Showing papers on "Immobilized enzyme published in 2008"
TL;DR: This review discusses biomimetic and bioinspired mineral formation as a technique for the immobilization of enzymes with potential application to a wealth of biocatalytic processes.
363 citations
TL;DR: This review attempts to provide an updated compilation of the studies reported on biodiesel production by using lipase immobilized through various techniques and the parameters, which affect their functionality.
Abstract: Increase in volume of biodiesel production in the world scenario proves that biodiesel is accepted as an alternative to conventional fuel. Production of biodiesel using alkaline catalyst has been commercially implemented due to its high conversion and low production time. For the product and process development of biodiesel, enzymatic transesterification has been suggested to produce a high purity product with an economic, environment friendly process at mild reaction conditions. The enzyme cost being the main hurdle can be overcome by immobilization. Immobilized enzyme, which has been successfully used in various fields over the soluble counterpart, could be employed in biodiesel production with the aim of reducing the production cost by reusing the enzyme. This review attempts to provide an updated compilation of the studies reported on biodiesel production by using lipase immobilized through various techniques and the parameters, which affect their functionality.
289 citations
TL;DR: Amberzyme-CALB was found to have far better stability for reuse relative to Novozym 435 for the polycondensation reaction and differences in CALB reactivity were discussed based on resin physical parameters and availability of active sites determined by active site titrations.
204 citations
TL;DR: The immobilized lipase proved to be stable and lost little activity when was subjected to repeated uses and the optimum pH for free and immobilized enzyme were 6, resulting in 80% immobilization yield.
Abstract: In the present work, a novel method for immobilization of lipase within hydrophilic polyurethane foams using polyglutaraldehyde was developed for the immobilization of Thermomyces lanuginosus lipase to produce biodiesel with canola oil and methanol. The enzyme optimum conditions were not affected by immobilization and the optimum pH for free and immobilized enzyme were 6, resulting in 80% immobilization yield. Using the immobilized lipase T. lanuginosus, the effects of enzyme loading, oil/alcohol molar ratio, water concentration, and temperature in the transesterification reaction were investigated. The optimal conditions for processing 20 g of refined canola oil were: 430 μg lipase, 1:6 oil/methanol molar ratio, 0.1 g water and 40 °C for the reactions with methanol. Maximum methyl esters yield was 90% of which enzymatic activity remained after 10 batches, when tert-butanol was adopted to remove by-product glycerol during repeated use of the lipase. The immobilized lipase proved to be stable and lost little activity when was subjected to repeated uses.
183 citations
TL;DR: The stabilization degree of the derivative increased with the immobilization time, an indication that a multipoint covalent attachment between enzyme and the support had really occurred, and 58-fold more stable than the soluble enzyme.
Abstract: In this work Candida antarctica lipase type B (CALB) was immobilized on agarose and chitosan. The influence of activation agents (glycidol, glutaraldehyde and epichlorohydrin) and immobilization time (5, 24 and 72 h) on hydrolytic activity, thermal and alkaline stabilities of the biocatalyst was evaluated. Protein concentration and enzymatic activity in the supernatant were determined during the immobilization process. More active derivatives were attained when the enzymatic extract was first purified through dialysis. The highest activities achieved were: for agarose-glyoxyl (with glycidol), 845 U/g of gel, after 72 h of immobilization; for chitosan-glutaraldehyde and agarose-glutaraldehyde, respectively, 1209 U/g of gel and 2716 U/g of gel, after 5 h of immobilization. Thermal stability was significantly increased, when compared to the soluble enzyme: 20-fold for agarose-glyoxyl (with glycidol)-CALB, 18-fold for chitosan-glutaraldehyde-CALB and 21-fold for agarose-glutaraldehyde. The best derivative, 58-fold more stable than the soluble enzyme, was obtained when CALB was immobilized on chitosan activated in two steps, using glycidol and glutaraldehyde, 72 h immobilization time. The stabilization degree of the derivative increased with the immobilization time, an indication that a multipoint covalent attachment between enzyme and the support had really occurred.
164 citations
TL;DR: The nanosheet-based ZnO could be a promising matrix for the fabrication of direct electrochemical biosensors, and may find wide potential applications in biomedical detection and environmental analysis.
160 citations
TL;DR: This review will detail recent patents for techniques for enzyme immobilization, along with patents for chemical and biotechnological processes that can employ immobilized enzymes, which allow for the re-use of the enzymatic catalysts.
