锇酸钾糖原对比染色的化学方面

Chemical aspects of glycogen contrast-staining by potassium osmate.

作者信息

Riemersma J C, Alsbach E J, De Bruijn W C

出版信息

Histochem J. 1984 Feb;16(2):123-36. doi: 10.1007/BF01003544.

DOI:10.1007/BF01003544

Abstract

To obtain contrast-staining of glycogen in electron microscopy, various contrast-enhancing additives can be used in combination with potassium osmate. Examples are potassium ferrocyanide and certain nitrogen heterocyclic compounds, such as triazoles. In the reaction sequence leading to contrast-stained glycogen, a primary reaction is the formation of glycogen osmate. This reaction was studied with isolated glycogen. On the basis of the stoichiometric findings, a molecular structure of the reaction product is proposed; apparently, osmate is bound by glycogen because of the presence of suitably located hydroxyl groups. The resulting compound is not itself sufficiently electron dense, but it binds 1,2,4-triazole as an additional ligand. Secondary reactions can result in additional osmium binding, and finally to osmium (IV) deposits, leading to contrast.

摘要

为了在电子显微镜下获得糖原的反差染色，各种反差增强添加剂可与锇酸钾联合使用。例如亚铁氰化钾和某些氮杂环化合物，如三唑。在导致糖原反差染色的反应序列中，一个主要反应是形成糖原锇酸盐。该反应是用分离出的糖原进行研究的。根据化学计量学研究结果，提出了反应产物的分子结构；显然，由于存在位置合适的羟基，锇酸盐被糖原结合。生成的化合物本身电子密度不够高，但它能结合1,2,4-三唑作为额外的配体。二级反应会导致更多的锇结合，最终形成锇（IV）沉积物，从而产生反差。

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