The Golgi-Hortega-Lavilla Technique, with a Useful Additional Step for Application to Brain Tissue After Prolonged Fixation

The Golgi-Hortega-Lavilla silver impregnation technique was successfully applied to brain slices of various species that had been fixed for six to 24 months in a glutaraldehyde-paraformaldehyde fixative. The procedure is described in detail. Aside from being able to use material after prolonged fixation, the technique has the following advantages: 1) the impregnation is stable and yields constant results at all levels of the central nervous system, and 2) contrast is enhanced because any background precipitate that forms during staining is cleared with potassium cyanide. The possibility of using this method on material held in fixative for even longer periods is suggested.     

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.     

Formalin-Chloride Fixation to Improve Silver Impregnation of the Golgi Apparatus

The addition of a 1% concentration of alkaline earth or heavy metal chloride to a 15% neutral formalin solution was found to be much superior to a similar addition of nitrate. Of the 19 salts tried, BaCl₂ and CoCl₂ generally gave the best results with the tissues of Pheretima posthuma, Pila globosa, Rana tigrina, Cauia porcellus and Mus rattus. The CoCl₂ fixative was found to work more successfully with shorter time for fixation and subsequent impregnation by silver, than da Fano's cobalt nitrate technique. The results obtained with BaCl₂ fixative, were equally good and in some cases even excelled those obtained with Aoyama's CdCl₂. Fixatives containing MgCl₂ and ZnCl₂ were satisfactory but the results were not so good as were those obtained with barium and cobalt chloride fixatives. Fixatives containing nitrates generally required longer periods for impregnation and reduction, than those containing chlorides.     

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.     

An improved combined cholinesterase stain and silver impregnation method for quantitative analysis of innervation patterns in frog muscle

The original method combining Karnovsky's cholinesterase stain and Bodian silver impregnation has been modified to stain both myelinated and unmyelinated axons and to reduce background staining. The improvements were obtained by adding nitric acid to a paraformaldehyde-acetone fixative and by carrying out the silver impregnation of axons in an alcoholic solution. The method is especially suitable for quantitative estimation of the different kinds of nerve sprouting as well as for study of the remodeling of neuromuscular junctions in normal and experimental frog muscles.     

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.     

The development of a new technology for controlled cell fixation. A methodological pilot study.

Fixation in a traditional sense means the immersion of biological material into a chemical fluid. For permanent preservation (1) the fixative is always supplied in excess of the cell sample, and (2) the process of fixation is influenced by chemical impurities of the fixative fluid. Both factors influence the subsequent staining of cells. In order to avoid these uncontrolled influences, a new technology for controlled cell fixation has to be developed, whereby freshly prepared formaldehyde gas in an "inert" gas-flow of helium was applied to thin membranes by use of a capillary flow-in technique. The amount of fixative gas supplied, adsorbed, absorbed, diffused, and desorbed after saturation of the membranes could be reliably measured with an on-line operating "inert" mass spectrometer of the Omegatron type.     

Mapping of experimental axon degeneration by electron microscopy of golgi preparations

Summary For the mapping of the terminal area of transected axons within the central nervous system, electron microscopy has recently been adopted. A greater accuracy is thereby obtained than with silver impregnation and light microscopy, since it becomes possible to determine the kinds of structure (soma, dendrites, spines) with which the degenerating boutons establish synaptic contact. In the present study this technique was extended by Golgi impregnation of such material with the aim of making possible classification of the postsynaptic neuron. A few days after transection of a pathway (commissural fibres to the hippocampus being used as a model in this study) the brain was fixed by perfusion with phosphate buffered formalin with sucrose. This was followed by immersion in an osmium tetroxide-potassium dichromate mixture (Dalton's fixative without sodium chloride) later replaced by a solution of silver nitrate. Satisfactory Golgi impregnation of nerve cells and processes was obtained. By careful trimming, and reembedding of selected areas, blocks for ultramicrotomy could be obtained which contained only one type of impregnated cell, e.g., hippocampal pyramidal cells.The relation of basal dendrites of such cells to degenerating boutons of commissural fibres was studied. Numerous examples of contact between degenerating boutons and spines belonging to the basal dendrites were seen. Although the Golgi precipitate obscured the postsynaptic substance in the spines, a number of features at the sites of contact were considered strong indication that many of the contacts were synapses and not merely the result of random juxtaposition. This combined procedure is supposed to be applicable to other problems and to other parts of the nervous system as well.This study was supported in part by Grant NB 02215 from the National Institute of Neurological Diseases and Blindness, U.S. Public Health Service. This ais is gratefully acknowledged. The author is indebted to Mrs. J. L. Vaaland and Mr. B. V. Johansen for valuable technical assistance.     

