Poly(γ-glutamic acid)/Silica Hybrids with Calcium Incorporated in the Silica Network by Use of a Calcium Alkoxide Precursor

Current materials used for bone regeneration are usually bioactive ceramics or glasses. Although they bond to bone, they are brittle. There is a need for new materials that can combine bioactivity with toughness and controlled biodegradation. Sol-gel hybrids have the potential to do this through their nanoscale interpenetrating networks (IPN) of inorganic and organic components. Poly(γ-glutamic acid) (γ-PGA) was introduced into the sol-gel process to produce a hybrid of γ-PGA and bioactive silica. Calcium is an important element for bone regeneration but calcium sources that are used traditionally in the sol-gel process, such as Ca salts, do not allow Ca incorporation into the silicate network during low-temperature processing. The hypothesis for this study was that using calcium methoxyethoxide (CME) as the Ca source would allow Ca incorporation into the silicate component of the hybrid at room temperature. The produced hybrids would have improved mechanical properties and controlled degradation compared with hybrids of calcium chloride (CaCl2), in which the Ca is not incorporated into the silicate network. Class II hybrids, with covalent bonds between the inorganic and organic species, were synthesised by using organosilane. Calcium incorporation in both the organic and inorganic IPNs of the hybrid was improved when CME was used. This was clearly observed by using FTIR and solid-state NMR spectroscopy, which showed ionic cross-linking of γ-PGA by Ca and a lower degree of condensation of the Si species compared with the hybrids made with CaCl2 as the Ca source. The ionic cross-linking of γ-PGA by Ca resulted in excellent compressive strength and reduced elastic modulus as measured by compressive testing and nanoindentation, respectively. All hybrids showed bioactivity as hydroxyapatite (HA) was formed after immersion in simulated body fluid (SBF).

[1]  Julian R. Jones,et al.  Bioactivity in silica/poly(γ-glutamic acid) sol-gel hybrids through calcium chelation. , 2013, Acta biomaterialia.

[2]  Julian R. Jones,et al.  Epoxide opening versus silica condensation during sol-gel hybrid biomaterial synthesis. , 2013, Chemistry.

[3]  Julian R. Jones,et al.  Effect of calcium source on structure and properties of sol-gel derived bioactive glasses. , 2012, Langmuir : the ACS journal of surfaces and colloids.

[4]  Julian R. Jones,et al.  Bioactive silica–poly(γ-glutamic acid) hybrids for bone regeneration: effect of covalent coupling on dissolution and mechanical properties and fabrication of porous scaffolds , 2012 .

[5]  Julian R. Jones,et al.  Electrospun silica/PLLA hybrid materials for skeletal regeneration , 2011 .

[6]  D. Brauer,et al.  Fluoride-containing bioactive glasses: Fluoride loss during melting and ion release in tris buffer solution , 2011 .

[7]  C. Ohtsuki,et al.  Modification of Polyglutamic Acid with Silanol Groups and Calcium Salts to Induce Calcification in a Simulated Body Fluid , 2011, Journal of biomaterials applications.

[8]  Molly M. Stevens,et al.  Silica‐Gelatin Hybrids with Tailorable Degradation and Mechanical Properties for Tissue Regeneration , 2010 .

[9]  Bedilu Allo,et al.  Synthesis and electrospinning of ε-polycaprolactone-bioactive glass hybrid biomaterials via a sol-gel process. , 2010, Langmuir : the ACS journal of surfaces and colloids.

[10]  Julian R. Jones,et al.  Synthesis of bioactive class II poly(γ-glutamic acid)/silica hybrids for bone regeneration , 2010 .

[11]  Julian R. Jones,et al.  Nanostructure evolution and calcium distribution in sol-gel derived bioactive glass , 2009 .

[12]  Jonathan C. Knowles,et al.  Preparation, structural characterisation and antibacterial properties of Ga-doped sol–gel phosphate-based glass , 2009 .

[13]  K. Hsieh,et al.  -Polyglutamic Acid Produced by Bacillus subtilis (natto): Structural Characteristics, Chemical Properties and Biological Functionalities , 2006 .

[14]  B. Beake Modelling indentation creep of polymers: a phenomenological approach , 2006 .

