Aims: A serious problem in orthopedic surgery is the development of infections. The realization of antibacterial and biocompatible/bioactive surfaces represents a challenge. In this study antibacterial behavior has been conferred to surfaces of glasses and glass-caramics, with different degrees of bioactivity, by the introduction of silver through ion exchange.

Methods: Materials have been studied both in bulk form, and as coatings. All samples have been analyzed by means of XRD, SEM and EDS before and after the treatment. Coatings’ roughness, porosity and adhesion resistance have been also analyzed. In vitro reactivity and silver release were carried out soaking samples in SBF. Samples have been analyzed by means of SEM/ EDS and XRD; silver has been quantified in solution by GFAAS. Cellular tests have been performed in order to evaluate materials biocompatibility before and after the treatment. Antibacterial behavior has been tested against S.Aureus.

Results: Characterization analyses show that glassy or crystalline structure and morphology are maintained after the ion-exchange. As well the coating adhesion resistance is higher then the limit provided by ISO standard for hydroxyapatite coatings. GFAAS analysis determined that silver is gradually released in solution. Cellular tests demonstrate that biocompatibility is generally maintained after treatment but it is closely connected to the amount of silver released. Microbiological tests show antibacterial behavior for silver-doped samples.

Conclusions: Ion-exchange technique permits the introduction of controlled silver amount without modifying materials’ structural and morphological properties. Comparing cellular and microbiological tests it is possible to design process parameters to confer, antibacterial properties but not cytotoxic behavior.