Candida antarctica lipase B immobilization

The concept of zeolite action was tested in a particular reaction where the enzyme is exposed from the beginning to an acidic environment the esterification of geraniol with acetic acid catalyzed by Candida antarctica lipase B immobilized on zeolite NaA [219]. Lipases have been used for the hydrolysis of triglycerides and due to their ambivalent hydrophobic/hydrophilic properties they are effective biocatalysts for the hydrolysis of hydrophobic substrates [220]. When water-soluble lipases are used in organic media they have to be immobilized on solid supports in order to exhibit significant catalytic activity. 

Biocatalysts also operate in ionic liquids [28]. The ones that have been most widely investigated are the lipase family of enzymes. For example, Candida Antarctica lipase B immobilized in [bmim][BF4] or [bmim][PFe] under anhydrous conditions is able to catalyse transesterifications at rates comparable to those observed in other solvents. Certain lipase mediated enantioselective acylations have even resulted in considerable improvements in enantiomeric excesses... 

The complete transformation of a racemic mixture into a single enantiomer is one of the challenging goals in asymmetric synthesis. We have developed metal-enzyme combinations for the dynamic kinetic resolution (DKR) of racemic primary amines. This procedure employs a heterogeneous palladium catalyst, Pd/A10(0H), as the racemization catalyst, Candida antarctica lipase B immobilized on acrylic resin (CAL-B) as the resolution catalyst and ethyl acetate or methoxymethylacetate as the acyl donor. Benzylic and aliphatic primary amines and one amino acid amide have been efficiently resolved with good yields (85—99 %) and high optical purities (97—99 %). The racemization catalyst was recyclable and could be reused for the DKR without activity loss at least 10 times. 

Miletid, N., R. Rohandi, Z. Vukovic, A. Nastasovic, and K. Loos. 2009. Surface Modification of Macroporous Poly(Glycidyl Methacrylate-Co-Ethylene Glycol Dimethacrylate) Resins for Improved Candida Antarctica Lipase B Immobilization. Reactive and Functional Polymers 69 (l) 68-75. 

Boros, Z., Falus, P., Markus, M., Weiser, D., Olah, M., Hornyanszky, G., Nagy, J., and Poppe, L. (2013) How the mode of Candida antarctica lipase B immobilization affects the continuous-flow kinetic resolution of racemic amines at various temperatures. J. Mol. Catal. B Enzym., 85- 86, 119-125. doi 10.1016/j.molcatb.2012.09.004... 

Deep eutectic solvents based on choline acetate (ChOAc), which have lower viscosities as compare to the ChCl/Urea eutectic mixture, have been also used as reaction media in several biocatalyzed transesterification reactions. In this sense, Zhao et al. reported the transesterification of ethyl sorbitate with 1-propanol by the lipase Novozym 435 Candida Antarctica lipase B immobilized on acrylic resins), achieving high initial rates (1 pmolmin g ) and selectivity (99%). Furthermore, in a model biodiesel synthesis system, the authors examined the transeterification of the lipid Miglyol oil 812 (a mixture of triglycerides of caprylic acid (C8) and capric acid (CIO)) with methanol, catalyzed by Novozym 435 in ChOAc/Gly (1 1.5 molar ratio). The biocatalytic reaction was very rapid in this eutectic mixture, with 97% conversion achieved after only 3 hours. 

Biphasic systems consisting of ionic liquids and supercritical CO2 showed dramatic enhancement in the operational stability of both free and immobilized Candida antarctica lipase B (CALB) in the catalyzed kinetic resolution of rac- -phenylethanol with vinyl propionate at 10 MPa and temperatures between 120 and 150°C (Scheme 30) 275). Hydrophobic ionic liquids, [EMIM]Tf2N or [BMIM]Tf2N, were shown to be essential for the stability of the enzyme in the biotransformation. Notwithstanding the extreme conditions, both the free and isolated enzymes were able specifically to catalyze the synthesis of (J )-l-phenylethyl propionate. The maximum enantiomeric excess needed for satisfactory product purity (ee >99.9%) was maintained. The (S)-l-phenylethanol reactant was not esterified. The authors suggested that the ionic liquids provide protection against enzyme denaturation by CO2 and heat. When the free enzyme was used, [EMIM]Tf2N appeared to be the best ionic liquid to protect the enzyme, which... 

