Anodic thin films on titanium used as masks for surface micropatterning of biomedical devices

Ceramic oxide films like TiO2 are used on medical implants to improve biocompatibility and corrosion behavior. Along with the chemical composition, the topography of implants with surface features in the tens of microns range is known to promote osteointegration. In this work, the prospective of anodically grown TiO2 thin films as mask material for subsequent electrochemical micro/nanopatterning of medical implant surfaces sensitized by He-ion beam and YAG-laser irradiation is investigated. ochemical impedance spectroscopy was used to characterize resistance and capacitance of oxide films anodized under various conditions. The resistance obtained by fitting to an appropriate equivalent circuit was compared to the film stability in electrochemical pitting experiments. Film thickness, composition and microstructure were analyzed by glow discharge optical emission spectroscopy (GDOES), X-ray photoelectron spectroscopy, scanning and transmission electron microscopy and Raman spectroscopy. reasing film resistance of the porous part of the oxide was found to correlate to increasing pitting resistance. GDOES revealed a low carbon and sulfur concentration in the film as well as an accumulation of hydrogen at the oxide/metal interface. Based on the performance in pitting tests, suitable anatase TiO2 films were used for laser micropatterning, and thinner mainly amorphous films were used for He-ion beam micropatterning experiments. YAG-laser treatment led to preferential dissolution of the irradiated sites during the subsequent etching step. Both preferential and reduced dissolution was observed in case of He-ion implantation. Potential physico-chemical mechanisms for observed micropatterning effects are discussed.