1. Effects of Embedding 2. Experiments with Modifications

Paraffin embedding was found to be satisfactory for brain stained by a modification of the Golgi dichromate-silver method. Nitrocellulose embedding caused fading in a few specimens. Several modifications in which the tissue was impregnated with silver nitrate before treating it with potassium dichromate were investigated. The following one is recommended. Fix pieces of brain 5-6 mm. thick for 2 days in: silver nitrate;0.5%, 90 ml.; formalin, comml. unneutralized (37-40% gas), 10 ml.; pyridine, pure, 0.05-0.1 ml. Mix in the order given and test for pH with brom cresol purple. A pH of 5.5-6.0 is about optimum and the amount of pyridine added can be varied to adjust it. A slight turbidity of the fixing fluid may be disregarded, but precipitation indicates too much alkalinity. Rinse the tissues with distilled water and place them in a mixture of potassium dichromate, 2.5%, 100 ml. and osmic acid, 1%, 1 ml., for 3-5 days. Wash in water, dehydrate with alcohol and embed in soft paraffin for thick sectioning. Greater intensity of staining (but with an increase in precipitate) can be secured by rinsing the blocks after the dichromate treatment and resilvering in a 0.5% solution of silver nitrate for a day or two, then washing, dehydrating and embedding. This modification of the Golgi method was worked out on brain of adult rat, guinea pig, cat and monkey. Results with fetal material were not good. All solutions used were aqueous, and staining was done at room temperature.     

Selective Silver Impregnation of Degenerating Axons In The Central Nervous System

Rat and rabbit brains containing surgical lesions of 5-10 days' duration were fixed in 10% formalin (neutralized with calcium carbonate) for 1 week to 6 months. Frozen sections (15-20 n) were rinsed and then soaked 7 minutes in a 1.7% solution of strong ammonia in distilled water. Subsequent treatment was as follows: rinse; 0.05% aqueous potassium permanganate 5-15 minutes; 0.5% aqueous potassium metabisulfite, 2 changes of 2.5 minutes each; wash thoroughly in 3 changes distilled water; 1.5% aqueous silver nitrate, 0.5-1.0 hr.; 1% citric acid, 5-10 sec.; 2 changes distilled water; 1% sodium thiosulfate, 30 see.; 3 changes distilled water. Each section is then processed separately. Ammoniacal silver solution (450 mg. silver nitrate in 10 ml. distilled water; add 5 ml. ethanol; let cool to room temperature; add 1 ml. strong ammonia water and 0.9 ml. of 2.5% aqueous sodium hydroxide), 0.5-1.0 min. with gentle agitation. Reduction of about 1 minute is accomplished in: distilled water, 45 ml.; ethanol, 5 ml.; 10% formalin, 1.5 ml.; 1% citric acid, 1.5 ml. Rinsing; 1% sodium thiosulfate, 10 sec.; thorough washing followed by dehydration through graded alcohol and 3 changes of xylene or toluene complete the staining process. Normal nerve fibers are slightly stained to unstained, degenerating fibers, black. The treatment in potassium permanganate is critical since too little favors overstaining of normal fibers and too much abolishes staining of degenerating fibers.     

A Golgi-electron microscope method for insect nervous tissue.

Golgi's light microscope method of selective silver impregnation for nervous tissue combined with electron microscopy appears to offer a promising method for working out the detailed anatomy of individual neurons and their connections. Insect nervous tissue is fixed in a mixture of 2% paraformaldehyde and 2 1/2% glutaraldehyde in Millonig's buffer (pH 7.2) before postfixation for 12 hours in a solution brought to pH 7.2 with KOH containing 2% potassium dichromate, 1% osmium tetroxide and 2% D-glucose. The tissue is then transferred to a solution of 4% potassium dichromate for 1 day; and for 1-2 days to a 0.75% silver nitrate solution. After dehydration and embedding in Araldite, 50 mum sections are made. Areas of interest are cut from these sections and re-embedded in silicone molds. Ultrathin sections are then cut and stained with uranyl acetate and lead citrate. The Golgi method described here gives good results at the level of both light and electron microscopy.     

