mainly vaterite at 25 degrees C; this interaction also controlled the morphology of calcium carbonate formed on pAsp substrate.     

Enhancing enzymatic properties by the immobilization method

Effects of some immobilized carriers on enzymatic properties have been studied. The following results were obtained: (1) When cholinesterase was immobilized on the hydrophobic carrier with either α-naphthylamine, benzylamine, orp-methylbenzylamine groups, the affinities of immobilized cholinesterase for toxic organophosphors, GB (Isopnopy 1-methylphophonofluoridate) and Vx [o-ethyl-S-(2-diisopnoylomino-thyl) methyl phosphonothiolate], were enhanced 60–90 times and 700–1200 times, respectively, whereas the thermal stability of the immobilized cholinesterase increased to 110%. Approximately 82–88% activity of the immobilized cholinesterase remained after continuously operating for 8 h; and (2) Lipase was immobilized on the carrier that was made up of 6% polyethylenimine, 1% alginate gel, and 1% glutaraldehyde. The initial reaction rate of the esterification of lauric acid with lauric alcohol catalyzed by this kind of immobilized lipase was increased 21 times, as compared to lipase powder. About 72% esterification activity of lipase remained after continuous operating for 10 d.     

Selection of stabilizing additive for lipase immobilization on controlled pore silica by factorial design

Candida rugosa lipase was covalently immobilized on silanized controlled poresilica (CPS) previously activated with glutaraldehyde in the presence of several additives to improve the performance of the immobilized from in long-term operation. Proteins (albumin and lecithin) and organic molecules (β-cyclodextrin and polyethylene glycol [PEG]-1500) were added during the immobilization procedure, and their effects are reported and compared to the behavior of the immobilized biocatalyst in the absence (lacking) of additive. The selection of the most efficient additive at different lipase loadings (150–450 U/g of dry support) was performed by experimental design. Two 2²full factorial designs with two repetitions at the center point were employed to evaluate the immobilization yield. A better, stabilizing effect was found when small amounts of albumin or PEG-1500, were added simul-taneou sly to the lipase on to the support. The catalytic activity had a maximum (193 U/mg) for lipase loading of 150 U/g of dry support using PEG-1500 as the stabilizing additive. This immobilized system was used to perform esterification reactions under repeated batch cycles (for the synthesis of butyl butyrate as a model). The half-life of the lipase immobilized on CPS in the presence of PEG-150 was found to increase fivefold compared with the control (immobilized lipase on CPS without additive).     

Effect of agar hydrogel and magnesium ions on the biomimetic mineralization of calcium carbonate

Here, agar hydrogel was selected as diffusion medium and template to control the biomimetic mineralization of calcium carbonate (CaCO₃). Due to three dimensional network structures and abundant functional groups (such as, hydroxyl groups), Ca²⁺ ions were uniformly distributed in the network and electrostatically attracted. The diffusion speed and range of CO₃^2? ions were mediated by the concentration of hydrogel medium. Under the synergistic effect of Mg²⁺ ions, the crystal CaCO₃ was induced by gas phase diffusion method in the hydrogel system. The results showed that the concentrations of Mg²⁺ ions and agar hydrogel had no obvious effect on the calcite phase of CaCO₃, but the morphologies and sizes changed with concentrations of medium and Mg²⁺ ions. Attribute to template effect, the crystallization behavior and growth rate of CaCO₃ crystals were regulated. Since Mg²⁺ ions were easily adsorbed on the surfaces of unit cell, the unique structure of CaCO₃ was precisely controlled. This study provides a useful reference and inspiration for the understandings of the contributions of ion supply rate in bio-mineralization and hydrogel medium in biomimetic mineralization.     

