|
|||||
|
|
Titanium hydride and hydrogen concentration in acid‐etched commercially pure titanium and titanium alloy implants: a comparative analysis of five implant systems |
|
| Authors: | S. Szmukler‐Moncler M. Bischof R. Nedir M. Ermrich |
| Affiliation: | 1. Department of Stomatology & Maxillo‐Facial Surgery, University of Paris, Paris, France;2. Department of Odontology, Section of Implantology and Oral Rehabilitation, Galeazzi Orthopeadic Institute, University of Milano, Milano, Italy;3. Ardentis Clinique Dentaire Vevey, Swiss Dental Clinics Group, 3 rue du Collège, Vevey, Switzerland;4. Department of Stomatology and Oral Surgery, School of Dental Medicine, University of Geneva, Geneva, Switzerland;5. X‐Ray Laboratory Dr Ermrich, Reinheim/Odw, Germany |
| Abstract: | Objectives: Acid etching is a popular method to texture the surface of dental implants. During etching, the titanium oxide protective layer is dissolved and small native hydrogen ions diffuse into the unprotected implant surface. They enrich the implant surface with hydrogen and precipitate into titanium hydride (TiH). The aim of this study was to measure the concentration of TiH at the implant surface and the total concentration of Hydrogen at five commercially available implant systems, made of either commercially pure (cp) titanium or titanium alloy. Material and methods: X‐Ray diffraction (XRD) was conducted on each implant system to determine the compounds present at the implant surface. Following a TiH2/Ti calibration curve, the concentration of TiH was determined. Concentration of hydrogen in the implants was measured by the inert gas fusion thermal conductivity/infrared detection method. Results: XRD data showed that TiH was present on all cp titanium implants but not on the alloyed implants. TiH concentration varied between 5% and 37%. Hydrogen concentration varied between 43 and 108 ppm, no difference in uptake was found between the cp titanium and alloyed implants. Low solubility of hydrogen in α‐titanium is responsible for precipitation into TiH. Stronger etching conditions led to higher concentration of TiH2‐x. Conclusion: High solubility of hydrogen in the β‐phase of the alloy is preventing hydrogen from precipitating into TiH. All implants, even those lacking TiH at the surface, were enriched with hydrogen. In all implants, hydrogen concentration was within the normative limit of 130 ppm. To cite this article: Szmukler‐Moncler S, Bischof M, Nedir R, Ermrich M. Titanium hydride and hydrogen concentration in acid‐etched commercially pure titanium and titanium alloy implants: a comparative analysis of five implant systems. Clin. Oral Impl. Res. 21 , 2010; 944–950. doi: 10.1111/j.1600‐0501.2009.01938.x |
| Keywords: | acid etching hydrogen concentration osseotite sandblasting SLA surface treatment titanium alloy titanium hydride X‐ray diffraction |