Silver Impregnation of Degenerating Axons in the Central Nervous System: A Modified Technic

Frozen sections of formalin-fixed brains containing surgical lesions, were treated with 15% ethanol for 0.5 hr., soaked in 0.5% phosphomolybdic acid for 0.25-1.0 hr., and subsequently treated with 0.05% potassium permanganate for 4-10 min. (The duration of the latter treatment is critical and individually variable). Subsequent procedure is as follows: decolorize in a mixture of equal parts of 1% hydroquinone and 1% oxalic acid; wash thoroughly and soak sections in 1.5% silver nitrate for 20-30 min.; ammoniacal silver nitrate (silver nitrate 0.9 g., distilled water 20 ml., pure ethanol 10 ml., strong ammonia 1.8 ml., 2.5% sodium hydroxide 1.5 ml.) 0.5-1.0 min.; reduce in acidified formalin (distilled water 400 ml., pure ethanol 45 ml., 1% citric acid 13.5 ml., 10% formalin 13.5 ml.) 1 min.; wash, and pass section through 1 % sodium thiosulf ate (0.5-1.0 min.); wash thoroughly and pass sections through graded alcohols and xylene (3 changes); cover in neutral synthetic resin.     

A Golgi-Electron Microscope Method for Insect Nervous Tissue

Golgi's light microscopic method of selective silver impregnation for nervous tissue combined with electron microscopy appears to offer a promising method for working out the detailed anatomy of individual neurons and their connections. Insect nervous tissue is fixed in a mixture of 2% paraformaldehyde and 21/2% glutaraldehyde in Millonig's buffer (pH 7.2) before postfixation for 12 hours in a solution brought to pH 7.2 with KOH containing 2% potassium dichromate, 1% osmium tetroxide and 2% D-glucose. The tissue is then transferred to a solution of 4% potassium dichromate for 1 day; and for 1-2 days to a 0.75% silver nitrate solution. After dehydration and embedding in Araldite, 50μm sections am made. Areas of interest are cut from these sections and re-embedded in silicone molds. Ultrathin sections are then cut and stained with uranyl acetate and lead citrate. The Golgi method described here gives good results at the level of both light and electron microscopy.     

Golgi Impregnation After Formalin Fixation

Formalin fixed (10% aqueous) brain from cat, rabbit and man cut to blocks 3-4 mm. thick was placed in a mixture of potassium bichromate, 5 g.; chloral hydrate, 3 g. and water 90 ml. for 24 hours. The specimens were rinsed through 3 changes of water, and transferred through 3 changes of 1% silver nitrate, 1-3 minutes each, then placed for 24 hours in 1.5% silver nitrate. Frozen sections, 40-50 μ were dehydrated and mounted with a cover glass, using Permount. No deterioration of the stain was seen after 5 months. Some brains had been in formalin for 9 months; others only 7 days.     

Silver Impregnation of the Golgi Apparatus, with Subsequent Nitrocellulose Embedding

The appearance of silver impregnation of the Golgi apparatus can be enhanced by the use of nitrocellulose as an embedding medium. Fixation of 1.5 mm thick pieces of fresh tissue for 8 hr in: glycine, 1.7 gm; 15% formalin, 100 ml; HNO₃, conc., 0.5 ml, at pH 2.6 followed by rinsing in water, 4 hr in 1.5% AgNO₃, another rinse, and 2 hr reduction in 1.5% hydroquinone in 15% formalin. This staining procedure yields consistently good results for rat, rabbit, and human tissues. Low-viscosity nitrocellulose embedding is done by infiltrating at 56 C in 7% nitrocellulose for 0.5 hr, 15% for 4 hr, and 27% for 1 hr. The nitrocellulose is hardened 2 hr in chloroform, after which, sections as thin as 5 μ can be cut on a sliding microtome. Gold toning and counterstaining can be done with the tissue affixed to the slide. The Golgi apparatus is stained dark brown to black, and there is better preservation of cellular detail than in tissues processed in paraffin.     

