Bioactivity in silica/poly(c-glutamic acid) sol-gel hybrids through calcium chelation

Esther M. Valliant; Frederik Romer; Daming Wang; David S. McPhail; Mark E. Smith; John V. Hanna; Julian R. Jones

doi:10.1016/j.actbio.2013.04.037

Bioactivity in silica/poly(c-glutamic acid) sol-gel hybrids through calcium chelation

Esther M. Valliant, Frederik Romer, Daming Wang, David S. McPhail, Mark E. Smith, John V. Hanna, Julian R. Jones

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61 Citas (Scopus)

Resumen

Bioactive glasses and inorganic/organic hybrids have great potential as biomedical implant materials. Sol-gel hybrids with interpenetrating networks of silica and biodegradable polymers can combine the bioactive properties of a glass with the toughness of a polymer. However, traditional calcium sources such as calcium nitrate and calcium chloride are unsuitable for hybrids. In this study calcium was incorporated by chelation to the polymer component. The calcium salt form of poly(c-glutamic acid) (cCaPGA) was synthesized for use as both a calcium source and as the biodegradable toughening component of the hybrids. Hybrids of 40 wt.% cCaPGA were successfully formed and had fine scale integration of Ca and Si ions, according to secondary ion mass spectrometry imaging, indicating a homogeneous distribution of organic and inorganic components. 29Si magic angle spinning nuclear magnetic resonance data demonstrated that the network connectivity was unaltered with changing polymer molecular weight, as there was no perturbation to the overall Si speciation and silica network formation. Upon immersion in simulated body fluid a hydroxycarbonate apatite surface layer formed on the hybrids within 1 week. The polymer molecular weight (Mw 30-120 kDa) affected the mechanical properties of the resulting hybrids, but all hybrids had large strains to failure, >26%, and compressive strengths, in excess of 300 MPa. The large strain to failure values showed that cCaPGA hybrids exhibited non-brittle behaviour whilst also incorporating calcium. Thus calcium incorporation by chelation to the polymer component is justified as a novel approach in hybrids for biomedical materials.

Idioma original	English
Páginas (desde-hasta)	7662-7671
Número de páginas	10
Publicación	Acta Biomaterialia
Volumen	9
N.º	8
DOI	https://doi.org/10.1016/j.actbio.2013.04.037
Estado	Published - ago. 2013
Publicado de forma externa	Sí

Nota bibliográfica

Funding Information:
This research has been funded in part by the Natural Sciences and Engineering Research Council of Canada , Canadian Centennial Scholarship Fund UK , the Department of Materials, Imperial College London , the EPSRC ( EP/E057098/1 , EP/E051669/1 , Challenging Engineering Grant EP/I020861/1 ) and the Philip Leverhulme Prize for Engineering . J.V.H. and M.E.S. acknowledge support for the solid-state NMR facilities at Warwick used in this research, which were funded by EPSRC and the University of Warwick. N.M.R. was also partially funded through the Birmingham Science City projects which were supported by Advantage West Midlands and the European Regional Development Fund. J.V.H. and M.E.S. acknowledge EPSRC support for FR via project EP/I004688/1.

ASJC Scopus Subject Areas

Biotechnology
Biomaterials
Biochemistry
Biomedical Engineering
Molecular Biology

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title = "Bioactivity in silica/poly(c-glutamic acid) sol-gel hybrids through calcium chelation",

abstract = "Bioactive glasses and inorganic/organic hybrids have great potential as biomedical implant materials. Sol-gel hybrids with interpenetrating networks of silica and biodegradable polymers can combine the bioactive properties of a glass with the toughness of a polymer. However, traditional calcium sources such as calcium nitrate and calcium chloride are unsuitable for hybrids. In this study calcium was incorporated by chelation to the polymer component. The calcium salt form of poly(c-glutamic acid) (cCaPGA) was synthesized for use as both a calcium source and as the biodegradable toughening component of the hybrids. Hybrids of 40 wt.% cCaPGA were successfully formed and had fine scale integration of Ca and Si ions, according to secondary ion mass spectrometry imaging, indicating a homogeneous distribution of organic and inorganic components. 29Si magic angle spinning nuclear magnetic resonance data demonstrated that the network connectivity was unaltered with changing polymer molecular weight, as there was no perturbation to the overall Si speciation and silica network formation. Upon immersion in simulated body fluid a hydroxycarbonate apatite surface layer formed on the hybrids within 1 week. The polymer molecular weight (Mw 30-120 kDa) affected the mechanical properties of the resulting hybrids, but all hybrids had large strains to failure, >26%, and compressive strengths, in excess of 300 MPa. The large strain to failure values showed that cCaPGA hybrids exhibited non-brittle behaviour whilst also incorporating calcium. Thus calcium incorporation by chelation to the polymer component is justified as a novel approach in hybrids for biomedical materials.",

