A silver impregnation method for embedded central nervous tissue of the rat

A simple and yet reliable silver impregnation method, using potassium ferrocyanide, for demonstrating nervous tissue of the rat central nervous system embedded in paraffin or paraplast is described. The method reported here is compared and discussed with earlier techniques using potassium dicyanoargentate, potassium ferrocyanide and potassium ferricyanide.     

Rapid method of silver nitrate impregnation of elements of the peripheral nervous system suitable for celloidin and paraffin sections

According to the method of neural elements impregnation in the authors' modification, the object is fixed for 6-12 h in Lillie fluid cooled to 4 degrees C. Then the object is kept under tap water for 2-6 h. Frozen sections are prepared and kept in pure pyridine for 1-6 h. When the sections are embedded into paraffin or celloidin, they are put into alcohol solutions gradually decreasing their concentration until water is reached, then put into pyridine. In order to remove cellulose, the celloidin sections are treated in 3 portions of pyridine (in the 1st and 2nd-for 10 min, and in the 3d-for 6 h). Then they are washed under tap water for 2-4 h and in distilled water for 30-40 min. Further treatment is performed according to the methods by Bielschowsky - Gros, Kampos or Rasskazova. Excess silver is removed by treating the sections in 2% ammonium persulfate under the microscope control (the process is stopped by putting the sections into 7% sodium hyposulfate for 10 min). Then the sections are treated in 0.1% aurum chloride, in 5% hyposulfite to reveale the tissue background [corrected] and by means of routine histological techniques either after Brashet, Hale, PAS-positive reaction or other methods applied after fixation in Lillie fluid.     

A Bodian method for mounted frozen sections.

For application of the Bodian method to frozen sections, cut frozen peripheral nerve or muscle at 10 mum and mount. Fix for 4 days in 18 parts 80% ethanol, 1 part 10% formalin, and 1 part glacial acetic acid. Fix central nervous tissue in the same mixture prior to freezing and sectioning, and after mounting postfix for 4 days. Impregnate by the Bodian procedure. The results equal Bodian stains of paraffin sections. The technique is simple and reliable. The use of 10 mum frozen sections produces little artifact and allows alternate serial sections to be stained with other techniques.     

A method for silver impregnation of mammary myoepithelia

Histochemical methods for microscopic visualization of mammary myoepithelial cells all yielded considerable variation in completeness of myoepithelial cell staining. Although extremely variable, silver impregnation occasionally gave tissue sections containing myoepithelia having excellent microanatomical detail and contrast with other tissue elements. Consequently, sources of variation in the silver technique were considered. Composition of the tissue fixative and pH of the silver impregnating solution were most critical. A final method is presented which gives consistent, complete silver impregnation of myoepithelia, where both the cell body and cell processes are clearly evident. The staining procedure is not light sensitive, nor is acid cleaning of glassware necessary. Tissue sections from lactating mouse, rat, hamster and goat are presented; tissue from other species should stain as well. The procedure should greatly facilitate the study of the function of myoepithelial cells and the visualization of these cells in mammary pathology.     

A modified silver method for demonstrating developing nervous tissue in culture

Dissociated explants of 8-day-old embryonic chick cerebrum were cultured for up to 18 days. By the beginning of the 2nd week and thereafter, primary cultures of neurons exhibited characteristic differentiated morphology with an interconnecting neurofibrillary network that became increasingly ramified. Neurons in bipolar, tripolar or multipolar form could be demonstrated positively using a short modified silver impregnation method with potassium ferrocyanide.     

A silver impregnation technique for the study of steroid receptors in central nervous system tissue prepared for autoradiography

The commonly used silver stains were found to be unsatisfactory for nervous tissue processed for autoradiography. A silver impregnation procedure for central nervous system tissues prepared for the autoradiographic study of steroid receptors is described. The procedure is a combination of several silver and reticular strains made up in solutions containing dimethylsulfoxide. The technique clearly distinguishes perikarya of neurons, brain nuclei and fiber tracts without substantial loss of silver grains, and thus greatly facilitates the identification of steroid receptor nuclei at all levels of the central nervous system.     

