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.     

Complete Staining of Nerve Fiber and Myoneural Junctions with Acetylthiocholine and Silver

We describe a combined stain for simultaneous demonstration of the preterminal axons and cholinesterase activity at myoneural junctions of mammalian muscles. This technique employs acetylthiocholine iodide as the substrate for cholinesterase activity and silver nitrate impregnation of preterminal axons. The procedure is rapid, simple and Uses fresh muscles. Intramuscular nerves, preterminal axons and myoneural junctions are stained simultaneously brown or black with minimal background staining of connective tissue and muscle fibers.     

Complete Staining of Nerve Fiber and Myoneural Junctions with Acetylthiocholine and Silver

We describe a combined stain for simultaneous demonstration of the preterminal axons and cholinesterase activity at myoneural junctions of mammalian muscles. This technique employs acetylthiocholine iodide as the substrate for cholinesterase activity and silver nitrate impregnation of preterminal axons. The procedure is rapid, simple and Uses fresh muscles. Intramuscular nerves, preterminal axons and myoneural junctions are stained simultaneously brown or black with minimal background staining of connective tissue and muscle fibers.     

The Differentiated Silver Impregnation of Certain Conducting Pathways in the Peripheral Nervous System

Feti of man, rabbit and mouse can be silver-impregnated in such a way that different kinds of nerve-fiber pathways in the peripheral nervous system are distinguishable from one another by different degrees of impregnation intensity. In the application of Bielschowsky's technic, it is important that the impregnation time in silver nitrate should be tested with respect to the species in question. This time is for man 6 weeks, for rabbit 3 weeks and for mouse 2–3 days.     

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.     

Silver impregnation methods for reticulum fibers and reticulin: A re-investigation of their origins and specifity

Summary Maresch (1905) introduced Bielschowsky's silver impregnation technic for neurofibrils as a stain for reticulum fibers, but emphasized the nonspecifity of such procedures. This lack of specifity has been confirmed repeatedly. Yet, since the 1920's the definition of reticulin and studies of its distribution were based solely on silver impregnation technics. The chemical mechanism and specifity of this group of stains is obscure. Application of Gomori's and Wilder's methods to human tissues showed variations of staining patterns with the fixatives and technics employed. Besides reticulum fibers, various other tissue structures, e.g. I bands of striated muscle, fibers in nervous tissues, and model substances, e.g. polysaccharides, egg white, gliadin, were also stained. Deposition of silver compounds on reticulum fibers was limited to an easily removable substance; the remaining collagen component did not bind silver. These histochemical studies indicate that silver impregnation technics for reticulum fibers have no chemical significance and cannot be considered as histochemical technics for reticulin or type III collagen.     

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.     

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.     

Silver staining analysis on spermatozoa of Nucella lapillus (Gastropoda,Prosobranchia)

Summary

Sperm of Nucella lapillus was studied by electron microscopy, including the application of a cytochemical silver method. Using silver impregnation a dense precipitation of Ag granules in spermatocyte II nucleoli was seen over the fibrillar component and a slight one in the granular component. On longitudinal sections of the spermatozoon the results demonstrate that argyrophilic proteins are located in the external limiting zone of the acrosome in the anterior portion of the nucleus between the cytoplasmic and the nuclear membranes, in the posterior end of the nucleus and in the terminal portion of the middle region. These data indicate an affinity for silver in areas of the cytoplasm containing microtubules and in zones of transition.     

Silver Impregnation of Peripheral and Central Axons

A silver impregnation method suitable for peripheral and central nervous system axons is described. Essential features are the use of reagent grade chemicals only, a pretreatment solution to ensure optimal impregnation of different organs from different animals and species, and an unvarying procedure. The results are compared to those obtainable with a number of current impregnation methods and with modern immunocytochemical reactions.     

Silver staining of proteins in polyacrylamide gels

Silver staining is used to detect proteins after electrophoretic separation on polyacrylamide gels. It combines excellent sensitivity (in the low nanogram range) with the use of very simple and cheap equipment and chemicals. It is compatible with downstream processing, such as mass spectrometry analysis after protein digestion. The sequential phases of silver staining are protein fixation, then sensitization, then silver impregnation and finally image development. Several variants of silver staining are described here, which can be completed in a time range from 2 h to 1 d after the end of the electrophoretic separation. Once completed, the stain is stable for several weeks.     

Silver impregnation of peripheral and central axons

A silver impregnation method suitable for peripheral and central nervous system axons is described. Essential features are the use of reagent grade chemicals only, a pretreatment solution to ensure optimal impregnation of different organs from different animals and species, and an unvarying procedure. The results are compared to those obtainable with a number of current impregnation methods and with modern immunocytochemical reactions.     

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 Differentiated Silver Impregnation of Certain Conducting Pathways in the Peripheral Nervous System

Feti of man, rabbit and mouse can be silver-impregnated in such a way that different kinds of nerve-fiber pathways in the peripheral nervous system are distinguishable from one another by different degrees of impregnation intensity. In the application of Bielschowsky's technic, it is important that the impregnation time in silver nitrate should be tested with respect to the species in question. This time is for man 6 weeks, for rabbit 3 weeks and for mouse 2-3 days.     

Silver Methenamine Staining for Scanning Electron Microscopy of Bone Sections Containing Biomaterials

Sections of tissue containing orthopedic materials are currently used to study the compatibility of those materials and to perform electron probe microanalysis at the material-tissue interface. Identification of the cells in contact with the material by Scanning electron microscopy (SEM) is of interest. We have developed a method for staining cells and tissue structures embedded in polymethyl methacrylate with silver methenamine once the sections have been obtained. Sections were prepared by grinding, and the silver methenamine was applied after oxidation with periodic acid. The procedure was carried out in a microwave oven. Backscatter SEM showed staining of the cell nucleus membrane, chromatin, the nuclear organizers, and the chromosomes of dividing cells. The cytoplasm and the cytoplasmic membrane were also stained. Collagen fibers of the extracellular matrix and the mineralized matrix of bone were labeled. Material particles in the macrophages were easily recognizable and Energy-Dispersive Spectrometer were not impaired by the presence of silver in the preparation.     

Effects of Oxidation on Neurofibrillar Argyrophilia

The effect of oxidation on neurofibrillar argyrophilia was studied by subjecting nervous tissues containing both normal and degenerating fibers to the action of potassium permanganate, periodic acid, chromic acid, lead tetraacetate, and sodium bismuthate prior to silver impregnation. The argyrophilic response of normal fibers to such treatment was studied with the Nonidez silver nitrate block technic, the double impregnation method of Bielschowsky on both blocks and sections, and a silver proteinate procedure. The response of degenerating fibers was studied by the Cajal formula 6 block technic and the modified Bielschowsky procedure of Nauta and Ryan for sections. The experimental data indicated that such oxidation did not produce any differential staining effects between normal or degenerating fibers.     

银纳米粉体制备研究的进展

介绍了在银纳米粉体制备中所采用的几种主要方法以及各种方法的优缺点。指出了目前研究中存在的问题,并对今后的研究进行了展望。     

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.     

A Method for Silver Impregnation of Mammary Myoepithelia

Histochemical methods for microscopic visualization of nummary 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.