[15]  M. Vallet‐Regí,et al.  Nanostructured Hybrid Materials for Bone Tissue Regeneration , 2006 .

[16]  Julian R Jones,et al.  Optimising bioactive glass scaffolds for bone tissue engineering. , 2006, Biomaterials.

[17]  Y. Chujo,et al.  Synthesis of anionic polymer–silica hybrids by controlling pH in an aqueous solution , 2005 .

[18]  Julian R. Jones,et al.  Bioactive glass and hybrid scaffolds prepared by sol–gel method for bone tissue engineering , 2005 .

[19]  E. Bourhis,et al.  Time dependence of the indentation behavior of hybrid coatings , 2004 .

[20]  G. De,et al.  Inorganic–organic hybrid coatings on polycarbonate.: Spectroscopic studies on the simultaneous polymerizations of methacrylate and silica networks , 2003 .

[21]  Larry L Hench,et al.  Third-Generation Biomedical Materials , 2002, Science.

[22]  J. E. Mark,et al.  Polyimide−Ceramic Hybrid Composites by the Sol−Gel Route , 2001 .

[23]  L L Hench,et al.  Gene-expression profiling of human osteoblasts following treatment with the ionic products of Bioglass 45S5 dissolution. , 2001, Journal of biomedical materials research.

[24]  P. Judeinstein,et al.  Structural studies of ideal organic-inorganic nanocomposites by high resolution diffractometry and NMR spectroscopy techniques , 1999 .

[25]  P. Dubois,et al.  Biodegradable and biocompatible inorganic–organic hybrid materials. I. Synthesis and characterization† , 1997 .

[26]  Ulrich S. Schubert,et al.  Hybrid Inorganic-Organic Materials by Sol-Gel Processing of Organofunctional Metal Alkoxides , 1995 .

[27]  Douglas A. Loy,et al.  BRIDGED POLYSILSESQUIOXANES. HIGHLY POROUS HYBRID ORGANIC-INORGANIC MATERIALS , 1995 .

[28]  P. Judeinstein,et al.  Dynamics of the sol-gel transition in organic-inorganic nanocomposites , 1994 .

[29]  Bruce M. Novak,et al.  Hybrid nanocomposite materials―between inorganic glasses and organic polymers , 1993 .

[30]  G. Pharr,et al.  An improved technique for determining hardness and elastic modulus using load and displacement sensing indentation experiments , 1992 .

[31]  M. Wolcott Cellular solids: Structure and properties , 1990 .

[32]  C. J. Brinker,et al.  Hydrolysis and condensation of silicates: Effects on structure , 1988 .

[33]  Massimo Guglielmi,et al.  Precursors for sol-gel preparations , 1988 .

[34]  W. Hayes,et al.  Bone compressive strength: the influence of density and strain rate. , 1976, Science.

[35]  Larry L. Hench,et al.  Bonding mechanisms at the interface of ceramic prosthetic materials , 1971 .

[36]  S. Wereley,et al.  soft matter , 2019, Science.

[37]  Julian R Jones,et al.  Review of bioactive glass: from Hench to hybrids. , 2013, Acta biomaterialia.

[38]  E. Bourhis,et al.  Elaboration and mechanical characterization of nanocomposites thin films: Part I: Determination of the mechanical properties of thin films prepared by in situ polymerisation of tetraethoxysilane in poly(methyl methacrylate) , 2006 .

[39]  E. Bourhis,et al.  Elaboration and mechanical characterization of nanocomposites thin films Part II. Correlation between structure and mechanical properties of SiO2-PMMA hybrid materials , 2006 .

[40]  G. Kickelbick,et al.  Concepts for the incorporation of inorganic building blocks into organic polymers on a nanoscale , 2003 .

[41]  Mark E. Smith,et al.  Multinuclear solid-state NMR of inorganic materials , 2002 .

[42]  J. Mackenzie,et al.  Mechanical properties of ormosils , 1996 .

[43]  P. Judeinstein,et al.  Hybrid organic–inorganic materials: a land of multidisciplinarity , 1996 .

[44]  H. Schmidt Thin films, the chemical processing up to gelation , 1992 .

[45]  M. Ashby,et al.  Cellular solids: Structure & properties , 1988 .