Assessment of Demyelination in Glycol Methacrylate Sections: A New Protocol for Cresyl Fast Violet Staining

A simple staining technique for nervous tissue is described. Tissue perfused with glutaraldehyde and formaldehyde and postfixed with osmium tetroxide is embedded in glycol methacrylate. One-micrometer sections are stained with 0.05% cresyl fast violet aqueous solution at 60 C for 5 min, washed with tap water and air dried. With this method the details of all nervous tissue elements are clearly demonstrated. The technique is particularly useful for assessing demyelination because the staining of axoplasm allows demyelinated axons to be well visualized.     

Protocol for the combination of neurohistological techniques on vibratome obtained sections

Introduction. The histological study of the nervous system requires the use of special techniques. Currently, no methods are available to visualize simultaneously all the cellular constituents of nervous tissue. Objectives. A protocol was adapted for staining nervous tissue by modification of a formerly difficult procedure. Materials and methods. Slices of brain and spinal cord, 4 mm thick, were taken from adult mice, previously fixed by intracardiac perfusion with 4% paraformaldehyde. Vibratome sections were obtained with thickness of 15-25 μm. These were mounted on glass slides prepared with gelatin as an adhesive. The preparations were subjected to staining protocol Luxol Fast Blue-PAS-hematoxylin (LPH) combined with silver staining method (LPH-Holmes). Results. LPH technique yielded an excellent differentiation of gray and white matter in all regions of the nervous system. A panoramic view of the gray matter was colored pink in contrast to the myelinated nerve fibers and tracts which were light blue. The combination LPH-Holmes retained the staining characteristics but significantly improved the demarcation of axons and tracts. Conclusions. A protocol was standardized for the LPH and LPH-Holmes nervous tissue stains applied in combination to tissue slices obtained with a vibratome. The method was shorter, less wasteful and less expensive than the original and also better preserved the integrity of nervous tissue.     

An Improved Silver Stain for Developing Nervous Tissue

A reduced silver technique using physical development to stain embryonic nervous tissue is described. Brains are fixed in Bodian's fixative. Paraffin sections are pretreated with 1% chromic acid or 5% formol. They are impregnated with 0.01% silver nitrate dissolved in 0.1 M boric acid/sodium tetraborate buffer of pH 8 or with silver proteinate. Finally they are developed in a special physical developer which contains 0.1% silver nitrate, 0.01-0.l% formol as developed agent, 25% sodium carbonate to buffer the solution at pH 10.3, 0.1% ammonium nitrate to prevent precipitation of silver hydroxide, and 5% tungstosilicic acid as a protective colloid. The development takes several minutes in this solution, thus the intensity of staining can be controlled easily. The method yields uniform, complete and reproducible staining of axons at all developmental stages of the nervous tissue and is easy to handle.     

An improved silver stain for developing nervous tissue.

A reduced silver technique using physical development to stain embryonic nervous tissue is described. Brains are fixed in Bodian's fixative. Paraffin sections are pretreated with 1% chromic acid or 5% formol. They are impregnated with 0.01% silver nitrate dissolved in 0.1 M boric acid/sodium tetraborate buffer of pH 8 or with silver proteinate. Finally they are developed in a special physical developer which contains 0.1% silver nitrate, 0.01-0.1% formol as reducing agent, 2.5% sodium carbonate to buffer the solution at pH 10.3, 0.1% ammonium nitrate to prevent precipitation of silver hydroxide, and 5% tungstosilicic acid as a protective colloid. The development takes several minutes in this solution, thus the intensity of staining can be controlled easily. The method yields uniform, complete and reproducible staining of axons at all developmental stages of the nervous tissue and is easy to handle.     

Paraffin sections of nervous tissue supravitally stained with methylene blue: a new, reliable and simple fixation technique

Two steps are recommended for fixation of central nervous tissue after supravital staining with methylene blue: application of ammonium heptamolybdate followed by a paraformaldehyde-glutaraldehyde mixture. The two fixatives complement each other so that both dye and tissue are optimally fixed. Molybdate renders the dye water and alcohol insoluble, the aldehyde mixture conditions the tissue for embedding in paraffin. This technique is a suitable alternative to conventional whole mount and frozen sectioning methods.     

