Poly(caprolactone-co-oxo-crown ether)-Based Poly(urethane)urea for Soft Tissue Engineering Applications

Poly(caprolactone-co-oxo-crown ether)-Based Poly(urethane)urea for Soft Tissue Engineering Applications

Random copolymers of ε-caprolactone and 2-oxo-12-crown-4 ether, poly(CL-co-OC), were used as soft segments in the synthesis of a set of poly(urethane)urea thermoplastic elastomers. With increasing OC content, the soft segment crystallinity decreased, which influenced the mechanical properties:  stra...

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Bibliographic Details
Published in:Biomacromolecules Vol. 8; no. 9; pp. 2739 - 2745
Main Authors: Wisse, Eva, Renken, Raymond A. E, Roosma, Jorg R, Palmans, Anja R. A, Meijer, E. W
Format: Journal Article
Language:English
Published: Washington, DC American Chemical Society 01-09-2007
Subjects:
Applied sciences
Biological and medical sciences
Crown Ethers - chemistry
Exact sciences and technology
Materials Testing
Medical sciences
Molecular Structure
Organic polymers
Physicochemistry of polymers
Polyesters - chemistry
Polymers with particular properties
Polyurethanes - chemistry
Preparation, kinetics, thermodynamics, mechanism and catalysts
Surgery (general aspects). Transplantations, organ and tissue grafts. Graft diseases
Technology. Biomaterials. Equipments
Tissue Engineering - methods
Biological properties
Lactone copolymer
Biodegradability
Tissue engineering
Segmented polymer
Telechelic polymer
Mechanical properties
Crown compound
Urea copolymer
Experimental study
Urethane copolymer
In vitro
Polyaddition
Hydrolysis
Random copolymer
Caprolactone copolymer
Preparation
Hydroxyl group
Biomaterial
Ring opening copolymerization
Aliphatic copolymer
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Summary:Random copolymers of ε-caprolactone and 2-oxo-12-crown-4 ether, poly(CL-co-OC), were used as soft segments in the synthesis of a set of poly(urethane)urea thermoplastic elastomers. With increasing OC content, the soft segment crystallinity decreased, which influenced the mechanical properties:  strain induced crystallization disappeared upon the introduction of OC into poly(CL). The material therefore became weaker, however, without a reduction in strain at break. All polymers showed mechanical properties that are suitable for soft tissue engineering. Degradation studies of poly(CL-co-OC) copolymers revealed a higher intrinsic rate of hydrolysis as compared to poly(CL). When at least two neighboring OC units were present in the soft segment, a jump in the intrinsic hydrolysis rate was observed. From this study we deduced an ideal OC:CL ratio for the thermoplastic elastomer soft segments for soft tissue engineering applications. An in vitro degradation study of these poly(urethane)urea showed an increased weight loss. Combined with the enhanced hydrophilicity and reduced crystallinity, we are confident that this will indeed lead to an increased degradation rate in vivo.
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ISSN:1525-7797
1526-4602
DOI:10.1021/bm070375d