Activation of lipase by sol-gel coating with hydrophobic alkyl-substituted silicates in supercritical carbon dioxide

Journal of Chemical Technology and Biotechnology

Volumn 84, Issue 9, 2009, Pages 1412-1417

  Kawakami, Koei ^a   Urakawa, Taiki ^a   Oda, Yasuhiro ^a   Iwai, Yoshio ^a  

^a KYUSHU UNIVERSITY   (Japan)

Author keywords

Alkyl substituted silicate; Encapsulation; Esterification; Lipase; Sol gel method; Supercritical carbon dioxide

Indexed keywords

ALKYL-SUBSTITUTED SILICATE; AQUEOUS SOLUTIONS; CRUDE LIPASE; ENZYMATIC ACTIVITIES; HYDROPHOBIC SILICATE; NONAQUEOUS MEDIA; NOVEL METHODS; RHIZOPUS ORYZAE; SILICA PRECURSORS; SOL-GEL COATINGS; SOL-GEL ENTRAPMENT; SOL-GEL METHOD; SOL-GEL ROUTES; SUPERCRITICAL CARBON DIOXIDE; SUPERCRITICAL CARBON DIOXIDES; TETRAMETHOXYSILANE;

ALKYLATION; CARBON DIOXIDE; COATINGS; ESTERIFICATION; ESTERS; GELATION; GELS; HYDROPHOBICITY; LIPASES; POWDERS; SILICA; SILICATES; SOL-GEL PROCESS; SOLS; SUPERCRITICAL FLUID EXTRACTION;

SOL-GELS;

CARBON DIOXIDE; DIMETHYLDIMETHOXYSILANE; SILANE DERIVATIVE; SILICATE; TETRAMETHOXYSILANE; TRIACYLGLYCEROL LIPASE; UNCLASSIFIED DRUG;

AQUEOUS SOLUTION; ARTICLE; CHEMICAL MODIFICATION; CONTROLLED STUDY; ENZYME ACTIVATION; ENZYME ACTIVITY; ENZYME IMMOBILIZATION; ESTERIFICATION; GEL; HYDROPHOBICITY; MATERIAL COATING; NONHUMAN; RHIZOPUS ORYZAE; SUPERCRITICAL FLUID;

RHIZOPUS ORYZAE;

EID: 70349487690     PISSN: 02682575     EISSN: 10974660     Source Type: Journal    
DOI: 10.1002/jctb.2178     Document Type: Article

References (36)