Golgi potassium-dichromate silver-nitrate impregnation

Summary Golgi preparations were made by consecutive treatment of formalin-fixed brain and liver with potassium dichromate and silver nitrate. Impregnated tissue dissected from thin slices of the blocks were studied by X-ray powder diffraction methods, in a diffractometer and a Guinier camera. Such tissue proved to contain crystalline silver chromate, Ag₂CrO₄, both while still in the silver nitrate solution and after dehydration in ethanol and clearing in xylene and xylene-Dammar resin. No other compounds containing chromium or silver were detectable. Formalin-fixed tissue merely treated with silver nitrate contained silver chloride, but in impregnated tissue the amount was too scarce to be visible. Hence, silver chloride was no integral part of the Golgi precipitate.A number of mostly ethereal oils traditionally used for clearing histological sections, did not cause the appearance of metallic silver in detectable amount in the Golgi preparations. However, after treatment with clove oil and creosote metallic silver was detected in the tissue.This study was supported by U.S. P.H. S. Grant NS 07998. This aid is gratefully acknowledged.We are indebted to Miss I. Madsen and Mrs. K. Sörensen for technical assistance.     

Golgi'S Dichromate-Silver Method 3. Chromating Fluids

Slices of cat brains that had been fixed in 10% aqueous formalin for various periods from 2 days to over a year were subjected to different types of chromation prior to impregnation with silver nitrate. Acid solutions of Al, Ba, Ca, Cd, Ce, Co, Cu, Fe, K, Ni, Sr and Zn chromates were tested for usefulness as chromating agents. The chromates of Cd, Co, K, Sr and Zn were found to be best; Ca, Ce and Ni gave positive results, but Al, Ba, Cu and Fe were quite unsatisfactory. Acetic acid was somewhat preferable to formic as the acidifying agent. A formula consisting of potassium chromate, 5% aq., 100 ml. and glacial acetic acid 6-8 ml. was found to be similar in action to comparable mixtures that contained the chromate of Cd, Co, Sr or Zn. Brain slices chromated 24-48 hours in these acidified chromates and silvered in 0.75-1.0% silver nitrate for 12-24 hours at 37-40° C. gave at least three times as many good preparations as similar specimens chromated with plain potassium dichromate solution.     

Alcoholic Thionin Counterstaining Following Golgi Dichromate-Silver Impregnation

Brains of cats that had been fixed 2 months or longer in 10% formalin were cut into 3-6 mm. slices and impregnated by Golgi's dichromate-silver procedure (6% dichromate solution, 4-6 days; 1.5% silver nitrate solution 2 days). Sections 100 µ thick were cut after embedding in low melting point paraffin. Three changes of xylene and three of absolute alcohol were followed by staining 3-5 minutes in a saturated solution of thionin in absolute alcohol. The sections were dipped quickly in absolute alcohol and cleared in xylene, then differentiation was effected by an equal-parts mixture of absolute alcohol and xylene. A final clearing in three changes of xylene and mounting in Permount completed the process. Counter-staining was most successful when applied to freshly cut sections.     

Visualization of Legionella pneumophila in paraffin sections using hexamine silver

A modification of Gomori's hexamine silver technique is given as a simple, reliable method for the nonspecific demonstration of Legionella pneumophila in paraffin sections. When tested against serogroups I to VI it was found that pretreatment with potassium dichromate rendered L. pneumophila demonstrable by the Gomori-Burtner hexamine silver solution when buffered to pH 7.8. Tissue was fixed in 10% buffered formalin and sections were cut at 3-5 microns. After treatment with 10% potassium dichromate for 1 hour at room temperature, sections are placed in the silver solution at 56 C until they develop a pale golden yellow color, at which point they are checked periodically under the microscope for optimal staining (approximately 3-4 hours). Sections are then toned, fixed and counterstained in 1% neutral red. The L. pneumophila coccobacilli stain black against a clear background, while nuclei stain red/black.     