Paraffin Sections of Nervous Tissue Supra Vitally Stained with Methylene Blue: A New, Reliable and Simple Fixation Technique

TWO steps are recommended for fixation of central nervous tissue after supravital staining with methylene blue: application of ammonium heptamolybdate followed by a paraformaldehyde-glutaraldehyde mixture. The two fixatives complement each other so that both dye and tissue are optimally fixed. Molybdate renders the dye water and alcohol insoluble, the aldehyde mixture conditions the tissue for embedding in paraffin. This technique is a suitable alternative to conventional whole mount and frozen sectioning methods.     

Immunocytochemical localization of a chondroitin sulfate proteoglycan in nervous tissue. I. Adult brain, retina, and peripheral nerve

Monospecific antibodies were prepared to a previously characterized chondroitin sulfate proteoglycan of brain and used in conjunction with the peroxidase-antiperoxidase technique to localize the proteoglycan by immunoelectron microscopy. The proteoglycan was found to be exclusively intracellular in adult cerebellum, cerebrum, brain stem, and spinal cord. Some neurons and astrocytes (including Golgi epithelial cells and Bergmann fibers) showed strong cytoplasmic staining. Although in the central nervous system there was heavy axoplasmic staining of many myelinated and unmyelinated fibers, not all axons stained. Staining was also seen in retinal neurons and glia (ganglion cells, horizontal cells, and Muller cells), but several central nervous tissue elements were consistently unstained, including Purkinje cells, oligodendrocytes, myelin, optic nerve axons, nerve endings, and synaptic vesicles. In sympathetic ganglion and peripheral nerve there was no staining of neuronal cell bodies, axons, myelin, or Schwann cells, but in sciatic nerve the Schwann cell basal lamina was stained, as was the extracellular matrix surrounding collagen fibrils. Staining was also observed in connective tissue surrounding the trachea and in the lacunae of tracheal hyaline cartilage. These findings are consistent with immunochemical studies demonstrating that antibodies to the chondroitin sulfate proteoglycan of brain also cross-react to various degrees with certain connective tissue proteoglycans.     

Poor reliability of immunocytochemical localization of IgG in immersion-fixed tissue from the central nervous system.

The effect of fixation technique and post mortem-to-fixation interval in immersion-fixed tissue from the central nervous system on immunocytochemical staining for the presence of an immunoglobulin was determined in mice. Immersion-fixed tissue was found to be inferior to perfusion-fixed tissue for immunocytochemical staining of this serum protein. Unlike what has been observed for other antigens, the quality of staining for IgG in immersion-fixed tissue decreased to unacceptable levels if the post mortem-to-fixation interval was increased to more than a few hours. This effect may be secondary to the rapid post-mortem disintegration of the blood-brain barrier and a resulting diffusion of serum proteins into surrounding tissue from the vasculature.     

The histochemical localisation of aminopeptidases in the central nervous system and an analysis of factors contributing to the final staining pattern

Summary A method is described for the localisation of aminopeptidases in the central nervous system. The enzymatic cleavage of the peptide bond in the substituted naphthylamide substrates results in the liberation of free naphthylamine which in the presence of an azo salt can be precipitated as a blue dye at sites of enzyme activity. Analysis of different brain regions using this technique indicates that these enzymes may have a specific function at certain sites in the CNS. Since this is the first method to produce any localised staining in nervous tissue an analysis of factors contributing to the final staining pattern is also presented.     

The histochemical localisation of aminopeptidases in the central nervous system and an analysis of factors contributing to the final staining pattern.

A method is described for the localisation of aminopeptidases in the central nervous system. The enzymatic cleavage of the peptide bond in the substituted naphthylamide substrates results in the liberation of free naphthylamine which in the presence of an azo salt can be precipitated as a blue dye at sites of enzyme activity. Analysis of different brain regions using this technique indicates that these enzymes may have a specific function at certain sites in the CNS. Since this is the first method to produce any localised staining in nervous tissue an analysis of factors contributing to the final staining pattern is also presented.     