1. Dave BC, Dunn B, Valentine JS and Zink JI, Sol-gel encapsulation methods for biosensors. Anal Chem 66:1120-1127 (1994).
2. Jin W and Brennan JD, Properties and applications of proteins encapsulated within sol-gel derived materials. Anal Chim Acta 461:1-36 (2002).
3. Pierre AC,Thesol-gel encapsulation of enzymes.BiocatalBiotransform 22:145-170 (2004).
4. Avnir D, Coradin T, Lev O and Livage J, Recent bio-applications of sol-gel materials. J Mater Chem 15:1-18 (2005).
5. Gadre SY and Gouma PI, Biodoped ceramics: Synthesis, properties, and applications. J Am Ceram Soc 89:2987-3002 (2006).
6. Besanger T and Brennan JD, Entrapment of membrane proteins in sol-gel derived silica. J Sol-gel Sci Technol 40:209-225 (2006).
7. Coradin T and Livage J, Aqueous silicates in biological sol-gel applications: New perspectives of old precursors. Accts Chem Res 40:819-826 (2007).
8. Carturan G, Dal Toso R, Boninsegna S and Dal Monte R, Encapsulation of functional cells by sol-gel silica: Actual progressandperspectives for cell therapy. J Mater Chem 14:2087-2098 (2004).
9. Reetz MT, Zonta A and Simpelkamp J, Efficient immobilization of lipases by entrapment in hydrophobic sol-gel materials. Biotechnol Bioeng 49:527-534 (1996).
10. Reetz MT, Entrapment of biocatalysts in hydrophobic sol-gel materials for use in organic chemistry. Adv Mater 9:943-954 (1997).
11. Reetz MT, Tielmann P, Wiesenhofer W, Konen W and Zonta A, Second generation sol-gel encapsulated lipases: robust heterogeneous biocatalysts. Adv Synth Catal 345:717-728 (2003).
12. Kawakami K and Yoshida S, Thermal stabilization of lipase by sol-gel entrapment in organically modified silicates formed on kieselguhr. J Ferment Bioeng 82:239-245 (1996).
13. Furukawa S, Ono T, Ijima H and Kawakami K, Enhancement of activity of sol-gel immobilized lipase in organic media by pretreatment with substrate analogues. J Mol Catal B Enzymatic 15:65-70 (2001).
14. Furukawa S, Ono T, Ijima H and Kawakami K, Effect of imprinting sol-gel immobilized lipase with chiral template substrates in esterification of (R)-(+)- and (S)-(-)-glycidol. J Mol Catal B Enzymatic 17:23-28 (2002).
15. Pierre M, Buisson P, Fache F and Pierre A, Influence of the drying technique of silica gels on the enzymatic activity of encapsulated lipase. Biocatal Biotransform 18:237-251 (2000).
16. Buisson P, El Rassy H, Maury S and Pierre AC, Biocatalytic gelation of silica in the presence of a lipase. J Sol-gel Sci Technol 27:373-379 (2003).
17. El Rassy H, Maury S, Buisson P and Pierre AC, Hydrophobic silica aerogel-lipase biocatalysts: Possible interactions between the enzyme and the gel. J Non-Cryst solids 350:23-40 (2004).
18. Maury S, Buisson P, Perrard A and Pierre AC, Compared esterification kinetics of the lipase from Burkholderia cepacia either free or encapsulated in a silica aerogel. J Mol Catal B Enzymatic 32:193-203 (2005).
19. Pierre AC and Buisson P, Use of a lipase to synthesize silica gels in a hydrophobic organic solvent. J Sol-gel Sci Technol 38:63-72 (2006).
20. Noureddini H, Gao X, Joshi S and Wagner PR, Immobilization of Pseudomonas cepacia lipase by sol-gel entrapment and its application in the hydrolysis of soybean oil. J Am Oil Chem Soc 79:33-40 (2002).
21. Noureddini H, Gao X and Philkana RS, Immobilized Pseudomonas cepacia lipase for biodiesel fuel production from soybean oil. Bioresource Technol 96:769-777 (2005).
22. Noureddini H and Gao X, Characterization of sol-gel immobilized lipases. J Sol-gel Sci Technol 41:31-41 (2007).
23. Kuncova G, Szilva J, Hetflejs J and Sabata S, Catalysis in organic solvents with lipase immobilized by sol-gel technique. J Sol-gel Sci Technol 26:1183-1187 (2003).
24. Novak Z, Habulin M, Krmelj V and Knez Z, Silica aerogels as supports for lipase catalyzed esterifications at sub- and supercritical conditions. J Supercrit Fluids 27:169-178 (2003).
25. Chen JP and Lin WS, Sol-gel powders and supported sol-gel polymers for immobilization of lipase in ester synthesis. Enzyme Microb Technol 32:801-811 (2003).
26. Aucoin MG, Erhardt FA and Legge RL, Hyperactivation of Rhizomucor miehei lipase by hydrophobic xerogels. Biotechnol Bioeng 85:647-655 (2004).
27. Clifford JS and Legge RL, Use of water to evaluate hydrophobicity of organically-modified xerogel enzyme supports. Biotechnol Bioeng 92:231-237 (2005).
28. Vidinha P, Augusto V, Almeida M, Fonseca I, Fidalgo A, Ilharco L, et al, Sol-gel encapsulation: an efficient and versatile immobilization technique for cutinase in non-aqueous media. J Biotechnol 121:23-33 (2006).
29. Hara P, Hanefeld U and Kanerva LT, Sol-gel and cross-linked aggregates of lipase PS from Burkholderia cepacia and their application indry organic solvents. J Mol Catal B Enzymatic 50:80-86 (2008).
30. Menaa B, Herrero M, Rives V, Lavrenko M and Eggers DK, Favorable influence of hydrophobic surfaces on protein structure in porous organically-modified silica glasses. Biomaterials 29:2710-2718 (2008).
31. King MB, Mubarak A, Kim JD and Bott TR, The mutual solubilities of water with supercritical and liquid carbon dioxide. J Supercrit Fluids 5:296-302 (1992).
32. Gießauf A and Gamse T, A simple process for increasing the specific activity of porcine pancreatic lipase by supercritical carbon dioxide treatment. J Mol Catal B Enzymatic 9:57-64 (2000).
33. Bauer C, Gamse T and Marr R, Quality improvement of crude porcine pancreatic lipase preparations by treatment with humid supercritical carbon dioxide. Biochem Eng J 9:119-123 (2001).
34. Kawakami K, Sera Y, Sakai S, Ono T and Ijima H, Development and characterization of a silica monolith immobilized enzyme microbioreactor. Ind Eng Chem Res 44:236-240 (2005).
35. Kawakami K, Abe D, Urakawa T, Kawashima A, Oda Y, Takahashi R et al, Development of a silica monolith microbioreactor entrapping highly activated lipase and an experiment toward integration with chromatographic separation of chiral esters. J Sep Sci 30:3077-3084 (2007).
36. Kawakami K, Takahashi R, Shakeri M and Sakai S, Application of a lipase-immobilized silica monolith bioreactor to the production of fatty acid methyl esters. J Mol Catal B Enzymatic 57:194-197 (2009).