Visualization of Legionella Pneumophila in Paraffin Sections using Hexamine Silver

A modification of Gomori's hexamine silver technique is given as a simple, reliable method for the nonspecific demonstration of Legionella pneumophila in paraffin sections. When tested against serogroups I to VI it was found that pretreatment with potassium dichromate rendered L. pneumophila demonstrable by the Gomori-Burtner hexamine silver solution when buffered to pH 7.8. Tissue was fixed in 10% buffered formalin and sections were cut at 3-5 μm. After treatment with 10% potassium dichromate for 1 hour at room temperature, sections are placed in the silver solution at 56 C until they develop a pale golden yellow color, at which point they are checked periodically under the microscope for optimal staining (approximately 3-4 hours). Sections are then toned, fixed and counterstained in 1% neutral red. The L. pneumophila coccobacilli stain black against a clear background, while nuclei stain red/black.     

Formalin-Pyrogallol As A Fixative For Plant Cytoplasm

Specimens of plant material 5.0 mm. thick or thinner were fixed 12-24 hours in a mixture of 10% commercial formalin 100 ml.; N NaOH, 1 ml. and pyrogallol 7 g. Histologic results obtained after paraffin embedding, mordanting of sections 24 hours in 2% ferric alum and hematoxylin staining indicated that the fixation was especially good for cytoplasmic structures.     

A Urea Silver Nitrate Method for Nerve Fibers and Nerve Endings

A silver nitrate stain for nerve fibers and endings applicable to paraffin sections on the slide utilizes the properties of urea to accelerate the procedure and improve the specificity of the stain. After removal of the paraffin the sections are run through absolute, 95% and 80% alcohol and placed for 60-90 minutes at 50-60°C. in: 1% aqueous silver nitrate, 100 ml.; urea, 20-30 g.; 1g. mercuric cyanide and 1 g. picric acid in 100 ml. of distilled water, 1-3 drops. After the silver bath they are rinsed quickly in 2 changes of distilled water and reduced for 3-5 minutes at 25-30°C. in: water, 100 ml.; sodium sulfite, anhydrous, 10g.; hydroquinone, 1-2g.; urea, 20-30g. They are then washed thoroughly in 4-5 changes of distilled water, passed through graded alcohols into 80% alcohol and examined under the microscope. If nerve fibers are not distinct, the sections are returned to the same urea-silver-nitrate bath for 10-15 minutes, rinsed, reduced, washed and dehydrated as before. This process may be repeated until staining is adequate; then they are dehydrated, cleared, and mounted.

Nerve fibers show a color range from brown to black; nerve cells from yellow to brown; and the background, depending on the type of tissue and its fixation, from yellow to light brown.     

The Golgi silver impregnation method: commemorating the centennial of the Nobel Prize in medicine (1906) shared by Camillo Golgi and Santiago Ramón y Cajal

The Golgi silver impregnation technique is a simple histological procedure that reveals complete three-dimensional neuron morphology. This method is based in the formation of opaque intracellular deposits of silver chromate obtained by the reaction between potassium dichromate and silver nitrate (black reaction). Camillo Golgi, its discoverer, and Santiago Ramón y Cajal its main exponent, shared the Nobel Prize of Medicine and Physiology in 1906 for their contribution to the knowledge of the nervous system structure, Their successes were largely due to the application of the silver impregnation method. However, Golgi and Cajal had different views on the structure of nervous tissue. According to the Reticular Theory, defended by Golgi, the nervous system was formed by a network of cells connected via axons within a syncytium. In contrast, Cajal defended the Neuron Doctrine which maintained that the neurons were independent cells. In addition, Golgi had used a variant of his "black reaction" to discover the cellular organelle that became known as the Golgi apparatus. Electron microscopy studies confirmed the postulates of the Neuron Doctrine as well as the existence of the Golgi complex and contributed to a resurgence of use of the Golgi stain. Although modern methods of intracellular staining reveal excellent images of neuron morphology, the Golgi technique is an easier and less expensive method for the study of normal and pathological morphology of neurons.     

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.     

