目的:探讨大鼠角膜层间植入微粒体诱导新生血管模型的制作技巧和特点。方法:9只SD大鼠手术显微镜下做角膜基质微囊袋并植入含有VEGF的缓释微粒体。术后1、3、5、7d采用裂隙灯显微镜观察角膜新生血管的生长情况。结果:大鼠角膜微囊袋内植入微粒体后1d仅见角膜缘血管网充血扩张,未见新生血管生长;3d可见毛刷状新生血管自角膜缘伸入角膜,面积为(2.23±0.59)mm2;5d新生血管垂直于角膜缘向微粒体方向束状延伸,并达到微粒体下缘部位,面积为(6.81±1.35)mm2;7d新生血管继续向前生长,达到并超过微粒体下缘,部分新生血管顶端互相吻合成袢状,面积为(8.92±1.79)mm2。其中,5d和7d新生血管面积比较无显著性差异。所有术眼均未见前房积血、角膜溃疡、微粒体脱出等并发症。结论:大鼠角膜层间植入微粒体诱导的新生血管生长稳定、无并发症、适用于定量研究。 Objective: To explore the techniques and characteristics of rat corneal interstitial microsomal-induced angiogenesis model. Methods: Nine SD rats underwent corneal microencapsulation and implantation of sustained-release microsomes containing VEGF. The growth of corneal neovascularization was observed with slit lamp microscope at 1, 3, 5 and 7 days after operation. Results: Only the corneal vascular network was inflated and expanded on the first day after implantation of microsomes in the cornea of ​​the rat cornea. No angiogenesis was seen on the cornea of ​​the cornea at 3 days. The corneal neovascularization reached the cornea from the corneal margin on 3d, with an area of ​​(2.23 ± 0.59) mm2; 5d neovascularization extends perpendicularly to the direction of corneal microsomes and reaches the lower edge of microsome with an area of ​​(6.81 ± 1.35) mm2; on the 7th day, angiogenesis continues to grow forward and beyond the lower edge of microsome, Some of the neovascular apical anastomosis 成 shaped, with an area of ​​(8.92 ± 1.79) mm2. Among them, there was no significant difference in the area of ​​neovascularization between 5d and 7d. All eyes were no anterior chamber hemorrhage, corneal ulcer, microsomal prolapse and other complications. Conclusion: Microscopically implanted corneal interstitial microsphere-induced neovascularization is stable and has no complications and is suitable for quantitative study.