材料科学
植入
生物医学工程
骨愈合
应力屏蔽
刚度
脚手架
复合材料
机械强度
机械负荷
骨整合
皮质骨
弹性模量
压电
联轴节(管道)
骨生长
陶瓷
骨组织
模数
生物材料
压力(语言学)
纳米陶瓷
抗压强度
纳米压痕
骨折
承重
机械转化
作者
Jiaming Liang,Chaonan Jin,Fang‐Zhou Yao,Wei Sun,Bo Li,Runzhi Xia,Jiahe Li,Yong Yu,Ke Wang,Fan Wang,Jing Sun,Yawei Liu,Hongjie Zhang,Kai Liu
标识
DOI:10.1002/adfm.202523587
摘要
Abstract The repair of weight‐bearing bone defects is critically limited by the mechanical mismatch between implants and native bone. While excessive implant stiffness causes stress shielding and inhibits bone formation, insufficient stiffness compromises structural stability and osseointegration. To address this, a dual‐network, piezoelectric nanoceramic‐reinforced implant is developed that replicates the mechanical properties of natural bone while actively enhancing osteogenesis for irregular defect repair. The implant combines a fast‐curing polymer network and a protein‐based network, strategically reinforced with high‐modulus piezoelectric nanoparticles. Through optimized covalent cross‐linking, physical entanglement, and nanoceramic dispersion, the system achieves synergistic mechanical and osteogenic performance—matching cortical bone in compressive strength (≈140 MPa) and elastic modulus (≈3.8 GPa). Under physiological loading, the embedded nanoceramics generate osteogenic bioelectric signals, further stimulating bone remodeling. In a tibial fracture model, the implant provides robust mechanical support and biological activity, enabling near‐complete functional gait recovery. This study demonstrates a mechano‐bioelectric dual‐regulation strategy to advance weight‐bearing bone regeneration.
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