INVIVO FRAGMENTATION OF MICROPOROUS POLYURETHANE-BASED AND COPOLYESTERETHER ELASTOMER-BASED VASCULAR PROSTHESES

WLJ HINRICHS; J KUIT; H FEIL; CRH WILDEVUUR; J FEIJEN

INVIVO FRAGMENTATION OF MICROPOROUS POLYURETHANE-BASED AND COPOLYESTERETHER ELASTOMER-BASED VASCULAR PROSTHESES

WLJ HINRICHS, J KUIT, H FEIL, CRH WILDEVUUR, J FEIJEN

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

A previous study showed that microporous, compliant and (bio)degradable vascular prostheses prepared from a polyurethane/poly(L-lactic acid) mixture can function as a temporary scaffold for the regeneration of small-calibre arteries. In this study the mechanism of fragmentation of vascular prostheses made of polyurethane, copolyesterether and blends of either polyurethane or copolyesterether with polymers differing in biodegradability, crystallinity and glass transition temperature is investigated. Animal studies revealed that after 6 wk of implantation only the prostheses made of blends containing a second polymer which was non-elastic at 37-degrees-C were fragmented extensively, whether the second polymer was (bio)degradable or not. It is concluded that fragmentation of the prostheses is mainly caused by alternating stresses induced by the arterial pulsations and that (bio)degradation plays a minor role.

Original language	English
Pages (from-to)	585-593
Number of pages	9
Journal	Biomaterials
Volume	13
Issue number	9
Publication status	Published - 1992

Keywords

VASCULAR PROSTHESES
POLYURETHANE
DEGRADATION
ARTERIAL-WALL REGENERATION
RAT ABDOMINAL-AORTA
GRAFTS
COMPLIANT
BIODEGRADATION
NEOARTERIES
DEGRADATION
INVITRO

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title = "INVIVO FRAGMENTATION OF MICROPOROUS POLYURETHANE-BASED AND COPOLYESTERETHER ELASTOMER-BASED VASCULAR PROSTHESES",

abstract = "A previous study showed that microporous, compliant and (bio)degradable vascular prostheses prepared from a polyurethane/poly(L-lactic acid) mixture can function as a temporary scaffold for the regeneration of small-calibre arteries. In this study the mechanism of fragmentation of vascular prostheses made of polyurethane, copolyesterether and blends of either polyurethane or copolyesterether with polymers differing in biodegradability, crystallinity and glass transition temperature is investigated. Animal studies revealed that after 6 wk of implantation only the prostheses made of blends containing a second polymer which was non-elastic at 37-degrees-C were fragmented extensively, whether the second polymer was (bio)degradable or not. It is concluded that fragmentation of the prostheses is mainly caused by alternating stresses induced by the arterial pulsations and that (bio)degradation plays a minor role.",

keywords = "VASCULAR PROSTHESES, POLYURETHANE, DEGRADATION, ARTERIAL-WALL REGENERATION, RAT ABDOMINAL-AORTA, GRAFTS, COMPLIANT, BIODEGRADATION, NEOARTERIES, DEGRADATION, INVITRO",

author = "WLJ HINRICHS and J KUIT and H FEIL and CRH WILDEVUUR and J FEIJEN",

year = "1992",

language = "English",

volume = "13",

pages = "585--593",

journal = "Biomaterials",

issn = "0142-9612",

publisher = "ELSEVIER SCI LTD",

number = "9",

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TY - JOUR

T1 - INVIVO FRAGMENTATION OF MICROPOROUS POLYURETHANE-BASED AND COPOLYESTERETHER ELASTOMER-BASED VASCULAR PROSTHESES

AU - HINRICHS, WLJ

AU - KUIT, J

AU - FEIL, H

AU - WILDEVUUR, CRH

AU - FEIJEN, J

PY - 1992

Y1 - 1992

N2 - A previous study showed that microporous, compliant and (bio)degradable vascular prostheses prepared from a polyurethane/poly(L-lactic acid) mixture can function as a temporary scaffold for the regeneration of small-calibre arteries. In this study the mechanism of fragmentation of vascular prostheses made of polyurethane, copolyesterether and blends of either polyurethane or copolyesterether with polymers differing in biodegradability, crystallinity and glass transition temperature is investigated. Animal studies revealed that after 6 wk of implantation only the prostheses made of blends containing a second polymer which was non-elastic at 37-degrees-C were fragmented extensively, whether the second polymer was (bio)degradable or not. It is concluded that fragmentation of the prostheses is mainly caused by alternating stresses induced by the arterial pulsations and that (bio)degradation plays a minor role.

AB - A previous study showed that microporous, compliant and (bio)degradable vascular prostheses prepared from a polyurethane/poly(L-lactic acid) mixture can function as a temporary scaffold for the regeneration of small-calibre arteries. In this study the mechanism of fragmentation of vascular prostheses made of polyurethane, copolyesterether and blends of either polyurethane or copolyesterether with polymers differing in biodegradability, crystallinity and glass transition temperature is investigated. Animal studies revealed that after 6 wk of implantation only the prostheses made of blends containing a second polymer which was non-elastic at 37-degrees-C were fragmented extensively, whether the second polymer was (bio)degradable or not. It is concluded that fragmentation of the prostheses is mainly caused by alternating stresses induced by the arterial pulsations and that (bio)degradation plays a minor role.

KW - VASCULAR PROSTHESES

KW - POLYURETHANE

KW - DEGRADATION

KW - ARTERIAL-WALL REGENERATION

KW - RAT ABDOMINAL-AORTA

KW - GRAFTS

KW - COMPLIANT

KW - BIODEGRADATION

KW - NEOARTERIES

KW - DEGRADATION

KW - INVITRO

M3 - Article

SN - 0142-9612

VL - 13

SP - 585

EP - 593

JO - Biomaterials

JF - Biomaterials

IS - 9

ER -

INVIVO FRAGMENTATION OF MICROPOROUS POLYURETHANE-BASED AND COPOLYESTERETHER ELASTOMER-BASED VASCULAR PROSTHESES

Abstract

Keywords

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