Kinetic resolution technology has also been applied to the duloxetine problem (Scheme 14.13). In this case, chloroketone 41 was converted to racemic alcohol 43 using sodium borohydride. The racemate was then treated with vinyl butanoate in hexanes, in the presence of catalytic immobilized Candida antarctica Lipase B (CALB). The reaction was stopped after reaching 50% conversion, leading to the isolation of the desired (5)-chloroalcohoI 43a, as well as the (Zf)-ester 45 in good yields and excellent enantiomeric excesses. Chloroalcohol 43a was converted to duloxetine (3) via the... 

Chemoenzymatic polymerizations have the potential to further increase macro-molecular complexity by overcoming these limitations. Their combination with other polymerization techniques can give access to such structures. Depending on the mutual compatibility, multistep reactions as well as cascade reactions have been reported for the synthesis of polymer architectures and will be reviewed in the first part of this article. A unique feature of enzymes is their selectivity, such as regio-, chemo-, and in particular enantioselectivity. This offers oppormnities to synthesize novel chiral polymers and polymer architectures when combined with chemical catalysis. This will be discussed in the second part of this article. Generally, we will focus on the developments of the last 5-8 years. Unless otherwise noted, the term enzyme or lipase in this chapter refers to Candida antarctica Lipase B (CALB) or Novozym 435 (CALB immobilized on macroporous resin). 

Recent studies in the pharmaceutical field using MBR technology are related to optical resolution of racemic mixtures or esters synthesis. The kinetic resolution of (R,S)-naproxen methyl esters to produce (S)-naproxen in emulsion enzyme membrane reactors (E-EMRs) where emulsion is produced by crossflow membrane emulsification [38, 39], and of racemic ibuprofen ester [40] were developed. The esters synthesis, like for example butyl laurate, by a covalent attachment of Candida antarctica lipase B (CALB) onto a ceramic support previously coated by polymers was recently described [41]. An enzymatic membrane reactor based on the immobilization of lipase on a ceramic support was used to perform interesterification between castor oil triglycerides and methyl oleate, reducing the viscosity of the substrate by injecting supercritical CO2 [42],... 

Lozano, P., G. Villora, D. Gomez, A.B. Gayo, J.A. Sanchez-Conesa, M. Rubio and J.L. Iborra, Membrane Reactor with Immobilized Candida Antarctica Lipase B for Ester Synthesis in Supercritical Carbon Dioxide, Journal of Supercritical Fluids, 29, 121-128 (2004). 

Adsorption of enzymes to various polymeric resins is a straightforward means for immobilization. Zwitterionic molecules such as proteins can bind to both anionic and cationic ion exchange resins. Hydrophobic macroporous resins are also useful for immobilizing many enzymes, particularly lipases. For example, an immobilized form of Candida antarctica lipase B (CAL-B) on acrylic resin has been sold for many years under the name, Novozym 435 (N435). The enzyme is produced in a modified Aspergillus organism by submerged fermentation and is subsequently adsorbed onto a macroporous... 

Lou, W.-Y., Zong, M.-H., Liu, Y.-Y., and Wang, J.-F. 2006. Efficient enantioselective hydrolysis of D,L-phenylglycine methyl ester catalyzed by immobilized Candida antarctica lipase B in ionic liquid containing systems. Journal of Biotechnology, 125 64—74. 

The application of enzymes as catalysts in organic chemistry is closely linked to their immobilization. Indeed, many enzymes are only available in an immobilized form. The immobilized enzymes can be used as received, greatly easing their application. Numerous of these readily available immobilized enzymes are now the working horses of biocatalysis. This has even led to the incorrect use of the abbreviation of an enzyme name for a specific enzyme preparation, that is CALB for the immobilized form of Candida antarctica lipase B on cross-linked polymethacrylate (also known as Novozym 435). Vice versa the commercial name of an enzyme preparation-Amano PS-has taken the place of the enzyme (Burkhdderia cepacia lipase on dextrin or diatomaceous earth). Surprisingly, often no attention is paid to the fact that the enzyme is immobilized [1]. 

