Development and Application of Immobilized Lipase Assembled with Ionic Liquid on Poly(acrylic acid) Beads

학위논문 (석사)-- 서울대학교 대학원 : 화학생물공학부, 2014. 2. 이윤식. Immobilized enzymes have attracted much attention due to the characteristics of operational stability, enhanced activity, and reusability as well as simple separation. Most of commercial lipases are immobilized form and are used to convert fatty acids t...

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Main Author:	여세원
Other Authors:	이윤식, 공과대학 화학생물공학부
Format:	Thesis
Language:	English
Published:	서울대학교 대학원 2014
Subjects:	Bio-catalysis Lipase Esterification Ionic Liquid-grafted Poly(acrylic acid) Beads 660 Antarc* Antarctica
Online Access:	http://hdl.handle.net/10371/127096

id	ftseoulnuniv:oai:s-space.snu.ac.kr:10371/127096
record_format	openpolar
spelling	ftseoulnuniv:oai:s-space.snu.ac.kr:10371/127096 2023-05-15T13:48:54+02:00 Development and Application of Immobilized Lipase Assembled with Ionic Liquid on Poly(acrylic acid) Beads 여세원 이윤식 공과대학 화학생물공학부 2014 application/pdf 1152529 bytes http://hdl.handle.net/10371/127096 eng en eng 서울대학교 대학원 000000018252 http://hdl.handle.net/10371/127096 Bio-catalysis Lipase Esterification Ionic Liquid-grafted Poly(acrylic acid) Beads 660 Thesis 2014 ftseoulnuniv 2017-11-09T15:44:18Z 학위논문 (석사)-- 서울대학교 대학원 : 화학생물공학부, 2014. 2. 이윤식. Immobilized enzymes have attracted much attention due to the characteristics of operational stability, enhanced activity, and reusability as well as simple separation. Most of commercial lipases are immobilized form and are used to convert fatty acids to fatty acid alkyl esters (FEs) via an environment-friendly process. Immobilization of enzymes on resin beads has been utilized as a common tool in biological studies as well as bio-industrial field. However, factors controlling the stability of enzyme on resin beads have not been fully explored. So, esterification reactions are designed to evaluate how the stability of Candida antarctica lipase B (CALB) depends on the hydrophilic/hydrophobic properties with or without ionic liquids (ILs) on poly(acrylic acid) (PA) beads, because the ILs can provide a tunable microenvironment to the lipase. The catalytic activities of the immobilized lipases were compared under several factors such as bead properties, immobilization methods, loading levels of ILs, chain lengths of alkyl group on ILs, and solvents. From these results, we found that the IL-grafted PA beads which contained more hydrophilic properties (octyl group) showed better catalytic performance than hydrophobic ones (dodecyl group). The use of tert-butanol as a solvent was a pivotal factor to maintain the activity of the immobilized lipase. Surprisingly, the single type immobilized lipase, PA-C8Im-Lipase, (C8Im loading level, 1.2 mmol/g) showed the best catalytic performance (95% yield) at 50 oC even though the network type immobilized lipase was expected to show the best performance. The single type immobilized lipase can be reused with slightly loss of activity. In conclusion, octyl group provided positive influence to the lipase activity on IL-grafted PA beads without blocking the hydrophobic active site of lipase. Contents Abstract .i List of Abbreviations .vi List of Figures .viii List of Schemes .ix List of Tables .x Chapter 1. Introduction .1 1.1 General Introduction of Lipase .1 1.1.1 Progress of Enzyme Catalysts .1 1.1.2 Properties of Free Lipase .2 1.1.3 Industrially Valuable Ester Compounds.3 1.2 Enzyme Immobilization.4 1.2.1 Strategies for Enzyme Immobilization.4 1.2.2 Role of Polymer Supports in Lipases Immobilization6 1.2.3 Polymer Grafting for Enzyme Immobilization Assembled with Ionic Liquids .7 1.3 Research objectives.8 Chapter 2. Experiments .9 2.1 General .9 2.1.1 Materials .9 2.1.2 Instruments .11 2.2 Modification of Poly(acrylic acid) Beads .12 2.2.1 Preparation of Ionic Liquid-grafted Poly(acrylic acid) Beads .12 2.2.2 Immobilization of Candida Antarctica Lipase B on Ionic Liquid-grafted Poly(acrylic acid) Beads .16 2.3 Enzyme Activity Test.18 2.3.1 Hydrolysis of p-Nitrophenyl Butyrate.18 2.3.2 Esterification of Fatty Acids .19 Chapter 3. Results and Discussion .20 3.1 Preparation and Characterization of Immobilized Lipase.20 3.2 Catalytic Activities of the IL-grafted PA Beads.25 3.2.1 Hydrolysis of p-Nitrophenyl Butyrate .25 3.2.2 Esterification Activity of Immobilized Lipases .27 3.2.3 Reusability of Immobilized Lipase .33 Conclusion .34 References .35 Abstract in Korean .38 Appendix .40 Master Thesis Antarc* Antarctica Seoul National University: S-Space
institution	Open Polar
collection	Seoul National University: S-Space
op_collection_id	ftseoulnuniv
language	English
topic	Bio-catalysis Lipase Esterification Ionic Liquid-grafted Poly(acrylic acid) Beads 660
