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.     

Application of silver stains to gastric endocrine cells in plastic sections

Summary A simultaneous light and electron microscopic study of mouse gastric mucosa was made to determine whether the silver nitrate methenamine stain of Duk-Ho Lee could be used to stain gastric endocrine-like cells in plastic embedded tissue. Examination of consecutive thick and thin sections showed that this stain blackened the granules of the predominant type of endocrine-like cell present. Blackening of the granules with silver occured in tissue fixed in osmium tetroxide solution with or without dichromate salt or in tissue fixed in glutaraldehyde then treated with osmium. The intensity of staining was deepest in the osmium-dichromate fixed tissue, but the glutaraldehyde-osmium procedure gave less interference from diffuse silver impregnation and better preservation of detail for electron microscopy.     

A Modified Silver Impregnation Technique for the Observation of Thick Sections of Lymph Nodes Perfused with Colloidal Carbon

For many years, a variant of the silver impregnation technique of Bielchowsky has been used to study the lymph node because it clearly outlines the various structures which are usually hard to contrast with standard staining methods. Like other variants of silver impregnation, this method blackens the cell nuclei as well as the reticular fibers; however, it inhibits the impregnation of the nuclear chromatin immediately adjacent to fibers. Hence, this variant selectively darkens the lymphoid cell populations of the nodal structures which contain a loose fiber network.

To study the blood vascular network of the lymph node based on perfusion of colloidal carbon, a staining procedure was needed which would contrast nodal structures on thick sections, while allowing the carbon-filled small blood vessels to be distinguished from the impregnated coarse reticular fibers. In an attempt to adapt this variant of Bielchowsky's technique, 10, 20, 40 and 60 nm thick sections from rat nodes, fixed in a solution of Bouin-Hollande for 72 hr, were silver impregnated with serial dilutions (1:2 to 1:128) of the ammoniacal silver solution. Forty-micrometer thick sections impregnated with a 1:16 dilution of the original silver solution at 37 C and for 30 min provided the best results for the conditions.     

Postembedding Staining of Brain Tissue for Ultrastructural Visualization of Amyloid in Alzheimer's Disease

A postembedding staining method is presented for ultrastructural visualization of amyloid deposits in brain sections from patients with Alzheimer's disease. Methenamine silver stain is applied to thin sections of tissue embedded in the acrylic resin LR Gold. Senile plaques are easily labeled by silver granules and the ultrastructural detail is well preserved. When staining time is prolonged, silver precipitate also is deposited on neuronal paired helical filaments. This method overcomes the drawbacks of previously reported applications of the stain on Vibra-tome and Epon sections. Thin sections from the same tissue block can be immunostained with antibodies to various plaque components, thus allowing comparative studies at the electron microscope level.     

A silver carbonate method for cell counts of neurons and glial elements on paraffin embedded brain tissue.

A modification of the Del Rio-Hortega method for the demonstration of central nervous system elements is presented. This silver impregnation technique is particularly useful for the classification of cell types for quantitative differential cell counts. Formalin fixed paraffin sections are immersed in formol-ammonium bromide for 1 1/2 hours; this solution is an excellent mordant for various silver nitrate stains. The samples are stained for 20 to 60 minutes in a silver carbonate solution (25 ml of 25% silver nitrate combined with 200 ml of 5% sodium carbonate) and then reduced in a 1% formaldehyde solution to which 20 drops of acetic acid have been added. Finally, the slides are fixed in sodium thiosulfate, rinsed in tap water, dehydrated, cleared, and mounted. This procedure will enable this investigator to identify neurons, oligodendroglia, and astrocytes on the basis of their nuclear staining as well as to demonstrate the laminae of brain tissue since the method allows differentiation of cell layers and fiber tracts.     

A simple impregnation technique for thin and semithin enterochromaffin cells in sections

Summary Constant, intense and precise impregnation of enterochromaffin (EC) cells was achieved simply by floating thin or semithin sections of gut mucosa, fixed in osmium tetroxide or in glutaraldehyde with postfixation in osmium, on a silver nitrate or proteinate solution. EC cells alone showed impregnation in the light microscope. In the electron microscope, impregnation affected not only the secretory granules of EC cells but also, although much more faintly, those of other, non-EC cells (D, X, D₁, G and other cells). Lysosomes also showed partial or total reactivity. Oxidation reduced but did not entirely suppress EC cell staining and had no effect on non-EC endocrine cell staining. Since the reaction did not occur with glutaraldehyde alone, osmium appeared to be a crucial component of the process. These findings should be borne in mind in applying Thiery's method for vicinal glycol groups to the type of study material used in these experiments.     