Abstract: Enzymes are proteins that catalyze chemical reactions. Unlike more traditional organic and inorganic catalysts, enzymes are large and fragile molecules, so over the years, scientists and engineers have found it more difficult to immobilize enzyme catalysts on easily separateable supports for use and re-use in a variety of technologies. Over the last decade, enzyme immobilization has become more important in industry, medicine, and biotechnology. This review will detail recent patents for techniques for enzyme immobilization, along with patents for chemical and biotechnological processes that can employ immobilized enzymes, which allow for the re-use of the enzymatic catalysts. These techniques include methods varying from physical adsorption and covalent attachment to entrapment in polymers and sol-gels. These techniques have shown value in the development of biosensors, bioprocessing for the chemical industry and the pharmaceutical industry, and bioremediation.
159 citations
TL;DR: It is shown for the first time that cofactor NAD(H) covalently attached to micro particles, which can be easily recovered and reused, effectively mediated multistep reactions catalyzed by enzymes that were also immobilized with the micro particles.
Abstract: Efficient cofactor regeneration and reuse are highly desired for many important biotransformation applications. Here we show for the first time that cofactor NAD(H) covalently attached to micro particles, which can be easily recovered and reused, effectively mediated multistep reactions catalyzed by enzymes that were also immobilized with the micro particles. Such an immobilized enzyme-cofactor catalytic system was examined for the production of methanol from CO(2) with in situ cofactor regeneration. Four enzymes including formate, formaldehyde, alcohol, and glutamate dehydrogenases were coimmobilized using the same particles as that used for cofactor immobilization (enzymes and cofactor were immobilized separately). Reactions were performed by bubbling CO(2) in a suspension solution of the particle-attached enzymes and cofactor. It appeared that the collision among the particles afforded sufficient interactions between the cofactor and enzymes, and thus enabled the sequential transformation of CO(2) to methanol along with cofactor regeneration. For a 30-min batch reaction, a productivity of 0.02 micromol methanol/h/g-enzyme was achieved. That was lower than but comparable to the 0.04 micromol methanol/h/g-enzyme observed for free enzymes and cofactor at the same reaction conditions. The immobilized system showed fairly good stabilities in reusing. Over 80% of their original productivity was retained after 11 reusing cycles, with a cumulative methanol yield based on the amount of cofactor reached 127%. That was a promising enhancement in cofactor utilization as compared to the single-batch yield of 12% observed with free enzymes and free cofactor.
158 citations
TL;DR: Activity of beta-galactosidase covalently attached to differently sized particles have been evaluated and compared and the highest activity was shown by the biocatalyst immobilized on nanoparticles obtained by means of the ionotropic gelation method with sodium sulphate as gelation agent.
149 citations
TL;DR: A simple way of fabricating enzymatic membrane reactor with high enzyme loading and activity retention from the conjugation between nanofibrous membrane and lipase was devised andabilities of the immobilized lipase were obviously improved.
124 citations
TL;DR: In this article, a graft polymerization of glycidyl methacrylate (GMS) and methacetyl-methacryloxyethyl trimethyl ammonium chloride (MTHC) onto the surface of modified-Fe 3 O 4 nanoparticles is described.
TL;DR: In this paper, the authors compared different types of bacterial cellulose beads for enzyme immobilization and found that the smallest size (0.5-1.5mm) were the best support.
Abstract: Over recent years, there has been a growing interest in the use of cellulose materials in bioprocessing technologies. Bacterial cellulose which is the pure cellulose has unique physical properties which differ from those of plant cellulose and has therefore attracted attention as a new functional material. The applications of bacterial cellulose rarely use the pellet type but it has potential in enzyme immobilization since pellet form is usually used in this field. In this research, Glucoamylase which is widely used in the food industry was immobilized on bacterial cellulose beads after testing using various activation procedures. The results showed that the epoxy method with glutaraldehyde coupling was the best method. After comparison of the different types of bacterial cellulose beads for glucoamylase immobilization, the wet bacterial cellulose beads of the smallest size (0.5–1.5 mm) were the best support. The immobilization of enzyme enhances its stability against changes in the pH value and temperature especially in the lower temperature region. The relative activity of the immobilized glucoamylase was still above 77% at pH 2.0 and it was the highest value in the literature. The relative activities were more than 68% in the lower temperature region even at 20 °C. Thus, bacterial cellulose beads are a practical potential support for the preparation of immobilized enzymes in industrial applications.
TL;DR: In this paper, a systematic study dealing with the influence of several parameters on the immobilization of lipase in ordered mesoporous materials (OMM) is presented, including the structure (cubic or hexagonal), the nature of the pores (channel-like or cage-like), the connectivity of the porous network and the pore size.
