Vancomycin-encapsulated hydrogel loaded microarc-oxidized 3D-printed porous Ti6Al4V implant for infected bone defects: Reconstruction, anti-infection, and osseointegration
Teng Zhang, Wenhao Zhou, Wanliang Yang, Jingwei Bi, Hao Li, Xianlei Gao, Baoliang Zhang, Guidong Shi, Ka Li, Zhijian Wei, Xin Pan, Shiqing Feng
Abstract
Infected bone defect is a formidable clinical challenge. Conventional approaches to prevention and treatment for infected bone defects are unsatisfactory. The key elements of the treatment are bone defect reconstruction, anti-infection, and osteogenesis. Conventional treatment methods remain unsatisfactory owing to the absence of composite integrating materials with anti-infective, and osteogenic activities as well as proper mechanical strength at the same time. In this study, we fabricated a vancomycin-encapsulated hydrogel with bacteria-responsive release properties combined with a shaved porous (submicron-micron) three-dimensional-printed Ti6Al4V implant. The implant surface, modified with submicron-sized pores through microarc oxidation (MAO), showed enhanced osteogenic activity and integrated well with the hydrogel drug release system, enabling sustained vancomycin release. In vitro experiments underscored the commendable antibacterial ability, biosafety, and osteoinductive potential. Effective antibacterial and osteogenic abilities of the implant were further demonstrated in vivo in infected rabbit bone defects. These results showed that the vancomycin-encapsulated hydrogel-loaded microarc-oxidized 3D-printed porous Ti6Al4V can repair the infected bone defects with satisfactory anti-infection and osseointegration effects. Summary diagram of the preparation and surgical implantation of the MAO/hydrogel composite porous Ti6Al4V scaffolds designed in this study. MAO, microarc oxidation. • The TS-M/H/V can repair infected bone defects with satisfactory anti-infection and osseointegration effects as well as perfect mechanical properties. • The TS-M/H/V can circumvent the drawbacks of traditional treatments and be assembly used intraoperatively, which is convenient for orthopaedic clinical application. • We can precisely control the vancomycin release by regulating the degradation period of the hydrogel to realize accurate anti-bacteria.