Department of Clinical and Experimental Medicine, Faculty of Health Sciences, Linköping University, Linköping, Sweden.
Invest Ophthalmol Vis Sci. 2011 May 10;52(6):3060-8. doi: 10.1167/iovs.10-6101.
To elucidate the temporal sequence of events leading to new capillary sprouting in inflammatory corneal angiogenesis.
Angiogenesis was induced by corneal suture placement in Wistar rats. The inflamed region was examined by time-lapse in vivo confocal microscopy for up to 7 days. At 6 and 12 hours and 1, 2, 4, and 7 days, corneas were excised for flat mount immunofluorescence with primary antibodies for CD31, CD34, CD45, CD11b, CD11c, Ki-M2R, NG2, and α-SMA. From days 0 to 4, the in vivo extravasation and expansion characteristics of single limbal vessels were quantified.
Starting hours after induction and peaking at day 1, CD45(+)CD11b(+) myeloid cells extravasated from limbal vessels and formed endothelium-free tunnels within the stroma en route to the inflammatory stimulus. Limbal vessel diameter tripled on days 2 to 3 as vascular buds emerged and transformed into perfused capillary sprouts less than 1 day later. A subset of spindle-shaped CD11b(+) myeloid-lineage cells, but not dendritic cells or mature macrophages, appeared to directly facilitate further capillary sprout growth. These cells incorporated into vascular endothelium near the sprout tip, co-expressing endothelial marker CD31. Sprouts had perfusion characteristics distinct from feeder vessels and many sprout tips were open-ended.
Time-lapse in vivo corneal confocal microscopy can be used to track a temporal sequence of events in corneal angiogenesis. The technique has revealed potential roles for myeloid cells in promoting vessel sprouting in an inflammatory corneal setting.
阐明导致炎症性角膜血管生成中新毛细血管发芽的时间顺序事件。
通过角膜缝线植入在 Wistar 大鼠中诱导血管生成。通过活体共聚焦显微镜在长达 7 天的时间内对炎症区域进行延时观察。在 6 小时和 12 小时以及 1 天、2 天、4 天和 7 天,切除角膜进行 CD31、CD34、CD45、CD11b、CD11c、Ki-M2R、NG2 和α-SMA 的免疫荧光平板标记。从第 0 天到第 4 天,量化了单个缘血管的活体渗出和扩张特征。
诱导后数小时开始,峰值出现在第 1 天,CD45(+)CD11b(+)髓样细胞从缘血管渗出,并在通向炎症刺激物的过程中在基质中形成无内皮的隧道。缘血管直径在第 2 天至第 3 天增加了两倍,因为血管芽出现并在不到 1 天后转化为灌注毛细血管芽。一小部分梭形 CD11b(+)髓样细胞,但不是树突状细胞或成熟巨噬细胞,似乎直接促进了进一步的毛细血管芽生长。这些细胞在芽尖附近并入血管内皮,共表达内皮标志物 CD31。芽具有与饲养血管不同的灌注特征,并且许多芽尖是开口的。
活体角膜共聚焦显微镜延时观察可用于跟踪角膜血管生成中的时间顺序事件。该技术揭示了髓样细胞在炎症性角膜环境中促进血管发芽的潜在作用。