An autometallographic technique for myelin staining in formaldehyde-fixed tissue

A new autometallographic (AMG) technique for staining myelin in formaldehyde- or paraformaldehyde- (PFA) fixed tissue is presented. The tissue sections were exposed to AMG development without prior treatment with silver salts. The method was examined on PFA-fixed tissue from mouse, rat, pig, and formaldehyde-fixed human autopsy material. Samples from brain, spinal cord, cranial, and spinal nerves were either cut on a vibratome, frozen and cryostat sectioned, or embedded and microtome sectioned, before AMG development and counterstaining. The AMG-myelin technique results in a specific black/dark-brown staining of myelin in all parts of the CNS and PNS. It works on all species examined, independent of the histological preparation techniques applied. The AMG staining is stable, stays unchanged through decades, allows counterstaining, and has previously been used with immunohistochemical techniques. On perfusion-fixed tissue the technique works without further fixation, but the intensity of the AMG-myelin staining is increased by increased postfixation time. Additionally, immersion fixation has to last for days depending on the size of the tissue block in order to obtain proper myelin staining. The most feasible explanation of the chemical events underlying the AMG-myelin technique is that nano-sized clusters of metallic silver are formed in the myelin as a result of chemical bounds with reducing capacity, exposed or created by the formaldehyde molecule. The AMG method is simple to perform and as specific as the conventional osmium and luxol fast blue stainings. The present technique is thus an effective, simple, inexpensive, and quick myelin staining method of formaldehyde- or PFA-fixed tissue.     

The use of backscattered electrons to examine selectively stained nerve fibers in the scanning electron microscope

Selective staining of neuronal tissues using standard light microscopic techniques has been combined with backscattered electron scanning electron microscopy. This technique allows neurons to be readily distinguished from their surrounding tissues and examined at high resolution. The technique overcomes some of the problems involved in scanning electron microscopy of nervous tissue in situ.     

The Use of Backscattered Electrons to Examine Selectively Stained Nerve Fibers in the Scanning Electron Microscope

Selective staining of neuronal tissues using standard light microscopic techniques has been combined with backscattered electron scanning electron microscopy. This technique allows neurons to be readily distinguished from their surrounding tissues and examined at high resolution. The technique overcomes some of the problems involved in scanning electron microscopy of nervous tissue in situ.     

Immunodetection of Outer Membrane Proteins by Flow Cytometry of Isolated Mitochondria

Methods to detect and monitor mitochondrial outer membrane protein components in animal tissues are vital to study mitochondrial physiology and pathophysiology. This protocol describes a technique where mitochondria isolated from rodent tissue are immunolabeled and analyzed by flow cytometry. Mitochondria are isolated from rodent spinal cords and subjected to a rapid enrichment step so as to remove myelin, a major contaminant of mitochondrial fractions prepared from nervous tissue. Isolated mitochondria are then labeled with an antibody of choice and a fluorescently conjugated secondary antibody. Analysis by flow cytometry verifies the relative purity of mitochondrial preparations by staining with a mitochondrial specific dye, followed by detection and quantification of immunolabeled protein. This technique is rapid, quantifiable and high-throughput, allowing for the analysis of hundreds of thousands of mitochondria per sample. It is applicable to assess novel proteins at the mitochondrial surface under normal physiological conditions as well as the proteins that may become mislocalized to this organelle during pathology. Importantly, this method can be coupled to fluorescent indicator dyes to report on certain activities of mitochondrial subpopulations and is feasible for mitochondria from the central nervous system (brain and spinal cord) as well as liver.     

Time-Gated Optical Projection Tomography Allows Visualization of Adult Zebrafish Internal Structures

Optical imaging through biological samples is compromised by tissue scattering and currently various approaches aim to overcome this limitation. In this paper we demonstrate that an all optical technique, based on non-linear upconversion of infrared ultrashort laser pulses and on multiple view acquisition, allows the reduction of scattering effects in tomographic imaging. This technique, namely Time-Gated Optical Projection Tomography (TGOPT), is used to reconstruct three dimensionally the internal structure of adult zebrafish without staining or clearing agents. This method extends the use of Optical Projection Tomography to optically diffusive samples yielding reconstructions with reduced artifacts, increased contrast and improved resolution with respect to those obtained with non-gated techniques. The paper shows that TGOPT is particularly suited for imaging the skeletal system and nervous structures of adult zebrafish.     

