Improvement in the morphology of micro-arc oxidised titanium surfaces: A new process to increase osteoblast response

Abstract

This study describes a method for combining sandblast-acid etching and micro-arc oxidation to optimise titanium implant surfaces, and examines the effects of these surfaces on osteoblast response. Titanium discs were grouped as: micro-arc oxidised (MAO), sandblast-acid etched and micro-arc oxidised (MAO-SA), micro-arc oxidised and heated (MAO-HT), and untreated smooth surface. The combination of sandblast-acid etching and micro-arc oxidation in the MAO-SA group created an average surface roughness of 2.02 ± 0.15 μm compared to the untreated machined surface of 0.31 ± 0.06 μm. Scanning electron microscopy observations of the surface structures showed that the irregularly ordered valleys created by sandblast-acid etching remained after micro-arc oxidation and that micropores had also formed. These microstructures provided a better place for osteoblasts to spread compared with the other surfaces. In addition, our results indicated that adherent osteoblasts expressed greater alkaline phosphatase (ALP) activity and osteocalcin (OC) production on MAO-SA surfaces compared with MAO, MAO-HT, and smooth surfaces. The overall results clearly indicate that combining sandblast-acid etching and micro-arc oxidation techniques improves the titanium surface morphology and increases the roughness, which provides an optimal surface for cell differentiation and osseointegration.