再狭窄
原位
新生内膜
血管平滑肌
内膜增生
细胞外基质
串扰
材料科学
新生内膜增生
细胞生物学
内科学
重编程
钙化
医学
癌症研究
组织工程
细胞外
间充质干细胞
表型
增生
细胞
移植
心脏病学
内膜
内皮干细胞
狭窄
炎症
抗体
血管舒张
表型转换
分泌物
作者
Shunqi Hu,Shifeng Ling,Fubang Liang,Y. Pan,Yì Wáng,Wenjie Bao,Jiameng Zhu,Fang Wang,Yawei Du,Wenguo Cui,M Z Yin
标识
DOI:10.1002/adma.202522615
摘要
Small-diameter vascular grafts (SDVGs) often fail due to restenosis driven by endothelial cell (EC)-derived PDGF-BB, which shifts vascular smooth muscle cells (VSMCs) toward a synthetic phenotype. Despite mechanistic insights, durable, localized, and cell-specific control of this crosstalk remains elusive. Here, we developed a circRNA-based in situ antibody engineering strategy to functionalize SDVGs, reprogramming ECs into local biofactories that secrete Olaratumab (Ola), a PDGFR-α-neutralizing antibody, to precisely modulate EC-VSMC signaling. In vitro, in situ Ola engineering reversed PDGF-BB-induced VSMC phenotypic switching, markedly suppressing migration, invasion, and excessive extracellular matrix deposition by attenuating MAPK and PI3K-AKT pathways. In the rat model, this approach enabled sustained local antibody secretion for up to 24 days, accelerated endothelialization, and significantly reduced neointimal hyperplasia and graft calcification over 6 months, thereby lowering the risk of SDVG restenosis. CircRNA-based in situ antibody engineering offers a powerful modality to modulate intercellular crosstalk and sustain the VSMC contractile phenotype.
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