鹿角
去细胞化
间质细胞
细胞生物学
骨髓
再生(生物学)
材料科学
生物
解剖
病理
医学
细胞外基质
免疫学
生态学
作者
Shengyou Li,Yujie Yang,Beibei Yu,Xueli Gao,Xue Gao,Shihao Nie,Tao Qin,Yiming Hao,Lingli Guo,Haining Wu,Teng Ma,Yi Zheng,Dan Geng,Jianbo Gao,Borui Xue,Yongfeng Zhang,Shijie Yang,Yitao Wei,Bing Xia,Zhuojing Luo,Qiang Qiu,Jinghui Huang
标识
DOI:10.1002/adma.202411571
摘要
Abstract Adult mammals are unable to regenerate bulky bone tissues, making large bone defects clinically challenging. Deer antler represents an exception to this rule, exhibiting the fastest bony growth in mammals, offering a unique opportunity to explore novel strategies for rapid bone regeneration. Here, a bone graft exploiting the biochemical, biophysical, and structural characteristics of antlers is constructed. It is decellularized antler cancellous bone (antler‐DCB) to obtain a bone scaffold. Then, an antler‐based bone graft is constructed by integrating antler‐DCB with antler‐derived biological signals, delivered by extracellular vesicles (EVs) from antler blastema progenitor cells (ABPCs), a novel stem cells responsible for antlerogenesis is discovered. The antler‐based bone graft transformed bone marrow stromal cells into cells with an ABPC‐like phenotype and transcriptomic signature. In vivo, the antler‐based graft triggered rapid bone formation in a rat model, with doubled volume of newly formed bones than commercial DCBs. In addition, the antler‐based graft orchestrated a coordinated process of vascularization, neurogenesis, and immunomodulation during osteogenesis, partially imitating early antlerogenesis. These findings provide practical insights to develop a therapeutic intervention for treating severe bone defects.
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