冷冻固定血管内皮。

R C Wagner, S B Andrews
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引用次数: 6

摘要

冷冻固定是指通过从标本中快速去除热量来固定组织成分,使结构被嵌入并稳定在自然包埋介质中,即冷冻(无定形或微晶)组织水中。冷冻固定现在经常被用作传统固定方法的补充,特别是当细胞结构微妙或动态,并且可能由于化学固定剂的缓慢选择性作用而不准确地保存时。血管内皮细胞专门用于跨细胞运输和调节血液流动和成分。这些细胞的动态和不稳定的亚细胞组织,可能反映了这些功能特化,使它们成为冷冻固定的理想候选者。将几种不同类型的内皮细胞压在液氦冷却块上,在低于20开尔文的温度下直接冷冻。这些样品随后通过冷冻取代进行结构分析。详细的原理,设计和协议描述了冷冻和冷冻替代。冷冻动脉和静脉毛细血管(美洲鳗的rete mirabile)、髂静脉(兔)和培养的髂静脉内皮(人)的电子显微照片显示,内皮小泡的特征胞内膜系统的组织结构在质量上与化学固定内皮相似,特别是在单个小泡簇相互连接以形成复杂的网络方面。luminal和abluminal网络不是在通信中,至少不是在静态图像中。然而,在数量上,大多数直接冷冻的内皮细胞比同类的戊二醛固定细胞具有更少的囊泡轮廓。这种差异可以通过假设冷冻固定的快速作用(大约1毫秒)给出更准确的囊泡网络图像来解释,因为它捕获了不稳定或动态膜的瞬态结构。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Cryofixation of vascular endothelium.

Cryofixation refers to the immobilization of tissue components by the rapid removal of heat from the specimen, so that the structure is interred and stabilized in a natural embedding medium, namely, frozen (amorphous or microcrystalline) tissue water. Cryofixation is now often used as a complement to the more traditional fixation methods, especially when the cell structure is delicate or dynamic and may be inaccurately preserved by the slow selective action of chemical fixatives. Vascular endothelial cells are specialized for transcellular transport and for the regulation of blood flow and composition. The dynamic and labile subcellular organization of these cells, presumably reflecting these functional specializations, makes them ideal candidates for cryofixation. Several different types of endothelial cells were directly frozen at temperatures below 20 degrees Kelvin by pressing them against a liquid-helium-cooled block. These samples were subsequently processed for structural analysis by freeze-substitution. Detailed rationales, designs, and protocols are described for both freezing and freeze-substitution. Electron micrographs of cryofixed arterial and venous capillaries (rete mirabile of the American eel), iliac vein (rabbit), and cultured endothelium from the iliac vein (human) reveal that the organization of the characteristic intracellular membrane system of endothelial vesicles is qualitatively similar to that seen in chemically fixed endothelium, especially with regard to the interconnection of clusters of individual vesicles to form elaborate networks. The luminal and abluminal networks are not in communication, at least not in static images. Quantitatively, however, most directly frozen endothelial cells have far fewer vesicular profiles than comparable glutaraldehyde-fixed cells. The differences can be explained by presuming that the rapid action of cryofixation (approximately 1 msec) gives a more accurate picture of the vesicular network because it captures the transient structure of labile or dynamic membranes.

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