The establishment of animal model with coronary microembolization suitable for long-term observation by using endovascular rnicrocatheter technique
- VernacularTitle:介入法建立长期可随访冠状动脉微栓塞动物模型
- Author:
Qingyong ZHANG
;
Zhihua WANG
;
Xiaobo LI
;
Lianhua YIN
;
Jingbo LI
;
Meng WEI
- Publication Type:Journal Article
- Keywords:
microembolization;
endovascular technique;
animal model;
mini-swine
- From:
Journal of Interventional Radiology
2009;18(12):920-922
- CountryChina
- Language:Chinese
-
Abstract:
Objective By using percutaneous endovascular microcatheter technique to establish an animal model of coronary microembolization in mini-swine which is suitable for long-term observation.Methods Coronary microembolization was established in 10 mini-swine by infusing 15 × 10~4 microspheres (φ45μm) selectively into the left anterior descending artery (n = 10). Coronary flow reserve (CFR) was measured by Doppler wire and left ventricular eject fraction (EF) was assessed by echocardiography.Hematoxylin and eosin (HE) staining and nitroblue tetrazolium (NBT) dye were used to demonstrate the presence of microembolization after the procedure of coronary microembolization. The ultra-structures of cardiomyocyte were observed by transmission electron microscopy (TEM). Before sacrifice, the CFR measurement and coronary angiography were performed again in survival animals. Results The coronary microvascular integrity (CFR < 2.0) and left ventricular function (EF < 50% ) were damaged by coronary microembolization. One month after the procedure, all the 10 animals survived and were able to receive the angiography and CFR measurement again. HE staining and NBT dye could demonstrate the presence of microembolization. The edema and fibrosis of cardiomyocytes could be revealed with TEM. Conclusion The animal model of coronary microembolization can be established in mini-swine by using percutaneous endovascular microcatheter technique. The model is suitable for long-term observation, the preparation is technically-simple and minimally-invasive with very low mortality. Therefore, this kind of animal model is an ideal experimental form for studying the mechanism of coronary microembolization.
