Surface modification of bulk titanium substrates for biomedical applications via low-temperature microwave hydrothermal oxidation.

Micro-to-nanoscale surface topographies of orthopaedic and dental implants can affect fluid wetting and biological response. Nanoscale features can be superimposed on microscale roughness of titanium (Ti) surfaces at high temperatures, resulting in increased osteoblast differentiation. However, high temperatures can compromise mechanical properties of the bulk material. Here, we have developed a novel low-temperature microwave hydrothermal (MWHT) oxidation process for nanomodification of microrough (SLA) Ti surfaces. Nanoscale protuberances (20 -100 nm average diameter) were generated on SLA surfaces via MWHT treatment at 200°C in H2 O, or in aqueous solutions of H2 O2 or NH4 OH, for times ranging from 1 to 40 h. The size, shape, and crystalline content of the nanoprotuberances varied with the solution used and treatment time. The hydrophilicity of all MWHT-modified surfaces was dramatically enhanced. MG63 and normal human osteoblasts (NHOsts) were cultured on MWHT-treated SLA surfaces. While most responses to MWHT-modified surfaces were comparable to those seen on SLA controls, the MWHT-generated nanotopography reduced osteocalcin production by NHOst cells, suggesting that specific nanotopographic characteristics differentially mediate osteoblast phenotypic expression. MWHT processing provides a scalable, low-temperature route for tailoring nanoscale topographies on microroughened titanium implant surfaces with significantly enhanced wetting by water, without degrading the microscale surface structure of such implants. © 2017 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 106A: 782-796, 2018.

[1]  L. Tian,et al.  Synthesis of tapered tetragonal nanorods of anatase TiO2 with enhanced photocatalytic activity via a sol–hydrothermal process mediated by H2O2 and NH3 , 2015 .

[2]  K. Kuroda,et al.  Hydrothermal treatment of titanium alloys for the enhancement of osteoconductivity. , 2015, Materials science & engineering. C, Materials for biological applications.

[3]  B. Boyan,et al.  Implant osseointegration and the role of microroughness and nanostructures: lessons for spine implants. , 2014, Acta biomaterialia.

[4]  Baozhu Tian,et al.  Facile Tailoring of Anatase TiO2 Morphology by Use of H2O2: From Microflowers with Dominant {101} Facets to Microspheres with Exposed {001} Facets , 2013 .

[5]  K. Manzoor,et al.  Osteointegration of titanium implant is sensitive to specific nanostructure morphology. , 2012, Acta biomaterialia.

[6]  M. Kakihana,et al.  Hydrothermal synthesis of brookite-type titanium dioxide with snowflake-like nanostructures using a water-soluble citratoperoxotitanate complex , 2011 .

[7]  T. Albrektsson,et al.  Current knowledge about the hydrophilic and nanostructured SLActive surface , 2011, Clinical, cosmetic and investigational dentistry.

[8]  R. Tannenbaum,et al.  The effects of combined micron-/submicron-scale surface roughness and nanoscale features on cell proliferation and differentiation. , 2011, Biomaterials.

[9]  S. Oswald,et al.  How is wettability of titanium surfaces influenced by their preparation and storage conditions? , 2010, Journal of materials science. Materials in medicine.

[10]  Thomas J Webster,et al.  The relationship between the nanostructure of titanium surfaces and bacterial attachment. , 2010, Biomaterials.

[11]  Toshio Igarashi,et al.  Influence of surface wettability on competitive protein adsorption and initial attachment of osteoblasts , 2009, Biomedical materials.

[12]  W. Att,et al.  Age-dependent Degradation of the Protein Adsorption Capacity of Titanium , 2009, Journal of dental research.

[13]  F. Rosei,et al.  Improving biocompatibility of implantable metals by nanoscale modification of surfaces: an overview of strategies, fabrication methods, and challenges. , 2009, Small.

[14]  J. Granjeiro,et al.  Basic research methods and current trends of dental implant surfaces. , 2009, Journal of biomedical materials research. Part B, Applied biomaterials.

