Litcius/Paper detail

Engineering Metallic Implants with Self-Catalytic Degradable Bionanozyme Coating and Ion-Releasing Biointerface for Bioadaptive Anti-infective and Osteogenic Functionality

Weidong Li, Min Wen, Jiahui Hao, Yuling Zhang, Liyuan Sheng, Zhaojun Jia

2026ACS Applied Materials & Interfaces9 citationsDOI

Abstract

Implant-associated infections and poor osseointegration remain major challenges for Ti-based indwelling devices. To address these, we developed a multifunctional implant coating integrating photothermal-enhanced nanobioenzymatic catalysis with degradable release of bioactive components for staged antibacterial and osteogenic functions. The coating consisted of a Ca 2+ /Cu 2+ -doped micro/nanostructured titanate layer overlaid with a bionanozyme (HMG)-loaded, alendronate-modified hyaluronic acid (AHA) matrix, anchored via Ca 2+ –alendronate chelation. The bionanozyme HMG comprised glucose oxidase (GOx) encapsulated in hollow MnO 2 nanozymes and stabilized by tannic acid (TA). Upon infection, GOx-generated H 2 O 2 (from glucose oxidation) was converted into •OH via a TA-mediated Cu + -based Fenton-like reaction, enhanced by MnO 2 ’s photothermal activity. MnO 2 and TA also acted as potential ROS scavengers to alleviate inflammation post infection resolution. Notably, bacteria-triggered top-layer degradation would cause interface self-renewal, releasing HMG for distal antibacterial action and exposing the micro/nanostructured titanate underlayer to favor cell adhesion and sustained Cu 2+ /Ca 2+ release for osteogenesis. Systemic in vitro / ovo / vivo studies confirmed the multifaceted antibacterial killing, accelerated mineralization, and improved tissue healing/biointegration, alongside favorable biological compatibility. This work presents a nanobioenzymatic coating strategy with multilayer design, aimed at catalytically active implants with self-adaptive interfaces that can accommodate evolving anti-infective and tissue-regenerative demands.

Topics & Concepts

BiointerfaceMaterials scienceCoatingOsseointegrationHyaluronic acidNanotechnologyTannic acidPhotothermal therapyNanoporousAdhesionGlucose oxidaseBiomedical engineeringTitaniumMetalBiocompatible materialDegradation (telecommunications)Surface modificationLayer (electronics)CatalysisScaffoldConformal coatingCell adhesionChemical engineeringSubstrate (aquarium)ImplantTissue engineeringTribocorrosionHalloysiteBioactive glassHydrophilizationBiocompatibilityTitanium alloyAdvanced Nanomaterials in CatalysisNanoplatforms for cancer theranosticsBone Tissue Engineering Materials
Engineering Metallic Implants with Self-Catalytic Degradable Bionanozyme Coating and Ion-Releasing Biointerface for Bioadaptive Anti-infective and Osteogenic Functionality | Litcius