人脑
纤维化
神经血管束
炎症
医学
神经科学
疾病
病态的
病理
神经免疫学
动脉瘤
人类疾病
血管平滑肌
血管疾病
电池类型
细胞
创伤性脑损伤
发病机制
生物
小胶质细胞
神经影像学
平滑肌
人体病理学
细胞体
血管周围间隙
内皮
神经退行性变
髓系细胞
神经炎症
脆弱性(计算)
作者
Jerry C. Wang,Chang N. Kim,Shubhang Bhalla,Lea Scherschinski,Adnan Gopinadhan,Santhosh Arul,Damian Sanchez,Tyler D. Schriber,Amanda C. M. Apolonio,Belda Gülsuyu,Muhammet M. Öztürk,John P. Andrews,Joseph Kim,Behnam Rezai Jahromi,Mika Niemelä,Martin Lehečka,Aunoy Poddar,Thomas Wälchli,Joshua S. Catapano,R Sen
标识
DOI:10.1038/s41593-026-02326-9
摘要
Brain aneurysms are a cerebrovascular disease that results in a severe type of stroke. The cell-specific molecular pathology underlying their formation and rupture is unknown. Here we profile 227,663 neurovascular cells, including 52,946 aneurysmal cells, from a total of 14 adult human brain aneurysms and 11 control vessels. Our atlas of human brain aneurysms, as well as cell-resolution spatial transcriptomics, revealed that pathological cerebrovascular remodeling occurs with the loss of structurally supportive smooth muscle cells and the emergence of activated perivascular fibroblasts, which re-populate the vascular wall and express multiple genes linked to aneurysm risk. Fibrotic changes coincide with fibroblast-myeloid cell signaling pathways and an influx of specialized macrophages that are rarely detected in non-aneurysmal cerebrovasculature and that express destabilizing vascular cell programs. Thus, we reveal an unrecognized interplay between cerebrovascular fibrosis and myeloid inflammation during disease progression, substantially advancing our understanding of the cellular drivers and mechanisms underlying this devastating cerebrovascular disease that will inform translational development.
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