Optimizing the tensile properties of polyvinyl alcohol hydrogel for the construction of a bioprosthetic heart valve stent

Autor:	D R Boughner, Z. F. Zhang, A. J. Hui, Wankei Wan, G. Campbell
Rok vydání:	2002
Předmět:	Materials science Biocompatibility Artificial heart valve Swine Biomedical Engineering Biocompatible Materials In Vitro Techniques Prosthesis Design medicine.disease_cause Polyvinyl alcohol Artificial skin Biomaterials chemistry.chemical_compound Tensile Strength Freezing Materials Testing Ultimate tensile strength medicine Animals Humans Heart valve Bioprosthesis Cardiac cycle Hemodynamics Biomaterial Elasticity Biomechanical Phenomena Prosthesis Failure medicine.anatomical_structure chemistry Heart Valve Prosthesis Polyvinyl Alcohol Biomedical engineering
Zdroj:	Journal of Biomedical Materials Research. 63:854-861
ISSN:	1097-4636 0021-9304
Popis:	Although bioprosthetic heart valves offer the benefits of a natural opening and closing, better hemodynamics, and avoidance of life-long anticoagulant therapy, they nevertheless tend to fail in 10-15 years from tears and calcification. Several authors, including the present ones, have identified the rigid stent as a factor contributing to these failures. The ultimate solution is an artificial heart valve that has mechanical properties that allow it to move in conformity with the aortic root during the cardiac cycle, has superior hemodynamics, is nonthrombogenic, will last more than 20 years, and mitigates the need for anticoagulants. We have identified a polymer, polyvinyl alcohol (PVA) hydrogel, that has mechanical properties similar to soft tissue. The purpose of this research is to match the tensile properties of PVA to the porcine aortic root and to fabricate a stent prototype for a bioprosthetic heart valve with the use of the PVA hydrogel. Specimens of 15% w/w PVA were prepared by processing through 1-6 cycles of freezing (-20 degrees C) at 0.2 degrees C/min freeze rate and thawing (+20 degrees C) at different thawing rates (0.2 degrees C/min and 1 degrees C/min), for different holding times (1 and 6 h) at -20 degrees C. Subsequently tensile tests and stress-relaxation tests were conducted on the specimens. The different holding times at -20 degrees C demonstrated no difference in the result. The slower thawing rate improved the tensile properties but did not produce significant changes on the stress-relaxation properties. The nonlinear stress-strain curve for the PVA after the fourth freeze-thaw cycle matched the porcine aortic root within the physiological pressure range. The stress-relaxation curve for PVA also approximated the shape of the aortic root. The complex geometry of an artificial heart valve stent was successfully injection molded. These results, in combination with other preliminary findings for biocompatibility and fatigue behavior, suggest that PVA hydrogel is a promising biomaterial for implants, catheters, and artificial skin.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_dedup___::ee6e905eb6177e725d9fd23c6c9d51a0 https://doi.org/10.1002/jbm.10333 Zobrazit plný text záznamu Plný text