Development of a heart valve model surface for optimization of surface modifications

[Display omitted] Current bioprosthetic valve replacements (BPVs) are susceptible to myriad complications, including calcification and thrombosis; however, recent research has explored surface modifications to encourage re-endothelialization of the tissue, preventing unwanted blood–tissue interactio...

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Veröffentlicht in:	Acta biomaterialia 2015-10, Vol.26, p.64-71
Hauptverfasser:	Fahrenholtz, Monica M., Wen, Suzanne, Grande-Allen, K. Jane
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Sprache:	eng
Schlagworte:	Biomimetic Materials - chemical synthesis Bioprosthesis Calcification Collagen - chemistry Elastic Modulus Equipment Failure Analysis Heart valve Heart Valve Prosthesis Heart valves In vitro test In vitro testing Materials Testing Optimization Platforms Polyethylene Glycols - chemistry Prosthesis Design Surface analysis Surface modification Surface Properties Thrombosis Valves X-ray photoelectron spectroscopy
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creator	Fahrenholtz, Monica M. Wen, Suzanne Grande-Allen, K. Jane
description	[Display omitted] Current bioprosthetic valve replacements (BPVs) are susceptible to myriad complications, including calcification and thrombosis; however, recent research has explored surface modifications to encourage re-endothelialization of the tissue, preventing unwanted blood–tissue interactions. A bioprosthetic valve surface model (BVSM) was developed to facilitate rapid in vitro optimization of surface modification techniques for BPVs. The BVSM was manufactured by photopolymerization of PEGDA and collagen type I and subsequent addition of amine-rich peptide to provide reactive sites for surface modification. This BVSM mimics surface mechanical properties of bioprosthetic valve tissue, as measured by micropipette aspiration. The BVSM successfully mimics the latent toxic effects of glutaraldehyde fixation, as shown through MTT assay results. Amine content, assessed by XPS, was shown to be significantly lower in the BVSM than unfixed tissue. However, incubation of the surface with amine-reactive NHS–PEG–Cy5 revealed even coverage of the BVSM surface, suggesting that there exists sufficient surface reactive groups to anchor surface modifications, and that translation of the modification process to tissue will yield more complete modification of the BPV surface. These results indicate successful construction of a BVSM that mimics essential properties of bioprosthetic valve tissue and its usefulness for rapid in vitro optimization of surface modification methods for endothelialization. Current bioprosthetic valve replacements are susceptible to many complications, including calcification and thrombosis; however, recent research has explored surface modifications to encourage the integration of the replacement with the native tissue, which would prevent unwanted blood–tissue interactions. However, methods to analyze and optimize such modifications are limited by the complex surface topography, individual variability, and opacity of native tissue. Thus, we have developed a novel bioprosthetic valve tissue model (BVM) which mimics the important features of the bioprosthetic valve tissue and serves as a platform for rapid optimization and testing of surface modification strategies for tissue valves. Thus, the BVM will provide a needed platform to support rapid improvement of clinically available cardiovascular implants.