TL;DR: The substrate specificity of immobilized enzyme revealed more efficient hydrolysis of higher carbon length (C-16) ester than other ones and the bound lipase showed enhanced activity when exposed to n-heptane.
TL;DR: Poly(acrylic acid) brushes are employed as templates to immobilize ribonuclease A (RNase A), which is commonly used to remove RNA from plasmid DNA preparations, and covalent esterification resulted in similar temperature dependence as free enzyme, whereas metal-ion complexation showed no temperature dependence indicating a significant change in conformation.
Abstract: The ability to immobilize proteins with high binding capacities on surfaces while maintaining their activity is critical for protein microarrays and other biotechnological applications. We employed poly(acrylic acid) (PAA) brushes as templates to immobilize ribonuclease A (RNase A), which is commonly used to remove RNA from plasmid DNA preparations. The brushes are grown by surface-anchored atom-transfer radical polymerization (ATRP) initiators. RNase A was immobilized by both covalent esterification and a high binding capacity metal-ion complexation method to PAA brushes. The polymer brushes immobilized 30 times more enzyme compared to self-assembled monolayers. As the thickness of the brush increases, the surface density of the RNase A increases monotonically. The immobilization was investigated by ellipsometry, X-ray photoelectron spectroscopy (XPS), thermogravimetric analysis (TGA), and near-edge X-ray absorption fine structure spectroscopy (NEXAFS). The activity of the immobilized RNase A was determined using UV absorbance. As much as 11.0 microg/cm(2) of RNase A was bound to PAA brushes by metal-ion complexation compared to 5.8 microg/cm(2) by covalent immobilization which is 30 and 16 times the estimated mass bound in a monolayer. The calculated diffusion coefficient D was 0.63 x 10(-14) cm(2)/s for metal-ion complexation and 0.71 x 10(-14) cm(2)/s for covalent immobilization. Similar values of D indicate that the binding kinetics is similar, but the thermodynamic equilibrium coverage varies with the binding chemistry. Immobilization kinetics and thermodynamics were characterized by ellipsometry for both methods. A maximum relative activity of 0.70-0.80 was reached between five and nine monolayers of the immobilized enzyme. However, the relative activity for covalent immobilization was greater than that of metal-ion complexation. Covalent esterification resulted in similar temperature dependence as free enzyme, whereas metal-ion complexation showed no temperature dependence indicating a significant change in conformation.
TL;DR: It is concluded that mPOS-PVA is an attractive and efficient support for b-galactosidase immobilization and was effective in hydrolyzing lactose from milk.
TL;DR: In this paper, a novel detection method based on biosensors comprising an immobilized enzyme in mesoporous silica materials (FSM8.0 or P123-M), an electrochemical mediator (i.e., quinone), and a electrochemical cell, using the enzyme formaldehyde dehydrogenase was presented.
Abstract: Mesoporous silica materials have a potential application for enzyme immobilization, which increases the stability of enzymes. We report the development of a novel detection method based on biosensors comprising an immobilized enzyme in mesoporous silica materials (i.e., FSM8.0 or P123-M), an electrochemical mediator (i.e., quinone), and an electrochemical cell, using the enzyme formaldehyde dehydrogenase. These biosensors exhibit a rapid response and high sensitivity, and they can detect 1.2 μM of formaldehyde in an aqueous solution (corresponding to sub-ppb atmospheric concentration of formaldehyde). Furthermore, the sensors exhibit high selectivity, reusability, and a remarkable storage stability (stable over 80 days), indicating that formaldehyde dehydrogenase retains its highly ordered structure in these mesoporous silica materials. These results indicate that mesoporous silica materials can provide favorable methods for enzyme immobilization on the electrode and they are useful for developing high-performance electrochemical biosensors.
TL;DR: In this paper, a process for producing non-monosaccharide and high-purity galactooligosACcharides (GOS) was proposed, which was obtained from lactose by Penicillium expansum F3 β-galactosidase immobilized in calcium alginate.
TL;DR: In this paper, the authors employed the same hydrophobically modified chitosan and Nafion® membranes to form and characterize enzyme modified electrodes for biofuel cell applications.
TL;DR: Free as well as alginate immobilized urease was utilized for detection and quantitation of cadmium (Cd2+) in aqueous samples revealing a clear dependence on the concentration of Cd2+.
TL;DR: The stabilization of a lipase from Bacillus thermocatenulatus (BTL2) by a new strategy is described, where the lipase is selectively adsorbed on hydrophobic supports and the carboxylic residues of the enzyme are modified with ethylenediamine, generating a new enzyme having 4-fold more amino groups than the native enzyme.