Staining of Nervous Tissue by Protein-Silver Mixtures

A staining method for nerves in paraffin sections is described in which an egg albumen-silver nitrate mixture is the impregnating solution. Blocks of tissue are fixed in Bouin's fixative, formol, Huber's fixative or formol-acetic-alcohol, and decalcified if necessary in Bensley's decalcifier. Sections are impregnated overnight, in the dark, at 37-56°C in a solution containing 50 ml of filtered, aqueous 0.5% dried egg albumen with 1.8-2.5 ml of 2% silver nitrate and adjusted to pH 8.2-8.3 by the addition of ammonia. The sections are then rinsed in distilled water and the silver reduced in a mixture of hydroquinone, 1 gm; anhydrous sodium sulfite, 10 gm and distilled water, 100 ml. The remainder of the process consists of washing, gold toning, fixing in 5% sodium thiosulfate, washing, dehydrating, clearing and mounting. Casein may be used as an alternative to egg albumen in the impregnating solution (0.5% casein, 50 ml; 2% silver nitrate, 1 ml). The pH value of the solution may be adjusted by a boric acid-borax buffer or ammonium hydrogen tetraborate in the place of ammonia.     

Assay for polyunsaturated fatty acids by argentation-thin-layer chromatography using commercial thin-layer plates

A simple, rapid, and convenient procedure for silver nitrate impregnation of commercial precoated silica gel plates is described. Silica-gel plates (Silica gel 60, E. Merck) were sprayed with 40% silver nitrate in water, dried in air, and activated at 100°C for 30 min. Samples containing fatty acid methyl esters were applied as 0.5- to 1.0-cm streaks and developed with a solvent system of benzene:ethyl acetate (9:1, v/v). The plates were sprayed with 70% sulfuric acid saturated with potassium dichromate, and the spots were detected by careful heating at 120°C for 90 min. This procedure is useful for separation and isolation of various species of fatty acid methyl esters and for simple, rapid, and reproducible estimation of microgram quantities of materials by spectrodensitometry of the chromatogram.     

Modification of the Marchi Technic

The formula proposed by Swank and Davenport (1935) was modified and applied to human and macaque nervous material. Three groups of experiments were performed and the following observations were made. (1) Diluting the osmic acid component, without altering the relative concentration of the other constituents of the solution resulted in practically no staining of the degenerated fibers. (2) When all constituents of the staining solution were used in much lower concentration than previously suggested, enhancement of staining of the degenerating fibers occurred and the different structures of the normal tissue were more easily identified. (3) At low concentrations of osmic acid and potassium chlorate, the contrast was diminished and artifacts produced by increasing the concentration of acetic acid or formalin or both. The new formula, based on the present results, consists of osmic acid, 0.5%, 11 ml.; potassium chlorate, 1%, 16 ml.; formalin (cone), 3 ml.; acetic acid, 10%, 3 ml.; and distilled water to make 100 ml. (All solutions are aqueous). Good staining after a long period of fixation in formalin, following degeneration of 8-80 days, was obtained and the cost of staining solution greatly reduced.     

Staining and Mounting Helminths

The following procedure is recommended: Fix ces-todes and trematodes (while held flat between glass slides) 0.5-2.0 hr. in the following mixture: formalin, 15; acetic acid (gl.), 5; glycerol, 10; 95% ethyl alcohol, 24; distilled H₂O, 46; all proportions by volume. After freeing them from the slides, wash thoroughly in running water and stain immediately thereafter. Stock staining solution: ferric ammonium alum (violet cryst.), 2 g.; distilled H₂O (cold) 100 ml.; after solution, add 2 ml. concentrated H₂SO₄, bring to a boil; add 1 g. coelestin blue B (Nat. Aniline), boil 3-5 min.; cool and add 10 ml. absolute methyl alcohol and 10 ml. glycerol. Dilute 1 vol. with 3 vol. distilled H20 for use. Stain 5-30 min., depending on size of specimens. Wash with 2 changes 0.5 hr. each of distilled H₂O, then 50% isopropyl alcohol 12-16 hr., 50% isopropyl alcohol 2 hr., followed by graded isopropyl alcohol for dehydration. Ether: ethyl alcohol (equal parts), 1 hr., is followed by embedding in celloidin in a sheet just thick enough to cover the specimens. Trim embedded specimens and dehydrate with isopropyl alcohol, 80%, 90% and absolute. Clear in beechwood creosote. Mount in balsam with cover glasses that overlap the edges of the celloidin 1-2 mm. While drying at 37°C, refill edges of mount with fresh balsam as needed. When dry, remove excess balsam and ring the edges with ordinary gloss enamel paint.