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简要报告:输注的干细胞外渗机制。

Brief report: Mechanism of extravasation of infused stem cells.

机构信息

Cedars-Sinai Heart Institute, Los Angeles, California 90048, USA.

出版信息

Stem Cells. 2012 Dec;30(12):2835-42. doi: 10.1002/stem.1184.

DOI:10.1002/stem.1184
PMID:23135922
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3508398/
Abstract

In order for bloodborne stem cells to be effective in tissue regeneration, cells must cross vessel walls and enter the parenchyma. Although such transmigration does occur, the mechanism remains elusive. Leukocytes invade tissue by diapedesis; stem cells are commonly assumed to do likewise, but evidence is lacking. Cardiac-derived regenerative cells and multicellular cardiospheres (CSPs) were infused into the coronary vessels of rat hearts. Serial histology revealed a novel mechanism of cell transmigration, "active vascular expulsion," which underlies the extravasation of infused cells and cell aggregates. In this mechanism, the vascular barrier undergoes extensive remodeling, while the cells themselves are relatively passive. The mechanism was confirmed in vivo by serial intravital microscopy of CSP extravasation in a dorsal skin flap model. Integrins and matrix metalloproteinases play critical roles in active vascular expulsion. In vitro models revealed that active vascular expulsion is generalizable to other stem cell types and to breast cancer cells. Recognition of active vascular expulsion as a mechanism for transvascular cell migration opens new opportunities to enhance the efficacy of vascularly delivered cell therapy.

摘要

为了使血液中的干细胞在组织再生中有效,细胞必须穿过血管壁并进入实质组织。尽管这种迁移确实会发生,但机制仍不清楚。白细胞通过穿胞作用入侵组织;人们通常认为干细胞也是如此,但缺乏证据。心脏来源的再生细胞和多细胞心肌球体(CSP)被注入大鼠心脏的冠状动脉。连续组织学显示了一种新的细胞迁移机制,“主动血管排斥”,这是注入细胞和细胞聚集体外渗的基础。在这种机制中,血管屏障经历了广泛的重塑,而细胞本身相对被动。该机制在活体中通过在背部皮肤瓣模型中对 CSP 外渗的连续活体显微镜检查得到了证实。整合素和基质金属蛋白酶在主动血管排斥中发挥关键作用。体外模型表明,主动血管排斥可推广到其他干细胞类型和乳腺癌细胞。将主动血管排斥识别为跨血管细胞迁移的一种机制,为增强血管内递送细胞治疗的效果开辟了新的机会。

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