doi_str_mv	10.1016/j.actbio.2015.08.021
format	Article
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Jane</creator><creatorcontrib>Fahrenholtz, Monica M. ; Wen, Suzanne ; Grande-Allen, K. Jane</creatorcontrib><description>[Display omitted] Current bioprosthetic valve replacements (BPVs) are susceptible to myriad complications, including calcification and thrombosis; however, recent research has explored surface modifications to encourage re-endothelialization of the tissue, preventing unwanted blood–tissue interactions. A bioprosthetic valve surface model (BVSM) was developed to facilitate rapid in vitro optimization of surface modification techniques for BPVs. The BVSM was manufactured by photopolymerization of PEGDA and collagen type I and subsequent addition of amine-rich peptide to provide reactive sites for surface modification. This BVSM mimics surface mechanical properties of bioprosthetic valve tissue, as measured by micropipette aspiration. The BVSM successfully mimics the latent toxic effects of glutaraldehyde fixation, as shown through MTT assay results. Amine content, assessed by XPS, was shown to be significantly lower in the BVSM than unfixed tissue. However, incubation of the surface with amine-reactive NHS–PEG–Cy5 revealed even coverage of the BVSM surface, suggesting that there exists sufficient surface reactive groups to anchor surface modifications, and that translation of the modification process to tissue will yield more complete modification of the BPV surface. These results indicate successful construction of a BVSM that mimics essential properties of bioprosthetic valve tissue and its usefulness for rapid in vitro optimization of surface modification methods for endothelialization. Current bioprosthetic valve replacements are susceptible to many complications, including calcification and thrombosis; however, recent research has explored surface modifications to encourage the integration of the replacement with the native tissue, which would prevent unwanted blood–tissue interactions. However, methods to analyze and optimize such modifications are limited by the complex surface topography, individual variability, and opacity of native tissue. Thus, we have developed a novel bioprosthetic valve tissue model (BVM) which mimics the important features of the bioprosthetic valve tissue and serves as a platform for rapid optimization and testing of surface modification strategies for tissue valves. 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Jane</creatorcontrib><title>Development of a heart valve model surface for optimization of surface modifications</title><title>Acta biomaterialia</title><addtitle>Acta Biomater</addtitle><description>[Display omitted] Current bioprosthetic valve replacements (BPVs) are susceptible to myriad complications, including calcification and thrombosis; however, recent research has explored surface modifications to encourage re-endothelialization of the tissue, preventing unwanted blood–tissue interactions. A bioprosthetic valve surface model (BVSM) was developed to facilitate rapid in vitro optimization of surface modification techniques for BPVs. The BVSM was manufactured by photopolymerization of PEGDA and collagen type I and subsequent addition of amine-rich peptide to provide reactive sites for surface modification. This BVSM mimics surface mechanical properties of bioprosthetic valve tissue, as measured by micropipette aspiration. The BVSM successfully mimics the latent toxic effects of glutaraldehyde fixation, as shown through MTT assay results. Amine content, assessed by XPS, was shown to be significantly lower in the BVSM than unfixed tissue. However, incubation of the surface with amine-reactive NHS–PEG–Cy5 revealed even coverage of the BVSM surface, suggesting that there exists sufficient surface reactive groups to anchor surface modifications, and that translation of the modification process to tissue will yield more complete modification of the BPV surface. These results indicate successful construction of a BVSM that mimics essential properties of bioprosthetic valve tissue and its usefulness for rapid in vitro optimization of surface modification methods for endothelialization. Current bioprosthetic valve replacements are susceptible to many complications, including calcification and thrombosis; however, recent research has explored surface modifications to encourage the integration of the replacement with the native tissue, which would prevent unwanted blood–tissue interactions. However, methods to analyze and optimize such modifications are limited by the complex surface topography, individual variability, and opacity of native tissue. Thus, we have developed a novel bioprosthetic valve tissue model (BVM) which mimics the important features of the bioprosthetic valve tissue and serves as a platform for rapid optimization and testing of surface modification strategies for tissue valves. 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Jane</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Development of a heart valve model surface for optimization of surface modifications</atitle><jtitle>Acta biomaterialia</jtitle><addtitle>Acta Biomater</addtitle><date>2015-10</date><risdate>2015</risdate><volume>26</volume><spage>64</spage><epage>71</epage><pages>64-71</pages><issn>1742-7061</issn><eissn>1878-7568</eissn><abstract>[Display omitted] Current bioprosthetic valve replacements (BPVs) are susceptible to myriad complications, including calcification and thrombosis; however, recent research has explored surface modifications to encourage re-endothelialization of the tissue, preventing unwanted blood–tissue interactions. A bioprosthetic valve surface model (BVSM) was developed to facilitate rapid in vitro optimization of surface modification techniques for BPVs. 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subjects	Biomimetic Materials - chemical synthesis Bioprosthesis Calcification Collagen - chemistry Elastic Modulus Equipment Failure Analysis Heart valve Heart Valve Prosthesis Heart valves In vitro test In vitro testing Materials Testing Optimization Platforms Polyethylene Glycols - chemistry Prosthesis Design Surface analysis Surface modification Surface Properties Thrombosis Valves X-ray photoelectron spectroscopy
title	Development of a heart valve model surface for optimization of surface modifications
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