[15]  Lyndon F Cooper,et al.  Advancing dental implant surface technology--from micron- to nanotopography. , 2008, Biomaterials.

[16]  H. Kim,et al.  Hydrothermal synthesis of titanium dioxides from peroxotitanate solution using different amine group-containing organics and their photocatalytic activity , 2007 .

[17]  Haiyang Li,et al.  Fracture toughness and adhesion of thermally grown titanium oxide on medical grade pure titanium , 2007 .

[18]  J. Banfield,et al.  Phase Stability and Transformation in Titania Nanoparticles in Aqueous Solutions Dominated by Surface Energy , 2007 .

[19]  L. Scheideler,et al.  Enhancing surface free energy and hydrophilicity through chemical modification of microstructured titanium implant surfaces. , 2006, Journal of biomedical materials research. Part A.

[20]  F Rupp,et al.  High surface energy enhances cell response to titanium substrate microstructure. , 2005, Journal of biomedical materials research. Part A.

[21]  Angel Díaz-Ortiz,et al.  Microwaves in organic synthesis. Thermal and non-thermal microwave effects. , 2005, Chemical Society reviews.

[22]  A. Hiroki,et al.  Decomposition of hydrogen peroxide at water-ceramic oxide interfaces. , 2005, The journal of physical chemistry. B.

[23]  Ulrich S. Schubert,et al.  Microwave-Assisted Polymer Synthesis: State-of-the-Art and Future Perspectives , 2004 .

[24]  Jin-Ming Wu Low-temperature preparation of titania nanorods through direct oxidation of titanium with hydrogen peroxide , 2004 .

[25]  David L. Cochran,et al.  Osteoblasts generate an osteogenic microenvironment when grown on surfaces with rough microtopographies. , 2003, European cells & materials.

[26]  パーシバル シンプソン,ジェイムズ,et al.  Surface modification implant , 2003 .

[27]  Jing Sun,et al.  pH Effect on Titania-Phase Transformation of Precipitates from Titanium Tetrachloride Solutions , 2002 .

[28]  L. Nolte,et al.  Interface shear strength of titanium implants with a sandblasted and acid-etched surface: a biomechanical study in the maxilla of miniature pigs. , 1999, Journal of biomedical materials research.

[29]  S. Steinemann Titanium--the material of choice? , 1998, Periodontology 2000.

[30]  C. Ouchi,et al.  Effects of ultra-high purification and addition of interstitial elements on properties of pure titanium and titanium alloy , 1998 .

[31]  L. Qi,et al.  Hydrothermal Preparation of Uniform Nanosize Rutile and Anatase Particles. , 1995 .

[32]  Q. H. Li,et al.  Microwave-hydrothermal synthesis of ceramic powders , 1992 .

[33]  G. Welsch,et al.  Effects of oxygen and heat treatment on the mechanical properties of alpha and beta titanium alloys , 1988 .

[34]  A. Matthews The crystallization of anatase and rutile from amorphous titanium dioxide under hydrothermal conditions , 1976 .

[35]  J. Schrooten,et al.  Staphylococcal biofilm growth on smooth and porous titanium coatings for biomedical applications. , 2014, Journal of biomedical materials research. Part A.

[36]  T. Kitashima,et al.  Numerical Analysis of Oxygen Transport in Alpha Titanium during Isothermal Oxidation , 2013 .

[37]  M. Kakihana,et al.  Microwave-Assisted Hydrothermal Synthesis of Brookite Nanoparticles from a Water-Soluble Titanium Complex and Their Photocatalytic Activity , 2007 .

[38]  A. Zaban,et al.  Nanosize rutile titania particle synthesis viaa hydrothermal method without mineralizers , 2000 .

[39]  Y. Qian,et al.  Preparation of ultrafine powders of TiO2 by hydrothermal H2O2 oxidation starting from metallic Ti , 1993 .

[40]  R. Gedye,et al.  The use of microwave ovens for rapid organic synthesis , 1986 .

[41]  P. Siekevitz,et al.  Investigation on the Oxidation Mechanism of Titanium. , 1958 .