A Silver Impregnation Technique for Normal Axons in the Human Central Nervous System for Celloidin and Epon Sections, with Substitutes for Soft Tap Water

An improved silver technique has been developed for human CNS axons in sections from celloidin blocks that resist impregnation because of prolonged storage in alcohol. This method also gives consistently good impregnation of recently fixed material, and thus is suitable for routine use. Slightly modified, the method is also successful with osmicated Epon embedded sections. The quality of silver impregnation in methods using tap water in the reducing solutions varies in different laboratories. Having established that hard water is essential, substitutes for soft water were sought and found.     

A silver impregnation technique for normal axons in the human central nervous system for celloidin and epon sections, with substitutes for soft tap water

An improved silver technique has been developed for human CNS axons in sections from celloidin blocks that resist impregnation because of prolonged storage in alcohol. This method also gives consistently good impregnation of recently fixed material, and thus is suitable for routine use. Slightly modified, the method is also successful with osmicated Epon embedded sections. The quality of silver impregnation in methods using tap water in the reducing solutions varies in different laboratories. Having established that hard water is essential, substitutes for soft water were sought and found.     

Staining Formalin-Fixed Nerve Tissue with Mercuric Nitrate

Experiments were made to test the impregnating effect of Hg(NO₃)₂ on nervous tissue that had been fixed and chromated with solutions of known pH. Brains of cats, kittens, rats and mice were fixed by the pulsating-perfusion method of Haushalter and Bertram (1955), after first washing out the blood with saline-acacia solution, at pH 7.0, then followed by a 10% formol-saline-acacia fixative of the same pH. The removed brains were sliced to 3 mm thickness and further fixed 1-2 days in 10% formalin whose pH was also adjusted to 7.0. Chromation with acidified ZnCrO₄ at pH 3.1 for 1 day followed by impregnation for 2 days in a saturated solution of Hg(NO₃)₂ at pH 5.5-6.0 effected the staining. Dehydration, paraffin embedding and sectioning completed the process. Some moderately successful stains were made with mercuric salts with no chromation, but it was found that fixation at pH 7.0-7.2 followed by chromation at pH 3.1, and later by impregnation in Hg(NO₃)₂ at pH 5.8-6.0 was optimum for best staining of nerve cells for their processes. The advantages of the technique are: (1) selective staining of nerve cells, especially the axonic details; and (2) a relatively short time needed for its completion.     

OBSERVATIONS ON FIBRILLOGENESIS IN THE CONNECTIVE TISSUE OF THE CHICK EMBRYO WITH THE AID OF SILVER IMPREGNATION

A technique is described which combines silver impregnation and ultrathin sectioning for the electron microscopic demonstration of fibrils in the connective tissue of the chick embryo. The electron micrographs presented in this paper provide evidence for the specificity and completeness of the silver-impregnation technique. It has been shown that, in this particular tissue after fixation in neutral formalin and at the stage of development represented by our material, the argyrophil fibers are embedded in a material which is continuous with the body of the fibroblasts.     

An impregnation technique for studying distribution of mitochondria in central nervous system

Summary An impregnation technique for demonstration of mitochondria in central nervous system has been described. Formol perfused material is being chromated, embedded in paraffin and impregnated with a modified Nauta's method. The reaction is specific since reduced silver particles are deposed within the matrix of mitochondria. Phenomenon of complete and incomplete impregnation is discussed. Mitochondria in perikarya of neurons, dendrites and glia tend to be unstained if the impregnation is incomplete, while axonic and praesynaptic ones are labelled. In neuropil of different regions of the brain various types of mitochondrial aggregates appear in complete impregnation. The method may be a valuable tool for studying brain architecture and synaptology.With a grant of Alexander von Humboldt-Stiftung at the II. Institute of Anatomy, Berlin.     

Perfusion Method for Preparing Pig Brain Cortex for Golgi-Cox Impregnation

The perfusion procedure described in this paper produces high quality impregnation of pig visual and somatosensory cortical neurons with a Golgi-Cox solution. Starting within 30 min after death, pig heads were perfused with a fixative solution composed of a mixture (v/v) of liquid phenol, 5%; formalin, 14%; ethylene glycol, 25%; methanol, 28%; and water, 28% for two periods of 4 hr each. After perfusion, the heads were chilled for at least 18 hr. The entire brain was removed from the skull and then placed in 10% buffered formalin, where it remained for at least 10 days before taking the blocks that were to be immersed in the Golgi-Cox solution. Three weeks spent in the Golgi-Cox solution typically produced uniform neuron impregnation. The tissue blocks were then embedded in celloidin and sectioned at 120 μm. This procedure avoids the following difficulties: Golgi-Cox methods that produced excellent results with rodent or primate tissue were unsuccessful with pig tissue, placing fresh tissue in Golgi-Cox solution resulted in incomplete neuron impregnation, and immersion fixation in 10% buffered formalin without perfusion resulted in excessive staining of glia.     

