Novel L-DOPA-Derived Poly(ester amide)s: Monomers, Polymers, and the First L-DOPA-Functionalized Biobased Adhesive Tape

The synthesis, characterization, and testing of a range of novel bio‐inspired L‐DOPA‐derived poly(ester amide)s is presented, using a widely applicable, straightforward chemistry. A model system is used to study and establish the monomer and polymer synthetic protocols, and to provide a set of optim...

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Published in	Macromolecular rapid communications. Vol. 35; no. 1; pp. 71 - 76
Main Authors	Manolakis, Ioannis, Noordover, Bart A. J., Vendamme, Richard, Eevers, Walter
Format	Journal Article
Language	English
Published	Weinheim Blackwell Publishing Ltd 01.01.2014 Wiley Wiley Subscription Services, Inc
Subjects	adhesive properties Adhesives Amides - chemistry Applied sciences bio-inspired polymers Exact sciences and technology L-DOPA Levodopa - chemistry Magnetic Resonance Spectroscopy Organic polymers Physicochemistry of polymers poly(ester amide)s polycondensation Polyesters - chemistry Polymers Polymers with particular properties Preparation, kinetics, thermodynamics, mechanism and catalysts Tissue Adhesives Nitro compound bio-inspired polymers Adhesivity Solution polycondensation Polyesteramide Head to tail polymer Adhesive tape Esteramide copolymer Experimental study Functional polymer adhesive properties polycondensation poly(ester amide)s Biomimetic compound Preparation L-DOPA Surface properties Unsaturated copolymer Phenols Levodopa
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Abstract	The synthesis, characterization, and testing of a range of novel bio‐inspired L‐DOPA‐derived poly(ester amide)s is presented, using a widely applicable, straightforward chemistry. A model system is used to study and establish the monomer and polymer synthetic protocols, and to provide a set of optimum reaction conditions. It is further shown that fully biobased L‐DOPA‐containing adhesive tapes can be fabricated, which are positively evaluated in terms of their adhesive properties. The newly developed synthetic protocol constitutes a versatile platform for accessing and tailoring a plethora of relevant structures, including a variety of potentially biocompatible poly(ethylene glycol)‐based materials. A family of novel bio‐inspired L‐DOPA‐derived poly(ester amide)s is the subject of this work. The developed synthetic platform allows for facile synthesis, targets a wide range of structures and provides good control over the molecular and thermal properties of the resulting polymers. A particular composition containing L‐DOPA and fatty acid dimer residues is tested in terms of its adhesive performance with promising results.
AbstractList	The synthesis, characterization, and testing of a range of novel bio‐inspired L ‐DOPA‐derived poly(ester amide)s is presented, using a widely applicable, straightforward chemistry. A model system is used to study and establish the monomer and polymer synthetic protocols, and to provide a set of optimum reaction conditions. It is further shown that fully biobased L ‐DOPA‐containing adhesive tapes can be fabricated, which are positively evaluated in terms of their adhesive properties. The newly developed synthetic protocol constitutes a versatile platform for accessing and tailoring a plethora of relevant structures, including a variety of potentially biocompatible poly(ethylene glycol)‐based materials. image The synthesis, characterization, and testing of a range of novel bio-inspired L-DOPA-derived poly(ester amide)s is presented, using a widely applicable, straightforward chemistry. A model system is used to study and establish the monomer and polymer synthetic protocols, and to provide a set of optimum reaction conditions. It is further shown that fully biobased L-DOPA-containing adhesive tapes can be fabricated, which are positively evaluated in terms of their adhesive properties. The newly developed synthetic protocol constitutes a versatile platform for accessing and tailoring a plethora of relevant structures, including a variety of potentially biocompatible poly(ethylene glycol)-based materials. A family of novel bio-inspired L-DOPA-derived poly(ester amide)s is the subject of this work. The developed synthetic platform allows for facile synthesis, targets a wide range of structures and provides good control over the molecular and thermal properties of the resulting polymers. A particular composition containing L-DOPA and fatty acid dimer residues is tested in terms of its adhesive performance with promising results. The synthesis, characterization, and testing of a range of novel bio‐inspired L‐DOPA‐derived poly(ester amide)s is presented, using a widely applicable, straightforward chemistry. A model system is used to study and establish the monomer and polymer synthetic protocols, and to provide a set of optimum reaction conditions. It is further shown that fully biobased L‐DOPA‐containing adhesive tapes can be fabricated, which are positively evaluated in terms of their adhesive properties. The newly developed synthetic protocol