ascorbic-acid and silver-chromate

Direct electron microscopy of nervous tissue stained with the Golgi impregnation method is unsatisfactory because the cytoplasm of the cell bodies and processes of the impregnated neurons are completely filled with a compact precipitate of electron dense silver chromate. This precipitate entirely obscures the cytological details of the impregnated neurons. Because of its solidity and instability in aqueous solutions, the silver chromate is also a source of inconvenience during the preparation of the ultrathin sections. This review summarizes methods that have been developed with the aim of replacing the Golgi precipitate in CNS neurons with a more convenient electron dense material--for example, heavy metal salts or metallic particles. Conversion of the precipitate into a stable electron dense marker is done before the material is embedded for electron microscopy. The methods include lead, gold, and bromide substitution, treatment with ammonia, direct chemical reduction into metallic silver, and photoreduction of the silver chromate into silver through irradiation with ultraviolet light.

Topics: Aminophenols; Animals; Ascorbic Acid; Brain; Chromates; Microscopy, Electron; Neurons; Rats; Silver; Silver Compounds; Silver Staining

The silver chromate precipitate present in neurons impregnated according to the Golgi-rapid and Golgi-Kopsch procedures can be stabilized by treatment with a photographic developer. In a complementary light microscopic study the stabilizing properties of various photographic developers were tested. Kodalith, Elon-ascorbic acid, HC-110, D-19 and Neutol proved to be the most successful. In the present electron microscopic study, we studied the distribution, shape and size of the particles found in Golgi-rapid and Golgi-Kopsch-impregnated neurons by treatment with each of these developers and, simultaneously, the effect of the developer on the preservation of the ultrastructural details. The reaction product after developer-treatment of Golgi-rapid material is sufficiently stable to withstand embedding and thin sectioning, whereas in Golgi-Kopsch material additional gold chloride "toning" is necessary. In Golgi-impregnated, Kodalith-, Elon-ascorbic acid-, or HC-110-treated material the formed particles are small and located in the cytoplasm, limited by the plasma membranes of the impregnated profiles. In Golgi-impregnated, D-19 treated neurons, the formed particles are relatively coarse. The majority of these particles are within cytoplasm, but particles may also lie either across or entirely outside the plasma membranes of the impregnated profiles. A large number of the small particles in Golgi impregnated, Neutol-stabilized neurons can be seen partly or entirely outside the plasma membranes of the impregnated profiles. Good original ultrastructural preservation seems to be unaffected by developer treatment. Treatment of Golgi material with sodium bromide before stabilization (bromide substitution) results in the formation of small silver particles both inside and outside the impregnated profiles. The sodium bromide step of this procedure has an adverse effect on the preservation of ultrastructural detail.

Topics: Aminophenols; Animals; Ascorbic Acid; Brain; Bromides; Chromates; Golgi Apparatus; Male; Microscopy, Electron; Neurons; Photochemistry; Photography; Rats; Rats, Inbred Strains; Silver; Silver Compounds; Staining and Labeling