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.     

A New Method of Silver Impregnation for Nerve Cells and Fibers

Fragments of tissue, immediately after death, are fixed in Debaisieux's modification of the Duboscq-Brazil picro-aceticformol fluid, and treated as follows: Hydrate by soaking 2-6 hr. in distilled water with 30 drops of cone. NH₄OH per 100 cc. Freeze and cut sections about 25μ in thickness. Bleach sections about 15 min. in ammoniacal water (52 drops cone. NH₄OH per 100 cc. water). Transfer to 20% AgNO₃ solution and heat at 45° C. till light brown. Add cone. NH₄OH drop by drop till the Ag precipitates and then redisolves into an opalescent solution. Pour solution and sections into a little distilled water and transfer sections quickly to formaldehyde solution (3 cc. formalin to 100 cc. water). Dip sections in distilled water and transfer to 1% aqueous gold chloride till deep blue. Place for about 10 minutes in 5% aqueous sodium thiosulfate solution for fixing and clearing. Wash thoroly in tap water, dehydrate and mount. Special directions are given for applying this technic to delicate material such as insects, and for use with serial sections.     

An Ocular Grid-Planimeter Method for Enumerating Nerve Fibers

The estimation of numbers of nerve fibers in cross sections of peripheral nerves containing both fine and large fiber components can be accomplished by using an ocular grid and selectively counting a known area. With the use of a projecting apparatus and planimeter, the total cross section area is determined.

The following proportion expresses the principle involved:

total number of fibers in the nerve area of ass section of entire nerve number counted in the sample area area of sample

I f the planimeter calibration and the magnification of the tracing remain the same, a constant factor may be used for successive estimates. This factor is equal to the value of the planimeter reading of 1.000 divided by the area of the grid times the magnification squared. The final calculations are made by multiplying the number of fibers counted times the planimeter reading times the constant and dividing by the number of grid squares counted.

Counts of some nerves, using high magnification in enumerating the sample areas, can be finished in less than an hour after the preparation of slides. In comparing numbers obtained by complete counts with estimated numbers, the error was determined to be approximately ± 5%     

A Protargol Method for Staining Nerve Fibers in Frozen or Celloidin Sections

Extensive experimentation with protargol staining of neurons in celloidin and frozen sections of organs has resulted in the following technic: Fix tissue in 10% aqueous formalin. Cut celloidin sections IS to 25 μ, frozen sections 25 to 40 μ. Place sections for 24 hours in 50% alcohol to which 1% by volume of NH₄OH has been added. Transfer the sections directly into a 1% aqueous solution of protargol, containing 0.2 to 0.3 g. of electrolytic copper foil which has been coated with a 0.5% solution of celloidin, and allow to stand for 6 to 8 hours at 37° C. Caution: In this and the succeeding step the sections must not be allowed to come in contact with the copper. From aqueous protargol, place the sections for 24 to 48 hours at 37° C. directly into a pyridinated solution of alcoholic protargol (1.0% aqueous solution protargol, 50 ml.; 95% alcohol, 50 ml.; pyridine, 0.5 to 2.0 ml.), containing 0.2 to 0.3 g. of coated copper. Rinse briefly in 50% alcohol and reduce 10 min. in an alkaline hydroquinone reducer (H₃BO₃, 1.4 g.; Na₂SO₃, anhydrous, 2.0 g.; hydroquinone, 0.3 g.; distilled water, 85 cc; acetone, 15 ml.). Wash thoroly in water and tone for 10 min. in 0.2% aqueous gold chloride, acidified with acetic acid. Wash in distilled water and reduce for 1 to 3 min. in 2% aqueous oxalic acid. Quickly rinse in distilled water and treat the sections 3 to 5 min. with 5% aqueous Na₂S₂O₃+5H₂O. Wash in water and stain overnight in Einarson's gallocyanin. Wash thoroly in water and place in 5% aqueous phosphotungstic acid for 30 min. From phosphotungstic acid transfer directly to a dilution (stock solution, 20 ml.; distilled water, 30 ml.) of the following stock staining solution: anilin blue, 0.01 g.; fast green FCF, 0.5 g.; orange G, 2.0 g.; distilled water, 92.0 ml.; glacial acetic acid, 8 ml.) and stain for 1 hour. Differentiate with 70% and 95% alcohol; pass the sections thru butyl alcohol and cedar oil; mount.     

