生物相容性
化学
细胞内
透明质酸
涂层
镁
腐蚀
巨噬细胞极化
渗透(战争)
生物医学工程
生物物理学
基质(水族馆)
植入
镁合金
材料科学
炎症
骨愈合
表面改性
巨噬细胞
胶粘剂
人造骨
生物相容性材料
激进的
作者
Yuanyuan Wu,Zhe Cai,Yuling Zhang,Yufeng Zheng,L. Z. Liao,Zhaojun Jia
标识
DOI:10.1016/j.bioactmat.2025.12.018
摘要
Infected bone defects (e.g., osteomyelitis) present a complex clinical challenge characterized by persistent biofilms, intracellular pathogens, and compromised bone regeneration. We hypothesized that a bioadaptive magnesium implant with sequential coating/substrate degradation could render staged anti-infective and pro-regenerative therapy. To this end, we engineered TNE@AHAC implants consisting of a Mg-Zn alloy substrate functionalized with a multilayered coating: a corrosion-resistant MgF2 underlayer, a polydopamine/polyethyleneimine adhesive interlayer, and an infection-responsive aldehyde-modified hyaluronic acid (AHA) hydrogel toplayer embedded with microbe-targeting Fe3O4 nanozymes (TNE). The implants demonstrated improved hydrophilicity and corrosion resistance and time-sequenced coating/substrate degradation. In infectious microenvironments, the TNE-embedded coating degraded preferentially, releasing nanozymes that catalytically generated bactericidal hydroxyl radicals to eradicate planktonic bacteria, intracellular pathogens, and biofilms, while stimulating M1 macrophage polarization for enhanced immunobactericidal activity. Subsequently, controlled substrate corrosion released bioactive ions (Mg2+, Zn2+) and H2, which elicited M2 macrophage polarization and osteodifferentiation, while allowing favorable biocompatibility in vitro, in ovo, and in vivo. In a Staphylococcus aureus-infected rat femoral model, TNE@AHAC effectively eliminated infection, mitigated inflammation and osteolysis, and enhanced osteoregeneration/osseointegration. This work establishes a sequential degradation-driven bioadaptive paradigm for implant-mediated microenvironment remodeling in infectious bone defects.
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