Construction of Multifunctional Zinc Ion Sustained-Release Biocoating on the Surface of Carbon Fiber Reinforced Polyetheretherketone with Enhanced Anti-inflammatory Activity, Angiogenesis, and Osteogenesis.

Abstract

Current treatments of carbon fiber-reinforced polyetheretherketone (CFRPEEK) as orthopedic implants remain unsatisfactory due to the bioinert surface. The multifunctionalization of CFRPEEK, which endows it with regulating the immune inflammatory response, promoting angiogenesis, and accelerating osseointegration, is critical to the intricate bone healing process. Herein, a multifunctional zinc ion sustained-release biocoating, consisting of a carboxylated graphene oxide, zinc ion, and chitosan layer, covalently grafts on the surface of amino CFRPEEK (CP/GC@Zn/CS) to coordinate with the osseointegration process. The release behavior of zinc ions theoretically conforms to the different demands in the three stages of osseointegration, including the burst release of zinc ions in the early stage (7.27 μM, immunomodulation), continuous release in the middle stage (11.02 μM, angiogenesis), and slow release in the late stage (13.82 μM, osseointegration). In vitro assessments indicate that the multifunctional zinc ion sustained-release biocoating can remarkably regulate the immune inflammatory response, decrease the oxidative stress level, and promote angiogenesis and osteogenic differentiation. The rabbit tibial bone defect model further confirms that, compared to the unmodified group, the bone trabecular thickness of the CP/GC@Zn/CS group increases 1.32-fold, and the maximum push-out force improves 2.05-fold. In this study, a multifunctional zinc ion sustained-release biocoating constructed on the surface of CFRPEEK that conforms to the requirements of different osseointegration stages can be an attractive strategy for the clinical application of inert implants.