Lozano P, Villora G, Gomez D, Gayo AB, Sanchez-Conesa JA, Rubio M, and Iborra JL. Membrane reactor with immobilized Candida antarctica lipase B for ester synthesis in supercritical carbon dioxide. J. Supercrit. Fluids 2004 29(1-2) 121-128. 

Lozano P, Piamtongkam R, Kohns K, de Diego T, Vaultier M, Iborra JL (2007) Ionic liquids improve dtroneUyl ester synthesis catalyzed by immobilized Candida antarctica lipase B in solvent-free media. Green Chem 9 780-784... 

C and 80 bars. For that, four ionic liquids, namely [bmim INTf "], [bmim ] [PFg"]) [bdimim ][PFg ] and [omim+][PF ], were used. Figure 8.4 shows the synthetic activity and selectivity of immobilized Candida antarctica lipase B, CaLB, on ceramic membranes in scCO medium as well as in four different IL/scCO biphasic systems. 

As evident from Fig. 8.4, an increase in the selectivity has been observed in IL/ scCOj biphasic systems media (>99.5%) with respect to scCO assayed alone (95%). These results could be explained by the use of water-immiscible ILs which have a specific ability to reduce water activity in the enzyme microenvironment. The synthetic activity of the immobilized lipase in IL/scCO biphasic systems is lower than that in scCO assayed alone. Similar results were found by Mori et al. [40] in IL/ hexane biphasic systems. These authors reported that the enzymatic membranes prepared by simple adsorption of CaLB onto the surface were more reactive than membranes prepared with ILs. As can be observed in Fig. 8.4, the initial reaction rate in the assayed IL/scCO biphasic systems increased in the following sequence [bdimim ][PF ]<[bmim ][PFg ]<[bmim ][NTfj ]<[omim ] [PF ], which was practically in agreement with flie activity sequence reported by these authors using free Candida antarctica lipase B in homogeneous ionic liquid systems ([bmim ] [PF ]<[bdmim+][PFg ]<[bmim+][NTfj ]<[omim ][PF ]), with the exception of [bmim [PF ] and [bdimim+][PFg ]. These results were explained taking into account that biotransformation occurs within the ionic liquid phase, so substrates have to be transported from scCOj to the ionic liquid phase. The mechanism of substrate transport between the ionic liquid and the supercritical carbon dioxide could be by three consecutive steps diffusion of the substrates through the diffusion... 

Improved Immobilization Supports for Candida Antarctica Lipase B... 

Nakaoki, T., Kalra, B., Kumar, A., Gross, R.A., Kirk, O., and Christensen, M. (2002) Candida antarctica lipase B catalyzed polymerization of lactones Effect of immobilization matrix on polymerization kinetics and molecular weight. Abstracts of Papers of the Am. Chem. Soc., 224, U473. 

Candida antarctica lipase B chemically immobilized on epoxy-activated micro-and nanobeads Catalysts for polyester synthesis. Biomacromolecules, 9 (2), 463-471. 

Although there are notable exceptions as given below, the most common lipase-catalyst used for polyester synthesis is Candida antarctica lipase B (CALB) (please refer to Chapter 14 for more information on the structure and reaction mechanisms of CALB). The immobilized CALB catalyst that has been primarily used is Novozym 435, manufactured by Novozymes (Bagsvaerd, Denmark). Novozym 435 consists of CALB physically adsorbed within the macroporous resin Lewatit VPOC 1600 (poly[methyl methacrylate-co-butyl methacrylate], supplied by Bayer) (please refer to Chapter 3 for more information on Novozym 435). 

Many of the polymerizations presented in this book proceed in organic solvents. To enhance the stability of enzymes in these solvent systems and to ensure efficient recovery of the biocatalysts the enzymes are commonly immobilized. Chapter 2 reviews some of the new trends of enzyme immobilization on nanoscale materials, while Chapter 3 sheds light on some new approaches to improve the commercial immobilization of Candida antarctica lipase B - the biocatalyst most often employed in enzymatic polymer synthesis. 

Immobilization of Candida Antarctica Lipase B by Adsorption to Green Coconut Fiber... 

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