A Controllable Silver Stain for Nerve Fibers and Nerve Endings

A paraffin section method is described with a yellow-brown-black color range comparable to that of Ranson's pyridine silver block stain. After impregnation with activated protargol and reduction with a fine grain photographic developer, silver nitrate impregnation and reduction are repeated as often as necessary. The procedure is as follows:

Place hydrated sections of tissue fixed in chloral hydrate (25 g. in 100 ml. of 50% alcohol) in 1% aqueous protargol (Winthrop Chemical Co.) containing 5-6 g. metallic copper for 12-24 hours. After rinsing in 2 changes of distilled water, reduce 5 to 10 minutes in: Elon (Eastman Kodak Co.) 0.2 g., Na₂SO₃, dessicated, 10 g., hydroquinone 0.5 g., sodium borate powder 0.1 g., distilled water 100 ml. Wash thoroly in 4 or 5 changes of distilled water and place in 1% aqueous AgNO₃ for 10-20 minutes at 28°-50° C. Rinse in 2 or 3 changes of distilled water and reduce in the elon-hydroquinone solution. After thoroly washing in 4 or 5 changes of distilled water, examine under microscope.

If too pale, treat again in silver nitrate for 10-20 minutes, rinse, reduce 5-10 minutes and wash thoroly until nerve fibers show distinct microscopic differentiation, then dehydrate, clear and mount.     

The Strip Method for Counting Nerve Fibers or other Microscopic Units

A comparison of complete counts of nerve fibers by the strip method with the photographic method showed a minimum difference of 0.3% and a maximum of 2.9%. The preparations counted were selected for clarity and discreteness of fibers to avoid introducing an error (ambiguity of fibers) which is not pertinent to any particular method of counting. Agreement of counts with estimates radicated the feasibility of estimates when the greatest accuracy is not required.     

A Differential Staining Method for Elastic Fibers, Collagenic Fibers, and Keratin

A method allowing for the differential presentation of elastic fibers, other connective tissue fibers, epithelial and other types of cytoplasm, and keratin is described. The procedure is based on the affinity of orcein for elastic fibers, of anilin blue for collagenic material, and of orange G for keratin. Bouin-fixed, tissue-mat embedded sections are stained in Pinkus' acid orcein for 1 1/2 hours and rinsed in distilled water. The sections are differentiated in 50% alcohol containing 1% hydrochloric acid, washed in tap and then in distilled water. The sections are next transferred for I to 2 minutes to the anilin blue, orange G, phosphomolybdic acid combination known as solution No. 2 of Mallory's connective tissue stain, diluted 1:1 with distilled water. They are then rinsed in distilled water, quickly passed into 95% alcohol, and dehydrated in absolute alcohol containing some orange G, after which they are cleared and mounted. Within less than two hours sections may be stained and mounted with the following results: elastic fibers — red; collagenic fibers — blue; muscle fibers — yellow; keratin — orange.     

Diffusion of Ions in Myelinated Nerve Fibers

The diffusion of ions towards or away from the inner side of the nodal membrane in preparations, the cut ends of which are placed in various media, was investigated. The ion concentration changes were calculated by numerical solution of the unidimensional electrodiffusion equation under a variety of media compositions, axoplasmic diffusion coefficients, and internal anionic compositions. The potassium and cesium ion diffusion along the axon towards the node was determined experimentally by two different electrophysiological methods. On the basis of comparison between the experimental data and the computational predictions the axoplasmic potassium ion diffusion coefficient was determined to be almost equal to that in free aqueous solution, while that of cesium ion was close to one half of that in aqueous solution. Utilizing the values of diffusion parameters thus determined, we solved the electrodiffusion equation for a number of common experimental procedures. We found that in short fibers, cut 0.1-0.2 cm at each side of the node, the concentration approached values close to the new steady-state values within 5-30 min. In long fibers (over 1 cm long) steady-state concentrations were obtained only after a few hours. Under some conditions the internal concentrations transiently overshot the steady-state values. The diffusion potentials generated in the system were also evaluated. The ion concentration changes and generation of diffusion potential cannot be prevented by using side pools with cation content identical to that of the axoplasm.     

