Image_4_Improving the Post-polymerization Modification of Bio-Based Itaconate Unsaturated Polyesters: Catalyzing Aza-Michael Additions With Reusable Iodine on Acidic Alumina.TIF

Bio-based platform molecules such as itaconic, fumaric, and muconic acid offer much promise in the formation of sustainable unsaturated polyester resins upon reaction with suitable diols and polyols. The C=C bonds present in these polyester chains allows for post-polymerization modification and such...

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Main Authors: Oliver B. Moore, Polly-Ann Hanson, James W. Comerford, Alessandro Pellis, Thomas J. Farmer
Format: Still Image
Language:unknown
Published: 2019
Subjects:
Biochemistry
Environmental Chemistry
Geochemistry
Organic Chemistry
Inorganic Chemistry
Nuclear Chemistry
Medical Biochemistry: Proteins and Peptides (incl. Medical Proteomics)
Medical Biochemistry and Metabolomics not elsewhere classified
Food Chemistry and Molecular Gastronomy (excl. Wine)
Analytical Biochemistry
Cell Neurochemistry
Enzymes
Electroanalytical Chemistry
Analytical Chemistry not elsewhere classified
Organic Green Chemistry
Physical Organic Chemistry
Catalysis and Mechanisms of Reactions
Environmental Chemistry (incl. Atmospheric Chemistry)
biopolymer
itaconic acid
enzymatic polycondenzation
heterogeneous catalyst
Michael addition
mesaconate
antartic*
Online Access:https://doi.org/10.3389/fchem.2019.00501.s007
https://figshare.com/articles/Image_4_Improving_the_Post-polymerization_Modification_of_Bio-Based_Itaconate_Unsaturated_Polyesters_Catalyzing_Aza-Michael_Additions_With_Reusable_Iodine_on_Acidic_Alumina_TIF/8870537
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record_format openpolar
spelling ftfrontimediafig:oai:figshare.com:article/8870537 2023-05-15T14:15:25+02:00 Image_4_Improving the Post-polymerization Modification of Bio-Based Itaconate Unsaturated Polyesters: Catalyzing Aza-Michael Additions With Reusable Iodine on Acidic Alumina.TIF Oliver B. Moore Polly-Ann Hanson James W. Comerford Alessandro Pellis Thomas J. Farmer 2019-07-15T14:52:41Z https://doi.org/10.3389/fchem.2019.00501.s007 https://figshare.com/articles/Image_4_Improving_the_Post-polymerization_Modification_of_Bio-Based_Itaconate_Unsaturated_Polyesters_Catalyzing_Aza-Michael_Additions_With_Reusable_Iodine_on_Acidic_Alumina_TIF/8870537 unknown doi:10.3389/fchem.2019.00501.s007 https://figshare.com/articles/Image_4_Improving_the_Post-polymerization_Modification_of_Bio-Based_Itaconate_Unsaturated_Polyesters_Catalyzing_Aza-Michael_Additions_With_Reusable_Iodine_on_Acidic_Alumina_TIF/8870537 CC BY 4.0 CC-BY Biochemistry Environmental Chemistry Geochemistry Organic Chemistry Inorganic Chemistry Nuclear Chemistry Medical Biochemistry: Proteins and Peptides (incl. Medical Proteomics) Medical Biochemistry and Metabolomics not elsewhere classified Food Chemistry and Molecular Gastronomy (excl. Wine) Analytical Biochemistry Cell Neurochemistry Enzymes Electroanalytical Chemistry Analytical Chemistry not elsewhere classified Organic Green Chemistry Physical Organic Chemistry Catalysis and Mechanisms of Reactions Environmental Chemistry (incl. Atmospheric Chemistry) biopolymer itaconic acid enzymatic polycondenzation heterogeneous catalyst Michael addition mesaconate Image Figure 2019 ftfrontimediafig https://doi.org/10.3389/fchem.2019.00501.s007 2019-07-17T23:02:58Z Bio-based platform molecules such as itaconic, fumaric, and muconic acid offer much promise in the formation of sustainable unsaturated polyester resins upon reaction with suitable diols and polyols. The C=C bonds present in these polyester chains allows for post-polymerization modification and such moieties are conventionally utilized in curing processes during the manufacture of coatings. The C=C modification sites can also act as points to add useful pendants which can alter the polymers final properties such as glass transition temperature, biodegradability, hardness, polarity, and strength. A commonly observed