constitutes a versatile platform for accessing and tailoring a plethora of relevant structures, including a variety of potentially biocompatible poly(ethylene glycol)‐based materials. A family of novel bio‐inspired L‐DOPA‐derived poly(ester amide)s is the subject of this work. The developed synthetic platform allows for facile synthesis, targets a wide range of structures and provides good control over the molecular and thermal properties of the resulting polymers. A particular composition containing L‐DOPA and fatty acid dimer residues is tested in terms of its adhesive performance with promising results. The synthesis, characterization, and testing of a range of novel bio-inspired L-DOPA-derived poly(ester amide)s is presented, using a widely applicable, straightforward chemistry. A model system is used to study and establish the monomer and polymer synthetic protocols, and to provide a set of optimum reaction conditions. It is further shown that fully biobased L-DOPA-containing adhesive tapes can be fabricated, which are positively evaluated in terms of their adhesive properties. The newly developed synthetic protocol constitutes a versatile platform for accessing and tailoring a plethora of relevant structures, including a variety of potentially biocompatible poly(ethylene glycol)-based materials.The synthesis, characterization, and testing of a range of novel bio-inspired L-DOPA-derived poly(ester amide)s is presented, using a widely applicable, straightforward chemistry. A model system is used to study and establish the monomer and polymer synthetic protocols, and to provide a set of optimum reaction conditions. It is further shown that fully biobased L-DOPA-containing adhesive tapes can be fabricated, which are positively evaluated in terms of their adhesive properties. The newly developed synthetic protocol constitutes a versatile platform for accessing and tailoring a plethora of relevant structures, including a variety of potentially biocompatible poly(ethylene glycol)-based materials. The synthesis, characterization, and testing of a range of novel bio-inspired L-DOPA-derived poly(ester amide)s is presented, using a widely applicable, straightforward chemistry. A model system is used to study and establish the monomer and polymer synthetic protocols, and to provide a set of optimum reaction conditions. It is further shown that fully biobased L-DOPA-containing adhesive tapes can be fabricated, which are positively evaluated in terms of their adhesive properties. The newly developed synthetic protocol constitutes a versatile platform for accessing and tailoring a plethora of relevant structures, including a variety of potentially biocompatible poly(ethylene glycol)-based materials. [PUBLICATION ABSTRACT] The synthesis, characterization, and testing of a range of novel bio-inspired L-DOPA-derived poly(ester amide)s is presented, using a widely applicable, straightforward chemistry. A model system is used to study and establish the monomer and polymer synthetic protocols, and to provide a set of optimum reaction conditions. It is further shown that fully biobased L-DOPA-containing adhesive tapes can be fabricated, which are positively evaluated in terms of their adhesive properties. The newly developed synthetic protocol constitutes a versatile platform for accessing and tailoring a plethora of relevant structures, including a variety of potentially biocompatible poly(ethylene glycol)-based materials.
Author	Vendamme, Richard Eevers, Walter Manolakis, Ioannis Noordover, Bart A. J.
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Keywords	Nitro compound bio-inspired polymers Adhesivity Solution polycondensation Polyesteramide Head to tail polymer Adhesive tape Esteramide copolymer Experimental study Functional polymer adhesive properties polycondensation poly(ester amide)s Biomimetic compound Preparation L-DOPA Surface properties Unsaturated copolymer Phenols Levodopa
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Snippet	The synthesis, characterization, and testing of a range of novel bio‐inspired L‐DOPA‐derived poly(ester amide)s is presented, using a widely applicable,... The synthesis, characterization, and testing of a range of novel bio‐inspired L ‐DOPA‐derived poly(ester amide)s is presented, using a widely applicable,... The synthesis, characterization, and testing of a range of novel bio-inspired L-DOPA-derived poly(ester amide)s is presented, using a widely applicable,...
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SubjectTerms	adhesive properties Adhesives Amides - chemistry Applied sciences bio-inspired polymers Exact sciences and technology L-DOPA Levodopa - chemistry Magnetic Resonance Spectroscopy Organic polymers Physicochemistry of polymers poly(ester amide)s polycondensation Polyesters - chemistry Polymers Polymers with particular properties Preparation, kinetics, thermodynamics, mechanism and catalysts Tissue Adhesives
Title	Novel L-DOPA-Derived Poly(ester amide)s: Monomers, Polymers, and the First L-DOPA-Functionalized Biobased Adhesive Tape
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