Alcoholic Bouin fixation of insect nervous systems for bodian silver staining. III. A shortened, single impregnation method

Satisfactory Bodian silver staining of paraffin wax sections of both locust (Schistocerca gregaria) and cockroach (Periplaneta americana) central nerve tissue can be obtained with only one impregnation, instead of the usual two, by the following modified procedure. Freshly dissected ganglia are fixed in an improved synthetic alcoholic Bouin (40% formaldehyde 0-15: ethanol 25: acetic acid 5: picric acid 0.5: either ethyl acetate 5 and diethoxymethane 15, or ethyl acetate 25: distilled water to 100). Formaldehyde content governs intensity of glial staining (little or none without formaldehyde) and the mixture with more ethyl acetate substituted for diethoxymethane gives more intense staining overall. Sections are impregnated once only, overnight, in 2% Protargol solution brought to about pH 8.4 with ammonium hydroxide and containing 1.3 g of copper per 65 ml. Depending on fixative composition, species, section thickness and contrast desired between nerve fibers and background, the subsequent distilled water rinse is shortened or omitted and sections are developed in 1% hydroquinone with sodium sulfite content reduced (to 2.5-4% Na2SO3.7H2O) for thinner (10 micrometer) sections but normal (10%) for thicker (20 micrometer) ones. Sections are finally washed, gold intensified, treated with sodium thiosulfate and dehydrated, cleared and mounted as usual. Results are slightly lighter than with normal double impregnation but entirely suitable for studies of neuroanatomy.     

Influence of carbon dioxide on the impregnation of the nervous tissue by silver

It has been shown that 4% carbon dioxide (CO₂) in the air above reaction mixture inhibits the initiation of the formation of silver nanoparticles from complexes with biogenic amines (noradrenaline and serotonin). At the same concentration of CO₂ in the air above solution of AgNO₃, which is used for staining nerve tissues by the method of Golgi, neurons are preferentially stained, whereas at a concentration of 0.06%, vessels are stained. It is suggested that the entry of free silver ions to neurons is due to the inhibition of sites of initiation of silver nanoparticles in vessels at high CO₂ concentrations, while the lack of inhibition leads to silver precipitation in vessels at low CO₂ concentrations. It can be assumed that, for stable silver impregnation, the concentration of CO₂ must be controlled.     

Rio Hortega's silver impregnation technic of paraffin sections. First report]

Rio Hortega's silver impregnation techniques were meant and developed for frozen sections. They offer real advantages even if they are employed for impregnation of paraffin sections. The authors have tried to transform these methods, and the results have been excellent. Further communications will follow to describe the transformation of other methods and variants.     

A controlled silver impregnation method to characterize cultured cardiomyocytes

A morphological characterization of cultured cardiomyocytes was attempted using a modification of a silver impregnation technique originally described for connective tissue. Cardiac cells, obtained from newborn rats and grown as dissociated cultures on plastic surfaces, were fixed in methanol plus 5% glacial acetic acid, treated with potassium permanganate, decolorized in oxalic acid, sensitized with potassium bichromate, impregnated with a silver-ammonium complex, reduced in gelatin-formalin preparation, toned with gold chloride and fixed in sodium thiosulfate. The cultured cardiac cells tended to form a monolayer, although many myocytes remained isolated. Spherical nuclei, sharply stained with silver, were centrally located and surrounded by relatively plentiful cytoplasm packed with well delineated myofibrils. Contaminating fibroblasts were readily distinguished by their spindle-shaped nuclei and the presence of overstained collagen fibers, as well as the absence of myofibrils. In the absence of specific antibody for immunocytochemical identification of cardiomyocytes, morphological characterization of cell type and degree of differentiation by the controlled silver impregnation procedure described here provides a viable alternative, both in short- and long-term studies.     

Rapid Bielschowsky silver impregnation method using microwave heating.

The Bielschowsky silver impregnation method has been used extensively to demonstrate neuronal processes including dendrites, axons and neurofibrils. In this study, we examined the differences in the time required for and the staining quality of the Bielschowsky method for neuronal processes when microwave heating was used instead of processing at room temperature. For this purpose, a control group of sections stained according to the conventional method at room temperature was compared to an experimental group stained in a microwave oven at 180 W for 2, 4 and 1 min in 2% silver nitrate, ammoniacal silver nitrate and gold chloride, respectively. Light microscopic examination demonstrated that the normal structure was preserved in both groups and that there was no difference in the staining quality between the control and the microwave groups. In addition, staining time for this procedure was reduced to 8 min by using the microwave oven. Our study revealed that microwave irradiation can be used safely for Bielschowsky silver impregnation of neuronal tissues.