modification is the addition of secondary amines via an aza-Michael addition. Conventional procedures for the addition of amines onto itaconate polyesters require reaction times of several days as a result of undesired side reactions, in particular, the formation of the less reactive mesaconate regioisomer. The slow reversion of the mesaconate back to itaconate, followed by subsequent amine addition, is the primary reason for such extended reaction times. Herein we report our efforts toward finding a suitable catalyst for the aza-Michael addition of diethylamine onto a model substrate, dimethyl itaconate, with the aim of being able to add amine onto the itaconate units without excessive regioisomerization to the inactive mesaconate. A catalyst screen showed that iodine on acidic alumina results in an effective, heterogeneous, reusable catalyst for the investigated aza-Michael addition. Extending the study further, itaconate polyester was prepared by Candida Antartica Lipase B (CaL-B) via enzymatic polytranesterification and subsequently modified with diethylamine using the iodine on acidic alumina catalyst, dramatically reducing the required length of reaction (>70% addition after 4 h). The approach represents a multidisciplinary example whereby biocatalytic polymerization is combined with chemocatalytic modification of the resultant polyester for the formation of useful bio-based polyesters. Still Image antartic* Frontiers: Figshare
institution Open Polar
collection Frontiers: Figshare
op_collection_id ftfrontimediafig
language unknown
topic Biochemistry
Environmental Chemistry
Geochemistry
Organic Chemistry
Inorganic Chemistry
Nuclear Chemistry
Medical Biochemistry: Proteins and Peptides (incl. Medical Proteomics)
Medical Biochemistry and Metabolomics not elsewhere classified
Food Chemistry and Molecular Gastronomy (excl. Wine)
Analytical Biochemistry
Cell Neurochemistry
Enzymes
Electroanalytical Chemistry
Analytical Chemistry not elsewhere classified
Organic Green Chemistry
Physical Organic Chemistry
Catalysis and Mechanisms of Reactions
Environmental Chemistry (incl. Atmospheric Chemistry)
biopolymer
itaconic acid
enzymatic polycondenzation
heterogeneous catalyst
Michael addition
mesaconate
spellingShingle Biochemistry
Environmental Chemistry
Geochemistry
Organic Chemistry
Inorganic Chemistry
Nuclear Chemistry
Medical Biochemistry: Proteins and Peptides (incl. Medical Proteomics)
Medical Biochemistry and Metabolomics not elsewhere classified
Food Chemistry and Molecular Gastronomy (excl. Wine)
Analytical Biochemistry
Cell Neurochemistry
Enzymes
Electroanalytical Chemistry
Analytical Chemistry not elsewhere classified
Organic Green Chemistry
Physical Organic Chemistry
Catalysis and Mechanisms of Reactions
Environmental Chemistry (incl. Atmospheric Chemistry)
biopolymer
itaconic acid
enzymatic polycondenzation
heterogeneous catalyst
Michael addition
mesaconate
Oliver B. Moore
Polly-Ann Hanson
James W. Comerford
Alessandro Pellis
Thomas J. Farmer
Image_4_Improving the Post-polymerization Modification of Bio-Based Itaconate Unsaturated Polyesters: Catalyzing Aza-Michael Additions With Reusable Iodine on Acidic Alumina.TIF
topic_facet Biochemistry
Environmental Chemistry
Geochemistry
Organic Chemistry
Inorganic Chemistry
Nuclear Chemistry
Medical Biochemistry: Proteins and Peptides (incl. Medical Proteomics)
Medical Biochemistry and Metabolomics not elsewhere classified
Food Chemistry and Molecular Gastronomy (excl. Wine)
Analytical Biochemistry
Cell Neurochemistry
Enzymes
Electroanalytical Chemistry
Analytical Chemistry not elsewhere classified
Organic Green Chemistry
Physical Organic Chemistry
Catalysis and Mechanisms of Reactions
Environmental Chemistry (incl. Atmospheric Chemistry)
biopolymer
itaconic acid
enzymatic polycondenzation
heterogeneous catalyst
Michael addition
mesaconate
