Infection-prevention on Ti implants by controlled drug release from folic acid/ZnO quantum dots sealed titania nanotubes.

Bacterial infections and related complications are predominantly responsible for the failure of artificial biomaterials assisted tissue regeneration in clinic. In this work, a hybrid surface system is applied to prolong the drug release duration from dug-loaded titania nanotubes and thus to prevent Ti implants-associated bacterial infections. This feature is endowed by conjugating folic acid (FA) onto the surface of ZnO quantum dots (QDs)-NH via an amidation reaction. Titania nanotubes (TNTs) loaded with vancomycin (Van) are capped by these FA functionalized ZnO (ZnO-FA) QDs that keep stable in normal physiological environments but dissolves to Zn in the mildly acidic environment after bacterial infections as validated by the drug release profile. The antibacterial ratio of TNTs-Van@ZnO-FA QDs against Staphylococcus aureus is enhanced from 60.8% to 98.8%while this value is only increased from 85.2% to 95.1% for TNTs-Van once the pH value of the environment is decreased from 7.4 to 5.5. This is due to the synergistic effects of Van and Zn because the gradual dissolution of ZnO-FA caps on TNTs with the decrease of pH value can induce the acceleration of both Van and Zn release. In addition, this TNTs-Van@ZnO-FA system also exhibits excellent biocompatibility because of the folic acid and sustained release of Zn ions. Hence, this surface system can be potentially used as a promising bioplatform on Ti-based metallic implants to prevent bacterial infection with a long-lasting effect.