TL;DR: In this paper, the effect of silica as a host matrix on the enzyme kinetics was investigated. And the authors found that the PGA enzyme is more stable than the soluble form to temperature and pH environments and retained 73% of its activity after immobilization.
TL;DR: Surface-active cellulose films for covalent attachment of bioactive moieties were achieved by codissolution of cellulose with polyamidoamine (PAMAM) dendrimers in an ionic liquid followed by regeneration of the composite as a film.
TL;DR: Amino groups containing magnetic beads were used in covalent immobilization of the enzyme "chloroperoxidase (CPO)" which is one of a few enzymes that can catalyse the peroxide dependent oxidation of a wide spectrum of organic and inorganic compounds as mentioned in this paper.
TL;DR: The immobilized laccase not only can be operated magnetically, but also exhibits remarkably improved catalytic capacity and stability properties for various parameters, such as pH, temperature, reuse, and storage time, which can provide economic advantages for large-scale biotechnological applications of laccases.
Abstract: BACKGROUND: Immobilized enzymes provide many advantages over free enzymes including repeated or continuous reuse, easy separation of the product from reaction media, easy recovery of the enzyme, and improvement in enzyme stability. In order to improve catalytic activity of laccase and increase its industrial application, there is great interest in developing novel technologies on laccase immobilization. RESULTS: Magnetic Cu2+-chelated particles, prepared by cerium-initiated graft polymerization of tentacle-type polymer chains with iminodiacetic acid (IDA) as chelating ligand, were employed for Pycnoporus sanguineus laccase immobilization. The particles showed an obvious high adsorption capacity of laccase (94.1 mg g(-1) support) with an activity recovery of 68.0% after immobilization. The laccase exhibited improved stability in reaction conditions over a broad temperature range between 45 degrees C and 70 degrees C and an optimal pH value of 3.0 after being adsorbed on the magnetic metal-chelated particles. The value of the Michaelis constant (K-m) of the immobilized laccase (1.597 mmol L-1) was higher than that of the free one (0.761 mmol L-1), whereas the maximum velocity (V-max) was lower for the adsorbed laccase. Storage stability and temperature endurance of the immobilized laccase were found to increase greatly, and the immobilized laccase retained 87.8% of its initial activity after 10 successive batch reactions. CONCLUSION: The immobilized laccase not only can be operated magnetically, but also exhibits remarkably improved catalytic capacity and stability properties for various parameters, such as pH, temperature, reuse, and storage time, which can provide economic advantages for large-scale biotechnological applications of laccase. (c) 2007 Society of Chemical Industry.
TL;DR: Macroporous polymer particles containing surface epoxy groups were synthesized for immobilization of Candida rugosa lipase and AGE-150 polymer found to give maximum lipase activity yield and therefore evaluated for temperature, pH and storage stability.
TL;DR: The immobilized chitosanase immobilized on amylose-coated magnetic nanoparticles was used to produce pentamers and hexamers of chitOSan oligosaccharides, which possess beneficial biological activities and could be recovered and reused repeatedly.
TL;DR: Pectinase was immobilized on an activated agar-gel support by multipoint attachment and exhibited great operational stability, and an 81% residual activity was observed in the immobilized enzyme after 10 batch reactions.
TL;DR: In this article, a third generation biosensor based on HRP and a Sonogel-Carbon electrode has been fabricated with the aim of monitoring hydrogen peroxide in aqueous media via a direct electron transfer process.
TL;DR: A lipase from Bacillus thermocatenulatus cloned in E. coli has been purified using a very simple method: interfacial activation on a hydrophobic support followed by desorption with Triton.
Abstract: A lipase from Bacillus thermocatenulatus (BTL2) cloned in E. coli has been purified using a very simple method: interfacial activation on a hydrophobic support followed by desorption with Triton. Only one band was detected by SDS-PAGE. The pure enzyme was immobilized using different methodologies. BTL2 adsorbed on a hydrophobic support (octadecyl-Sepabeads) exhibited a hyperactivation with respect to the soluble enzyme, whereas the other immobilized preparations suffered a slight decrease in the expressed activity. The soluble enzyme was very stable, but all immobilized preparations were much more stable than the soluble enzyme, the octadecyl-Sepabeads-BTL2 preparation being the most stable one in all conditions (high temperature or in the presence of organic cosolvents), maintaining 100% of the activity at 65 degrees C or 30% of dioxane and 45 degrees C after several days of incubation. The glyoxyl preparation, the second more stable, retained 80% of the initial activity after 2 days, respectively. The adsorption of this thermophilic lipase on octadecyl-Sepabeads permitted an increase in the optimal temperature of the enzyme of 10 degrees C.