author = "Valliant, {Esther M.} and Frederik Romer and Daming Wang and McPhail, {David S.} and Smith, {Mark E.} and Hanna, {John V.} and Jones, {Julian R.}",

note = "Funding Information: This research has been funded in part by the Natural Sciences and Engineering Research Council of Canada , Canadian Centennial Scholarship Fund UK , the Department of Materials, Imperial College London , the EPSRC ( EP/E057098/1 , EP/E051669/1 , Challenging Engineering Grant EP/I020861/1 ) and the Philip Leverhulme Prize for Engineering . J.V.H. and M.E.S. acknowledge support for the solid-state NMR facilities at Warwick used in this research, which were funded by EPSRC and the University of Warwick. N.M.R. was also partially funded through the Birmingham Science City projects which were supported by Advantage West Midlands and the European Regional Development Fund. J.V.H. and M.E.S. acknowledge EPSRC support for FR via project EP/I004688/1. ",

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AU - Valliant, Esther M.

AU - Romer, Frederik

AU - Wang, Daming

AU - McPhail, David S.

AU - Smith, Mark E.

AU - Hanna, John V.

AU - Jones, Julian R.

N1 - Funding Information: This research has been funded in part by the Natural Sciences and Engineering Research Council of Canada , Canadian Centennial Scholarship Fund UK , the Department of Materials, Imperial College London , the EPSRC ( EP/E057098/1 , EP/E051669/1 , Challenging Engineering Grant EP/I020861/1 ) and the Philip Leverhulme Prize for Engineering . J.V.H. and M.E.S. acknowledge support for the solid-state NMR facilities at Warwick used in this research, which were funded by EPSRC and the University of Warwick. N.M.R. was also partially funded through the Birmingham Science City projects which were supported by Advantage West Midlands and the European Regional Development Fund. J.V.H. and M.E.S. acknowledge EPSRC support for FR via project EP/I004688/1.

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N2 - Bioactive glasses and inorganic/organic hybrids have great potential as biomedical implant materials. Sol-gel hybrids with interpenetrating networks of silica and biodegradable polymers can combine the bioactive properties of a glass with the toughness of a polymer. However, traditional calcium sources such as calcium nitrate and calcium chloride are unsuitable for hybrids. In this study calcium was incorporated by chelation to the polymer component. The calcium salt form of poly(c-glutamic acid) (cCaPGA) was synthesized for use as both a calcium source and as the biodegradable toughening component of the hybrids. Hybrids of 40 wt.% cCaPGA were successfully formed and had fine scale integration of Ca and Si ions, according to secondary ion mass spectrometry imaging, indicating a homogeneous distribution of organic and inorganic components. 29Si magic angle spinning nuclear magnetic resonance data demonstrated that the network connectivity was unaltered with changing polymer molecular weight, as there was no perturbation to the overall Si speciation and silica network formation. Upon immersion in simulated body fluid a hydroxycarbonate apatite surface layer formed on the hybrids within 1 week. The polymer molecular weight (Mw 30-120 kDa) affected the mechanical properties of the resulting hybrids, but all hybrids had large strains to failure, >26%, and compressive strengths, in excess of 300 MPa. The large strain to failure values showed that cCaPGA hybrids exhibited non-brittle behaviour whilst also incorporating calcium. Thus calcium incorporation by chelation to the polymer component is justified as a novel approach in hybrids for biomedical materials.

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Bioactivity in silica/poly(c-glutamic acid) sol-gel hybrids through calcium chelation

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ASJC Scopus Subject Areas

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