description Bio-based platform molecules such as itaconic, fumaric, and muconic acid offer much promise in the formation of sustainable unsaturated polyester resins upon reaction with suitable diols and polyols. The C=C bonds present in these polyester chains allows for post-polymerization modification and such moieties are conventionally utilized in curing processes during the manufacture of coatings. The C=C modification sites can also act as points to add useful pendants which can alter the polymers final properties such as glass transition temperature, biodegradability, hardness, polarity, and strength. A commonly observed modification is the addition of secondary amines via an aza-Michael addition. Conventional procedures for the addition of amines onto itaconate polyesters require reaction times of several days as a result of undesired side reactions, in particular, the formation of the less reactive mesaconate regioisomer. The slow reversion of the mesaconate back to itaconate, followed by subsequent amine addition, is the primary reason for such extended reaction times. Herein we report our efforts toward finding a suitable catalyst for the aza-Michael addition of diethylamine onto a model substrate, dimethyl itaconate, with the aim of being able to add amine onto the itaconate units without excessive regioisomerization to the inactive mesaconate. A catalyst screen showed that iodine on acidic alumina results in an effective, heterogeneous, reusable catalyst for the investigated aza-Michael addition. Extending the study further, itaconate polyester was prepared by Candida Antartica Lipase B (CaL-B) via enzymatic polytranesterification and subsequently modified with diethylamine using the iodine on acidic alumina catalyst, dramatically reducing the required length of reaction (>70% addition after 4 h). The approach represents a multidisciplinary example whereby biocatalytic polymerization is combined with chemocatalytic modification of the resultant polyester for the formation of useful bio-based polyesters.
format Still Image
author Oliver B. Moore
Polly-Ann Hanson
James W. Comerford
Alessandro Pellis
Thomas J. Farmer
author_facet Oliver B. Moore
Polly-Ann Hanson
James W. Comerford
Alessandro Pellis
Thomas J. Farmer
author_sort Oliver B. Moore
title Image_4_Improving the Post-polymerization Modification of Bio-Based Itaconate Unsaturated Polyesters: Catalyzing Aza-Michael Additions With Reusable Iodine on Acidic Alumina.TIF
title_short Image_4_Improving the Post-polymerization Modification of Bio-Based Itaconate Unsaturated Polyesters: Catalyzing Aza-Michael Additions With Reusable Iodine on Acidic Alumina.TIF
title_full Image_4_Improving the Post-polymerization Modification of Bio-Based Itaconate Unsaturated Polyesters: Catalyzing Aza-Michael Additions With Reusable Iodine on Acidic Alumina.TIF
title_fullStr Image_4_Improving the Post-polymerization Modification of Bio-Based Itaconate Unsaturated Polyesters: Catalyzing Aza-Michael Additions With Reusable Iodine on Acidic Alumina.TIF
title_full_unstemmed Image_4_Improving the Post-polymerization Modification of Bio-Based Itaconate Unsaturated Polyesters: Catalyzing Aza-Michael Additions With Reusable Iodine on Acidic Alumina.TIF
title_sort image_4_improving the post-polymerization modification of bio-based itaconate unsaturated polyesters: catalyzing aza-michael additions with reusable iodine on acidic alumina.tif
publishDate 2019
url https://doi.org/10.3389/fchem.2019.00501.s007
https://figshare.com/articles/Image_4_Improving_the_Post-polymerization_Modification_of_Bio-Based_Itaconate_Unsaturated_Polyesters_Catalyzing_Aza-Michael_Additions_With_Reusable_Iodine_on_Acidic_Alumina_TIF/8870537
genre antartic*
genre_facet antartic*
op_relation doi:10.3389/fchem.2019.00501.s007
https://figshare.com/articles/Image_4_Improving_the_Post-polymerization_Modification_of_Bio-Based_Itaconate_Unsaturated_Polyesters_Catalyzing_Aza-Michael_Additions_With_Reusable_Iodine_on_Acidic_Alumina_TIF/8870537
op_rights CC BY 4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.3389/fchem.2019.00501.s007
_version_ 1766287813482905600

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