A combined silver and acetylcholinesterase method for staining intramuscular innervation.

A combined acetylcholinesterase and silver stain for demonstrating the intramuscular innervation of fresh frozen tissue is described. Intramuscular nerves, subterminal axons, and motor end plates are simultaneously stained brown or black with minimal staining of connective tissue and muscle fibers in longitudinal sections 30-100 mu thick. The method has been applied to fetal and adult rat, porcine, and bovine skeletal muscle. Antemortem and postmortem tissue samples stained equally well. The method facilitates simultaneous appreciation of morphological alterations in nervous and muscular tissues; in clinical and research laboratories alike it is of value when muscle abnormalities which may be related to disorders of nervous origin are studied. Compared with other published procedures this method has shorter time requirements, uses fresh frozen tissue, and displays superior staining characteristics.     

A Combined Silver and Acetylcholinesterase Method for Staining Intramuscular Innervation

A combined acetylcholinesterase and silver stain for demonstrating the intramuscular innervation of fresh frozen tissue is described. Intramuscular nerves, subterminal axons, and motor end plates are simultaneously stained brown or black with minimal staining of connective tissue and muscle fibers in longitudinal sections 30-100 μ thick. The method has been applied to fetal and adult rat, porcine, and bovine skeletal muscle. Antemortem and postmortem tissue samples stained equally well. The method facilitates simultaneous appreciation of morphological alterations in nervous and muscular tissues; in clinical and research laboratories alike it is of value when muscle abnormalities which may be dated to disorders of nervous origin are studied. Compared with other published procedures this method has shorter time requirements, uses fresh frozen tissue, and displays superior staining characteristics.     

Immunocytochemical detection of sulphonylated DNA in tissue sections. An alternative to Feulgen staining of DNA

We report here on a new sensitive and highly specific DNA staining technique which we have called sulpho-DNA staining. DNA staining is based on a sulphonylation reaction of 2'-deoxycytidine or cytidine that takes place in the 6th position of cytosine with ensuing immunodetection of the sulphonylated DNA. The specificity of DNA staining is introduced by the use of an antibody recognizing only modified DNA but not modified RNA, by recourse to an additional acid hydrolysis step which destroys RNA but not DNA. We describe here the optimal conditions for the sulphonylation of DNA using O-methylhydroxylamine and metabisulphite as reactants. The new DNA stain labels all nuclei in either normal human tissue or in tumor cells. For nuclear DNA the staining signal is higher for the sulpho-DNA staining than for the Feulgen staining for nuclear DNA. This new DNA staining technique is suitable for use on tissue sections as well as on cytosmears.     

The PASDORO method for simultaneously demonstrating DNA and lipids in the brain

Conclusions and summary The PASDORO method has the advantage of allowing DNA and globular lipid to be demonstrated in frozen sections of formalin-fixed tissue. Its disadvantage is that, in most tissues, basement membrane staining interferes with the selective demonstration of DNA. However, in the central nervous system it is advantageous to be, able to trace capillary basement membrane. In this way cells related to the capillary endothelium can be easily identified. The addition of staining with Oil Red O to the basic PASD technique permits lipid-laden microglia to be readily identified around necrotic and demyelinating lesions.     

LR Gold embedding of nervous tissue for immunoelectron microscopy studies.

A major drawback of all acrylic resins commonly used for post-embedding immunocytochemical studies of the central nervous system is the disruption of the ultrastructural morphology, due to the high lipid content of neural tissue. We have investigated the suitability of the acrylic resin LR Gold, which has been employed recently for immunogold labeling studies in several non-neural tissues. Optimal preservation of both antigenicity and ultrastructure of nervous tissue was obtained after en bloc staining with uranyl acetate, followed by total dehydration in acetone and curing at low temperature. Cell membranes and myelin sheaths, which are usually lost with other acrylic resins, were well maintained. The degree of antigenicity of LR Gold-embedded tissues was comparable to that of LR White-embedded one, but the morphologic detail was much better preserved. The use of LR Gold is particularly advantageous for studying neurodegenerative disorders such as Alzheimer disease.