A simple impregnation technique for thin and semithin enterochromaffin cells in sections

Constant, intense and precise impregnation of enterochromaffin (EC) cells was achieved simply by floating thin or semithin sections of gut mucosa, fixed in osmium tetroxide or in glutaraldehyde with postfixation in osmium, on a silver nitrate or proteinate solution. EC cells alone showed impregnation in the light microscope. In the electron microscope, impregnation affected not only the secretory granules of EC cells but also, although much more faintly, those of other, non-EC cells (D, X, D1, G and other cells). Lysosomes also showed partial or total reactivity. Oxidation reduced but did not entirely suppress EC cell staining and had no effect on non-EC endocrine cell staining. Since the reaction did not occur with glutaraldehyde alone, osmium appeared to be a crucial component of the process. These findings should be borne in mind in applying Thiery's method for vicinal glycol groups to the type of study material used in these experiments.     

Effect of Temperature on Argyrophil Impregnation: Development of A High Temperature Rapid Argyrophil Procedure

Out studies on the effects of temperature on the demonstration of neurosecretory granules using argyrophil stains indicate an inverse relationship between the time needed for staining and temperature of the silver and reducing solutions. Careful monitoring of the temperature of silver solutions during the Grimelius procedure and its modifications show long incubation times serve in large part only to bring the solutions to reaction temperature. Tissue sections added when this temperature has been reached will stain with the same intensity as sections impregnated for the entire incubation period. We have modified the argyrophil procedure so that double-impregnation with solutions preheated to 60-70 C and development in Bodian's reducer prepared with preheated water rapidly demonstrates secretory granules. Our method does not require a microwave oven and much shorter incubation periods are required than with usual procedures. It is not necessary to incubate sections in hot solutions for extended periods of time, which can lead to detachment of sections, nonspecific staining and decomposition of the silver solution. Rinsing after impregnation and before development greatly increases contrast of argyrophil cells by reducing background staining. Our procedure results in more reliable staining of argyrophil and argentaffin cells and takes only ten minutes.     

Effect of temperature on argyrophil impregnation: development of a high temperature rapid argyrophil procedure

Our studies on the effects of temperature on the demonstration of neurosecretory granules using argyrophil stains indicate an inverse relationship between the time needed for staining and temperature of the silver and reducing solutions. Careful monitoring of the temperature of silver solutions during the Grimelius procedure and its modifications show long incubation times serve in large part only to bring the solutions to reaction temperature. Tissue sections added when this temperature has been reached will stain with the same intensity as sections impregnated for the entire incubation period. We have modified the argyrophil procedure so that double-impregnation with solutions preheated to 60-70 C and development in Bodian's reducer prepared with preheated water rapidly demonstrates secretory granules. Our method does not require a microwave oven and much shorter incubation periods are required than with usual procedures. It is not necessary to incubate sections in hot solutions for extended periods of time, which can lead to detachment of sections, nonspecific staining and decomposition of the silver solution. Rinsing after impregnation and before development greatly increases contrast of argyrophil cells by reducing background staining. Our procedure results in more reliable staining of argyrophil and argentaffin cells and takes only ten minutes.     

Appraisals and pitfalls of myoepithelial cell staining by Levanol Fast Cyanine 5RN.

In the search for specific staining of myoepithelial cells in human normal and pathologic mammary tissue we applied the milling dye Levanol (Supranol) Fast Cyanine 5RN. Reports from literature on this staining method were considered, and efforts were made to improve the procedure. Different fixatives were tested, and the pretreatment of the sections was modified. Five nuclear stains were tried but were finally omitted. Counterstain of the connective tissue proved useful. The advantages of the different modifications are discussed.     

Quantitative histology of the rat thyroid. Influence of histologic techniques on the morphometric data

The influence of various histologic techniques on the results obtained by morphometric analysis of the rat thyroid gland was studied. The limits of thyroid follicles were more clearly defined in both silver-impregnated paraffin-embedded sections and resin-embedded semithin sections than in routinely stained paraffin-embedded sections, thus enabling more accurate measurements of thyroid structures. Due to its simplicity, the silver impregnation method is clearly useful for histomorphometric studies when large numbers of measurements are involved. C cells were easily identified in paraffin-embedded sections by immunohistochemical staining. The measurement of interstitial tissue in sections without immunostaining of C cells led to an overestimation of the volume fraction of interstitial tissue.     