A Modified Bodian Stain for Routine Quantitative Assessment of Axonal Degeneration in Teased Nerve Fibers

We present a modified Bodian method for staining axons in teased peripheral nerves. For test material, guinea pig sciatic nerves, intact and cut in situ, were removed 3, 4 and 5 days after surgery. Notable characteristics of the stain are a strong contrast between the axon and surrounding myelin and easy detection of nodes of Ranvier. The method is suitable for the quantitative assessment of axonal degeneration.     

Silver Staining of Nerve Fibers in Cardiac Tissue

Fresh hearts of dog were perfused through the coronary vessels with 1000 ml. of fixative (chloral hydrate, 5 g. per 100 ml. of 70% ethyl alcohol) and blocks of tissue 2 × 5 mm. from epicardium to endocardium fixed 48 hours in the same fixative. The blocks were placed in 95% alcohol containing 0.3% addition of strong ammonia for 4 hours, followed by 2 changes of plain 95% alcohol of 1 hour each, then cleared and infiltrated with paraffin. Mounted sections 12-15 µ thick were incubated in 1% silver proteinate (obtained from Serumvertrieb, Marburg, Germany)² at 38° C. for 48 hours in the presence of 10 g. of 15 gauge copper wire per 200 ml. of solution. The slides were rinsed gently in 3 changes of distilled water for 2 minutes, 1 minute and 1 minute, respectively, and reduced in 1% hydroquinone and 5% sodium sulfite for 5 minutes. They were washed 5 minutes in tap water and 5 minutes in 2 changes of distilled water and toned 3-5 minutes in 0.25% gold chloride, rinsed in distilled water 10 seconds, reduced 10 seconds in 1 % oxalic acid, rinsed 1 minute, fixed in 5% sodium thiosulfate 5 minutes, washed in tap water through 3 changes, dehydrated, cleared and covered. All solutions were made with distilled water except where otherwise specified. The results gave good impregnation of fine nerve fibers without the usual confusing staining of reticular tissue.     

Silver Protein Staining of Nerve Fibers in Celloidin Sections

Celloidin sections from formalin-fixed brain and spinal cord of primates are stored in 70% alcohol after cutting, soaked in 2% pyridine in 50% alcohol for 6-8 hr at 37 C, and transferred to 1% concentrated NH₄OH in 50% alcohol 15-18 hr at 20-25 C. After washing and flattening, the sections are transferred to 1% silver protein solution containing 30 ml of 0.2 M H₃BO₃/100 ml. Impregnation is accomplished in 50 ml screw-top jars, 50 mm in diameter, which are filled to a depth of 35 mm, and have 1 gm of copper foil, 0.002 inch thick added. The foil is folded in loose accordion-fashion, pierced and threaded, cleaned in 5% HNO₃, rinsed in distilled water, and suspended in the solution just above the sections by fastening the thread to the jar lid. The sections are impregnated for 24 hr at 37 C, rinsed in distilled water, reduced in a solution of 5% Na₂SO₃ and 1% hydroquinone for 10 min, washed in distilled water and toned in 0.2% gold chloride for 5 min. After rinsing in distilled water, the sections are transferred to 1% oxalic acid for 45-60 sec, washed in distilled water and placed in 5% Na₂S₂O₃ for 5 min. Sections are then washed, dehydrated to 95% alcohol, cleared in terpineol, followed by 3 changes in xylene, and mounted.     

Differential Impregnation of Degenerating Nerve Fibers in Paraffin-Embedded Material

The silver method of Nauta and Gygax (1951) has been used on paraffin embedded material to give a result closely comparable to that obtained by Nauta and Gygax (1954) on frozen sections. It has been found that pyridine plays an important part in suppressing the impregnation of normal fibers in paraffin embedded material and that this sup pression can be augmented by the use of some of the higher methylated derivatives of pyridine, particularly 2,4,6-trimethyl pyridine (collidine).     

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.