水泥
生物医学工程
骨水泥
抗压强度
化学
多孔性
材料科学
体内
原位
骨矿物
骨移植
机械强度
吸水率
骨愈合
流变学
碳纤维
复合材料
钙
骨组织
生物相容性材料
作者
Xing Chen,Yifan Ma,Lingfei Zhao,Lingbin Che,Dianwen Song,Zihan Wu,Chang‐Sheng Liu,Yuan Yuan
标识
DOI:10.1002/advs.202512723
摘要
Abstract Injectable bone cements are recognized as ideal solution for bone augmentation due to their minimally invasive introduction strategy. However, current clinical formulations and composites, while demonstrating improvements in certain areas, often fail to comprehensively address challenges, including rheological injectability, mechanical stability, interconnected porosity, degradability, and bioactivity. To overcome limitations, a novel bone cement comprising linear polyhydroxy PEGylated poly(glycerol sebacate) (L‐PEGS) and calcium phosphate cement (CPC) is developed. The incorporation of L‐PEGS enhances injectability and reinforces the mechanical weakness of CPC, resulting in improvement in compressive strength (increased by 16.7 folds) and fatigue resistance (1000 cycles). Owing to linear polyhydroxy backbone, L‐PEGS initiates self‐reinforcing cross‐linking reaction synchronized with the hydration of CPC into hydroxyapatite. This hydration reinforcement is mediated by its abundant hydroxyl groups and high water absorption capacity, which accelerate hydration kinetics. Concurrently, the cross‐linking reaction generates in situ carbon dioxide, resulting in porous microarchitecture that facilitates hydration process, enhances cement degradability, and promotes nutrient exchange and new bone ingrowth. In vitro and vivo studies confirmed that L‐PEGS/CPC substantially enhances osteogenesis compared to clinical materials. Collectively, this injectable, hydration‐driven, and self‐reinforcing bone cement offers comprehensive solution to the challenges in current bone graft materials, holding promise for clinical bone repair.
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