Suppression of Connective Tissue Impregnation in a Silver Technique for Demonstrating Nerve Fibers

A tissue pretreatment technique is introduced which effectively suppresses the silver impregnation of connective tissue and nompecific background elements in peripheral nerve. The result is a selective impregnation of nerve fibers. The procedure utilizes fresh frozen sections and can be used with the Holmes (1947) or Bodian (1936) techniques. Fresh frozen sections are cut at 10 microns, mounted on slides and air dried for 5 minutes. They are fixed for 30 minutes in formol-sublimate (10% formalin saturated with mercuric chloride) and then placed into 0.5% iodine in 70% alcobol for 5 minutes followed by bleaching in 2.5% sodium thiosulfate for 2 minutes. After washing in running tap water for 10 minutes and a brief rinse in distilled water, impregnation is accomplished by the Holmes (1947) or Bodian (1936) procedure beginnins with the step containing the aqueous silver solution. The results show an absence of impregnation of connective tissue and nonspecific background. The technique is simple, rapid, and, by utilidng fresh hrozen sections, can be used for other histological and histochemical purposes. Several experiments were done to determine the causes of the connective tissue and background suppression. The air drying step was omitted; the sections were fixed in formalin without mercuric chloride; and the formol-sublimate fixation time was increased. The results suggest that connective tissue impregnation H suppressed by the use of mercuric chloride in the fixative and that the background supprgsion is related to the short fixation time with formol-sublimate.     

Suppression of connective tissue impregnation in a silver technique for demonstrating nerve fibers.

A tissue pretreatment is introduced which effectively suppresses the silver impregnation of connective tissue and nonspecific background elements in peripheral nerve. The result is a selective impregnation of nerve fibers. The procedure utilizes fresh frozen sections and can be used with the Holmes (1947) or Bodian (1936) techniques. Fresh frozen sections are cut at 10 microns, mounted on slides and air dried for 5 minutes. They are fixed for 30 minutes in formol-sublimate (10% formalin saturated with mercuric chloride) and then placed into 0.5% iodine in 70% alcohol for 5 minutes followed by bleaching in 2.5% sodium thiosulfate for 2 minutes. After washing in running tap water for 10 minutes and a brief rinse in distilled water, impregnation is accomplished by the Holmes (1947) or Bodian (1936) procedure beginning with the step containing the aqueous silver solution. The results show an absence of impregnation of connective tissue and nonspecific background. The technique is simple, rapid, and, by utilizing fresh frozen sections, can be used for other histological and histochemical purposes. Several experiments were done to determine the causes of the connective tissue and background suppression. The air drying step was omitted; the sections were fixed in formalin without mercuric chloride; and the formol-sublimate fixation time was increased. The results suggest that connective tissue impregnation is suppressed by the use of mercuric chloride in the fixative and that the background suppression is related to the short fixation time with formolsublimate.     

Appraisals and pitfalls of myoepithelial cell staining by Levanol Fast Cyanine 5RN

Summary In the search for specific staining of myoepithelial cells in human normal and pathologic mammary tissue we applied the milling dye Levanol (Supranol) Fast Cyanine 5RN. Reports from literature on this staining method were considered, and efforts were made to improve the procedure. Different fixatives were tested, and the pretreatment of the sections was modified. Five nuclear stains were tried but were finally omitted. Counterstain of the connective tissue proved useful. The advantages of the different modifications are discussed.     

Immunohistochemical demonstration of renin in the juxtaglomerular apparatus of three Bufo species

Summary The cellular localization of renin was examined in the kidneys of some amphibians of the genus Bufo by immunoperoxidase and immunofluorescence techniques with an antiserum to renin isolated from the submandibular gland of the mouse. Immunoreactivity could be demonstrated in the media cells of the afferent arterioles (juxtaglomerular cells) close to as well as at great distance from the glomeruli. Occasionally, media cells of larger arterial vessels were also stained. The immunohistochemical data seem to be in accordance with earlier results obtained with a modified silver impregnation technique (Movat's staining procedure) used for the visualization of juxtaglomerular cells in non-mammalian vertebrates. Mouse kidney tissue, studied for purposes of comparison, showed renin-immunoreactivity as described by earlier investigators, i.e., immunoreactive staining in the afferent arterioles near the glomeruli and in the proximal tubule cells.     