spellingShingle	Bio-catalysis Lipase Esterification Ionic Liquid-grafted Poly(acrylic acid) Beads 660 여세원 Development and Application of Immobilized Lipase Assembled with Ionic Liquid on Poly(acrylic acid) Beads
topic_facet	Bio-catalysis Lipase Esterification Ionic Liquid-grafted Poly(acrylic acid) Beads 660
description	학위논문 (석사)-- 서울대학교 대학원 : 화학생물공학부, 2014. 2. 이윤식. Immobilized enzymes have attracted much attention due to the characteristics of operational stability, enhanced activity, and reusability as well as simple separation. Most of commercial lipases are immobilized form and are used to convert fatty acids to fatty acid alkyl esters (FEs) via an environment-friendly process. Immobilization of enzymes on resin beads has been utilized as a common tool in biological studies as well as bio-industrial field. However, factors controlling the stability of enzyme on resin beads have not been fully explored. So, esterification reactions are designed to evaluate how the stability of Candida antarctica lipase B (CALB) depends on the hydrophilic/hydrophobic properties with or without ionic liquids (ILs) on poly(acrylic acid) (PA) beads, because the ILs can provide a tunable microenvironment to the lipase. The catalytic activities of the immobilized lipases were compared under several factors such as bead properties, immobilization methods, loading levels of ILs, chain lengths of alkyl group on ILs, and solvents. From these results, we found that the IL-grafted PA beads which contained more hydrophilic properties (octyl group) showed better catalytic performance than hydrophobic ones (dodecyl group). The use of tert-butanol as a solvent was a pivotal factor to maintain the activity of the immobilized lipase. Surprisingly, the single type immobilized lipase, PA-C8Im-Lipase, (C8Im loading level, 1.2 mmol/g) showed the best catalytic performance (95% yield) at 50 oC even though the network type immobilized lipase was expected to show the best performance. The single type immobilized lipase can be reused with slightly loss of activity. In conclusion, octyl group provided positive influence to the lipase activity on IL-grafted PA beads without blocking the hydrophobic active site of lipase. Contents Abstract .i List of Abbreviations .vi List of Figures .viii List of Schemes .ix List of Tables .x Chapter 1. Introduction .1 1.1 General Introduction of Lipase .1 1.1.1 Progress of Enzyme Catalysts .1 1.1.2 Properties of Free Lipase .2 1.1.3 Industrially Valuable Ester Compounds.3 1.2 Enzyme Immobilization.4 1.2.1 Strategies for Enzyme Immobilization.4 1.2.2 Role of Polymer Supports in Lipases Immobilization6 1.2.3 Polymer Grafting for Enzyme Immobilization Assembled with Ionic Liquids .7 1.3 Research objectives.8 Chapter 2. Experiments .9 2.1 General .9 2.1.1 Materials .9 2.1.2 Instruments .11 2.2 Modification of Poly(acrylic acid) Beads .12 2.2.1 Preparation of Ionic Liquid-grafted Poly(acrylic acid) Beads .12 2.2.2 Immobilization of Candida Antarctica Lipase B on Ionic Liquid-grafted Poly(acrylic acid) Beads .16 2.3 Enzyme Activity Test.18 2.3.1 Hydrolysis of p-Nitrophenyl Butyrate.18 2.3.2 Esterification of Fatty Acids .19 Chapter 3. Results and Discussion .20 3.1 Preparation and Characterization of Immobilized Lipase.20 3.2 Catalytic Activities of the IL-grafted PA Beads.25 3.2.1 Hydrolysis of p-Nitrophenyl Butyrate .25 3.2.2 Esterification Activity of Immobilized Lipases .27 3.2.3 Reusability of Immobilized Lipase .33 Conclusion .34 References .35 Abstract in Korean .38 Appendix .40 Master
author2	이윤식 공과대학 화학생물공학부
format	Thesis
author	여세원
author_facet	여세원
author_sort	여세원
title	Development and Application of Immobilized Lipase Assembled with Ionic Liquid on Poly(acrylic acid) Beads
title_short	Development and Application of Immobilized Lipase Assembled with Ionic Liquid on Poly(acrylic acid) Beads
title_full	Development and Application of Immobilized Lipase Assembled with Ionic Liquid on Poly(acrylic acid) Beads
title_fullStr	Development and Application of Immobilized Lipase Assembled with Ionic Liquid on Poly(acrylic acid) Beads
title_full_unstemmed	Development and Application of Immobilized Lipase Assembled with Ionic Liquid on Poly(acrylic acid) Beads
title_sort	development and application of immobilized lipase assembled with ionic liquid on poly(acrylic acid) beads
publisher	서울대학교 대학원
publishDate	2014
url	http://hdl.handle.net/10371/127096
genre	Antarc* Antarctica
genre_facet	Antarc* Antarctica
op_relation	000000018252 http://hdl.handle.net/10371/127096
_version_	1766249948976775168

Development and Application of Immobilized Lipase Assembled with Ionic Liquid on Poly(acrylic acid) Beads

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