Value of the filter imprint technique in aspiration biopsy cytology

In 468 fine needle aspiration (FNA) biopsies, after smearing of the aspirate on glass slides, additional material was obtained by flushing the needle with a fixative. The cells were collected on Millipore filters, from which imprints were prepared. The filter imprints were found to be sufficiently cellular in 60% of the cases, which reduced by 33 (7.3%) the number of cases with unsatisfactory aspirates. Diagnostic specificity and sensitivity were not influenced by the technique. The filter imprint technique was of particular value in breast aspirates.     

Perfusion method for preparing pig brain cortex for Golgi-Cox impregnation

The perfusion procedure described in this paper produces high quality impregnation of pig visual and somatosensory cortical neurons with a Golgi-Cox solution. Starting within 30 min after death, pig heads were perfused with a fixative solution composed of a mixture (v/v) of liquid phenol, 5%; formalin, 14%; ethylene glycol, 25%; methanol, 28%; and water, 28% for two periods of 4 hr each. After perfusion, the heads were chilled for at least 18 hr. The entire brain was removed from the skull and then placed in 10% buffered formalin, where it remained for at least 10 days before taking the blocks that were to be immersed in the Golgi-Cox solution. Three weeks spent in the Golgi-Cox solution typically produced uniform neuron impregnation. The tissue blocks were then embedded in celloidin and sectioned at 120 micron. This procedure avoids the following difficulties: Golgi-Cox methods that produced excellent results with rodent or primate tissue were unsuccessful with pig tissue, placing fresh tissue in Golgi-Cox solution resulted in incomplete neuron impregnation, and immersion fixation in 10% buffered formalin without perfusion resulted in excessive staining of glia.     

The Use of Lanthanum Chloride as a Marker for Intercellular Junctions in Rat Exocrine Pancreas

A simple technique of perfusion and immersion of tissue in fixative containing lanthanum chloride as an extracellular tracer is described. In addition to functioning as a tracer, the lanthanum chloride appears to enhance electron staining. In rat exocrine pancreas, intercellular spaces between exocrine and centroductular cells were outlined clearly by electron dense material and, at cellular interfaces, spot desmosomes, gap junctions, and tight junctions were demonstrated. The technique proved simple and effective and should prove useful in studies of epithelial and other tissues.     

The use of lanthanum chloride as a marker for intercellular junctions in rat exocrine pancreas

A simple technique of perfusion and immersion of tissue in fixative containing lanthanum chloride as an extracellular tracer is described. In addition to functioning as a tracer, the lanthanum chloride appears to enhance electron staining. In rat exocrine pancreas, intercellular spaces between exocrine and centroductular cells were outlined clearly be electron dense material and, at cellular interfaces, spot desmosomes, gap junctions, and tight junctions were demonstrated. The technique proved simple and effective and should prove useful in studies of epithelial and other tissues.     

Limitations in the measurement of c-myc oncoprotein and other nuclear antigens by flow cytometry

Recent developments in cell fixation, quantitative immunocytochemistry, and flow cytometry allow for the quantification of a variety of oncoproteins and other proliferation-associated antigens in both fresh and archival pathology material. These studies provide evidence that the standard tissue deparaffinization/dissociation technique significantly reduces the amount of c-myc oncoprotein remaining for analysis. To examine the factor(s) responsible for this observation, individual variables of the deparaffinization/dissociation technique including type of fixative, pepsin concentration, pepsinization times, pH, and exposure to organic solvents were examined in HeLa-S3 cells. The cells were stained with monoclonal antibodies either to the c-myc oncoprotein or to p105, a prolifera-tion-associated nuclear antigen. Protein-levels were measured on the basis of anti-c-myc or anti-p105 immunofluorescence by flow cytometry and were found not be affected significantly by type of fixative, exposure to organic solvents, acid pH solution, or mechanical disruption. Levels of c-myc oncoprotein were reduced by over 50%, however, when cells were exposed to 0.5% pepsin, whereas p105 was more resilient with only an approximately 7% reduction following the same treatment. Thus, careful examination of aspects of the deparaffinization/dissociation technique appears to be a necessary prerequisite for quantification of specific nuclear proteins from dissociated tissue specimens.