This study investigates the utilization of poly(vinyl
alcohol)
(PVA)/gelatin hydrogel films cross-linked with glutaraldehyde as a
novel material to coat the surface of vancomycin-loaded titania nanotubes
(TNTs), with a focus on enhancing biocompatibility and achieving controlled
vancomycin release. Hydrogel films have emerged as promising candidates
in tissue engineering and drug-delivery systems due to their versatile
properties. The development of these hydrogel films involved varying
the proportions of PVA, gelatin, and glutaraldehyde to achieve the
desired properties, including the gel fraction, swelling behavior,
biocompatibility, and biodegradation. Among the formulations tested,
the hydrogel with a PVA-to-gelatin ratio of 25:75 and 0.2% glutaraldehyde
was selected to coat vancomycin-loaded TNTs. The coated TNTs demonstrated
slower release of vancomycin compared with the uncoated TNTs. In addition,
the coated TNTs demonstrated the ability to promote osteogenesis,
as evidenced by increased alkaline phosphatase activity and calcium
accumulation. The vancomycin-loaded TNTs coated with hydrogel film
demonstrated effectiveness against both E. coli and S. aureus. These findings highlight the potential benefits
and therapeutic applications of using hydrogel films to coat implant
materials, offering efficient drug delivery and controlled release.
This study contributes valuable insights into the development of alternative
materials for medical applications, thereby advancing the field of
biomaterials and drug delivery systems.