Problems and experience in the light optical and histological presentation of glia cells]

1. 8 histological techniques and 13 modifications derived from those were tested on usefulness for the demonstration of glial cells in the adult rat brain. From these methods the impregnation techniques of Golgi-Kopsch, Valenzuela y Chacón and Rio del Hortega were modified according to a scheme of variance to find out the optimal variants. 2. The impregnation quality depends on the animal species, the animal age, the health of brains, the brain area, the balanced proportion of the treatment stages and the biochemical state of the glial cells. 3. The silver impregnation techniques are not so specific that only one glial type is stained, but one type prevails. The silver carbonate procedure according to Hortega allows to impregnate oligodendrocytes, microglial cells and astrocytes in frozen as well as in paraffin sections. The method of Golgi-Kopsch is more suited for oligodendrocytes and microglial cells than for astrocytes. Following the procedure of Valenzuela y Chacón especially astrocytes, but also microglial cells allow impregnation in both frozen and paraffin sections. 4. The different demonstration qualities of the proved methods call for critical examination of absolute measurements of cell size, length of processes and ramification density. 5. The presence of cell groups of different disposition towards impregnation within a glial type speaks for a biochemical inhomogeneity of the glial types.     

Human placenta: de visu demonstration of interstitial Cajal-like cells

Traditional interstitial cells of Cajal (ICC) are present in the digestive tube and are supposed to act as pacemakers and neuromodulators. However, interstitial Cajal-like cells (ICLCs) were found outside the gastrointestinal tract, in various organs (e.g. ureter, bladder, fallopian tube, uterus, pancreas, mammary gland, myocardium etc.) and looking for such ICLC is a priority in our laboratories.We report here unequivocal visual evidence that ICLCs are present in the mesenchymal tissue of the villi from human term placenta.The following methods were used: a. vital staining with methylene blue (cryosections); b. silver impregnation (paraffin sections); c. Epon-embedded sections (approximately 1 microm) of glutaraldehyde/osmium fixed tissue, stained with toluidine blue; d. primary cell cultures (or second-passage cells) to reveal the characteristic, very long, moniliform cell processes and mitochondrial localization at dilations (molecular fluorescence probe: Mito Tracker Green); e. immunofluorescence for c-kit/CD117 marker or other characteristic proteins; f. transmission electron microscopy to establish the identity of ICLC.     

Modification of the Silver Proteinate Impregnation Technique for Protozoa and Cultured Nerve Cells

Silver impregnation with silver-protein compounds is widely used for staining tissue sections and cell cultures. Some authors report that the results obtained with these methods have not always been reproducible because the reagent's composition varies according to the manufacturer. To avoid this problem in the method described in this paper, a silver proteinate, produced in our own laboratory is used. Although our method is based on Bodian's, the modifications we have made allows its use for both free-living cells (protozoa) and cells grown in culture (nerve cells). The significant modifications are 1) different fixation, 2) postfixation with Cajal's for-mol-bromide, 3) changes in the duration of the impregnation steps technique and 4) elimination of metallic copper. The method reported here enables us to use silver proteinate whenever we require it and to control the composition of the silver proteinate. This technique can be used for cells cultured in either plastic or glass.     

Chemical Stabilization of Golgi Silver Chromate Impregnations

Blocks of neural tissue were processed by a modified Golgi-Kopsch procedure and by the rapid Golgi method. Following the impregnation, the blocks were embedded in celloidin, sectioned at 100μm, and collected in 70% alcohol. The sections were then processed as follows: 1) rinsed in distilled water; 2) substituted with 0.4M sodium bromide for five minutes; 3) reduced in Kodak D-19 developer; and 4) treated in 0.5M sodium thiosulfate. The silver chromate deposits within the impregnated cells are converted successively to silver bromide and to reduced silver by this procedure. Sections so treated resist decomposition of the Golgi impregnation, and they may be counterstained with conventional aqueous cresyl violet to demonstrate the cytoarchitecture of the Golgi-impregnated tissue.     

Chemical stabilization of Golgi silver chromate impregnations.

Blocks of neural tissue were processed by a modified Golgi-Kopsch procedure and by the rapid Golgi method. Following the impregnation, the blocks were embedded in celloidin, sectioned at 100 micrometer, and collected in 70% alcohol. The sections were then processed as follows: 1) rinsed in distilled water; 2) substituted with 0.4M sodium bromide for five minutes; 3) reduced in Kodak D-19 developer; and 4) treated in 0.5M sodium thiosulfate. The silver chromate deposits within the impregnated cells are converted successively to silver bromide and to reduced silver by this procedure. Sections so treated resist decomposition of the Golgi impregnation, and they may be counterstained with conventional aqueous cresyl violet to demonstrate the cytoarchitecture of the Golgi-impregnated tissue.