Covalent immobilization of Candida antarctica lipase B on nanopolystyrene and its application to microwave-assisted esterification

Nanopolystyrene was used as a solid support for the covalent immobilization of Candida antarctica lipase B (CalB) using the photoreactive reagent 1-fluoro-2-nitro-4-azido benzene (FNAB) as a coupling reagent. The obtained derivative was then used as a biocatalyst in a microwave assisted esterification experiment. Factors such as contact time, pH, and enzyme concentration were investigated during immobilization. The hydrolytic activity, thermal, and operational stability of immobilized-CalB were determined. The maximum immobilized yield (218 μg/mg support) obtained at pH 6.8 exhibited optimum hydrolytic activity (4.42 × 10³ mU p-nitrophenol/min). The thermal stability of CalB improved significantly when it was immobilized at pH 10, however, the immobilized yield was very low (93.6 μg/mg support). The immobilized-CalB prepared at pH 6.8 and pH 10 retained 50% of its initial activity after incubation periods of 14 and 16 h, respectively, at 60 ℃. The operational stability was investigated for the microwave assisted esterification of oleic acid with methanol. Immobilized-CalB retained 50% of its initial activity after 15 batch cycles in the microwave-assisted esterification. The esterification time was notably reduced under microwave irradiation. The combined use of a biocatalyst and microwave heating is thus an alternative total green synthesis process.     

Effect of Candida antarctica lipase B immobilization on the porous structure of the carrier

A series of poly(GMA-co-EGDMA) resins with identical composition but varying particle sizes, pore radii, specific surface areas and specific volumes are studied to assess how Candida antarctica lipase B immobilization affects the porosity of the copolymer particles. Mercury porosimetry reveals a significant change in the average pore size (up to 6.1-fold), the specific surface area (up to 3.2-fold) and the specific volume (up to 2.1-fold) of the epoxy resin. A similar behaviour is observed for glutaraldehyde-modified epoxy resins. The influences of the resin porosity properties on the loading of Candida antarctica lipase B during immobilization and on the hydrolytic activity (hydrolysis of p-nitrophenyl acetate) of the immobilized lipase are studied.     

Intensification of lipase performance for long-term operation by immobilization on controlled pore silica in presence of polyethylene glycol

In agreement with previous studies, promising results were obtained when lipase was immobilized on controlled pore silica (CPS) in the presence of polyethylene glycol (PEG 1500). This methodology rendered immobilized derivatives with higher operational stability than those lacking PEG 1500. This article extends the scope of this approach by evaluating the combined effects of PEG concentration and lipase loading employing a multivariate statistical approach. A 2² factorial design with center point was adopted for a full understanding of these effects and their interactions. Conditions that maximize the immobilization yield were different from those attained for the biocatalyst’s operational stability. Possible reasons for the increase in both activity and stability of lipase immobilized on CPS in the presence of PEG 1500 are discussed in light of the influence of surface hydrophilic/hydrophobic balance.     

Kinetic and stability characterization ofChromobacterium viscosum lipase and its comparison withPseudomonas glumae lipase

A kinetic study ofChromobacterium viscosum lipase was undertaken, and compared withPseudomonas glumae lipase. Optimum operation conditions were pH 9.0 and 50°C for both enzymes. A substrate specificity study was also developed. Both enzymes showed higher activity on triglycerides with a long chain of fatty acid; the specific activity was always higher for C.viscosum lipase. Stability of both enzymes in aqueous medium at 60°C and pH 9.0 was evaluated. C.viscosum lipase was three times more stable than P.glumae lipase, with at _1/2 value of 0.75 h. In addition, the activity of C.viscosum lipase with substrate concentration was studied with a triolein emulsion. A dependence of the intrinsic characteristics of the emulsion was observed. Therefore, stability ofC. viscosum lipase B with reaction products was assayed in a micellar system. Acid products reduced the specific activity of the enzyme. Glycerol and high buffer concentration were stabilizers of enzyme deactivation. Finally, substrate specificity ofC. viscosum lipase B in a micellar system was developed with tributyrin, tricaprylin, and triolein. Only tributyrin showed an apparent Michaelis-Menten kinetic with V_max ^app = 958 U/mg and K_ma ^app = 75.5 mM. Tricaprylin and triolein showed diffusion limitations at low substrate concentration and substrate inhibition at high substrate concentration. Diffusion parameters were calculated for both these substrates. Mass transfer coefficients (k₁) were 0.314 Å/min and 1.53 Å/min for tricaprylin and triolein, respectively. Effectiveness factors (η) were 0.536 and 0.768 for tricaprylin and triolein, respectively.