Effects of fixation and processing on the immunohistochemical visualization of type-I, -III and -IV collagen in paraffin-embedded liver tissue

Summary We compared the effects of different fixatives and enzymatic-digestion procedures on the immunohistochemical visualization of type-I,-III and-IV collagen in paraffin-embedded normal human liver sections. None of the fixatives tested allowed the staining of these antigens without prior enzymatic digestion. The best results i.e. strong staining intensity and well-defined localization, were obtained when liver tissue was fixed in Bouin's fluid or in other solutions containing picric acid. Several other fixatives, including Carnoy's fluid, Lillie's AAF, 10% neutral formalin and 96% ethanol, gave unsatisfactory results. Pepsin was ineffective for unmasking type-I and-III collagen antigens, and was only partially effective for visualizing the type-IV collagen antigen. The best results were obtained when material fixed in Bouin's fluid was embedded in paraftin and digested with trypsin. Using this procedure, the results were comparable to those obtained in unfixed frozen sections with respect to the staining intensity, specificity and non-specific staining.     

The influence of fixation and tissue preparation on the immunohistochemical demonstration of fibronectin in human tissue

The influence of fixation and tissue preparation on the immunohistochemical localization of human fibronectin in gastrointestinal tract tissue has been examined using indirect immunoperoxidase technique. The most optimal staining result with strong intensity and well defined localization was obtained on frozen sections of unfixed material. Nearly identical results with improved morphology were obtained when staining paraffin sections of tissue fixed in 96% ethanol, 96% + 1% acetic acid and absolute acetone. All other fixatives tested, 10% neutral buffered formalin. Lillie's AAF, Bouin's fixative, Clarke's fixative, 4% formaldehyde, 4% formaldehyde + 0.5% cetylpyridiniumchloride (F-CPC), 4% formaldehyde +0.1% glutaraldehyde gave unsatisfactory results. However, proteolytic digestion with pepsin of paraffin sections prior to staining of buffered formalin and F-CPCfixed material gave results comparable with those obtained on unfixed frozen sections are regards definition of the staining whereas staining intensity was decreased in some degree. No improvement was observed when using proteolytic digestion of tissue fixed in other fixatives.     

The influence of fixation and tissue preparation on the immunohistochemical demonstration of fibronectin in human tissue

Summary The influence of fixation and tissue preparation on the immunohistochemical localization of human fibronectin in gastrointestinal tract tissue has been examined using indirect immunoperoxidase technique. The most optimal staining result with strong intensity and well defined localization was obtained on frozen sections of unfixed material. Nearly identical results with improved morphology were obtained when staining paraffin sections of tissue fixed in 96% ethanol, 96%+1% acetic acid and absolute acetone. All other fixatives tested, 10% neutral buffered formalin, Lillie's AAF, Bouin's fixative, Clarke's fixative, 4% formaldehyde, 4% formaldehyde+ 0.5% cetylpyridiniumchloride (F-CPC), 4% formaldehyde +0.1% glutaraldehyde gave unsatisfactory results. However, proteolytic digestion with pepsin of paraffin sections prior to staining of buffered formalin and F-CPCfixed material gave results comparable with those obtained on unfixed frozen sections as regards definition of the staining whereas staining intensity was decreased in some degree. No improvement was observed when using proteolytic digestion of tissue fixed in other fixatives.     

A Modified Turchini Technic for the Differential Staining of Nucleic Acids

The preparation of the 9-methyl-2,3,7-trihydroxy-6-fluorone reagent for the selective staining of both desoxyribose and ribose nucleic acids is described. With slight variations this method follows the Duckert (1937) modification of the Liebermann and Lindenbaum (1904) reaction.

The present modification of the Turchini et al. (1944) staining procedure has been used on human autonomic ganglia fixed in Bouin's fluid, rat tissues, fixed in Bouin's, Zenker's, formol and for-mol-saline fixatives and mouse liver frozen and dried. The modified Turchini method has been examined primarily for its qualitative reliability by means of the following procedure. Ribonuclease treated sections were compared with adjacent sections immersed in distilled water. In succeeding steps half of these sections were stained by the modified Turchini process and the other half by Einarsson's gallocyanin chrome alum. Evidence gleaned from this and other tests indicates that 9-methyl-2,3,7-trihydroxy-6-fluorone may be used for the selective staining of desoxyribose and ribose nucleic acids.     

Immunofluorescent Labelling of K-Papovavirus Antigens in Glycol Methacrylate Embedded Material: A Method for Studying Infected Cell Populations by Fluorescence Microscopy and Histological Staining of Adjacent Sections

Trypsin and protease V (pronase) were studied for their ability to enhance immuno-fluorescent labelling of papovavirus antigens in glycol methacrylate embedded sections of organs infected with murine K-papovavirus. Treatment of Bouin's fixed sections with 0.4% trypsin for 30 minutes resulted in specific immunofluorescent staining equal to that seen in frozen sections and produced little if any loss of histological detail. Treatment with protease V resulted in less brilliant fluorescence and less satisfactory tissue preservation. Studies were then conducted to determine the fixative which would produce brightest specific fluorescent antibody staining of papovavirus-infected cells while providing clearest definition of intranuclear inclusions and best morphological detail in histologically stained adjacent sections. Brightest immunofluorescence staining was accomplished on material fixed in 96% ethanol/1% glacial acetic acid or Bouin's solution. These fixatives also gave clear definition of intranuclear inclusions with histological stains and provided excellent morphological detail. Phosphate buffered paraformaldehyde/picric acid and 3.7% formalin gave less satisfactory fluorescence and obscured intranuclear inclusions in histological preparations. Sections fixed in 4% paraformaldehyde, 4% paraformaldehyde/1% glutaraldehyde, and 0.5 M p-toluenesulfonic acid were negative for specific fluorescence. Glycol methacrylate, used with proper fixation and trypsin pretreatment of sections, provides a useful embedding medium for immunofluorescent identification of virus-infected cells, and the 1.0-2.0 μm sections routinely obtainable with GMA permit study of individual infected cells by fluorescent antibody and histological staining of adjacent sections.     

Immunofluorescent labelling of K-papovavirus antigens in glycol methacrylate embedded material: a method for studying infected cell populations by fluorescence microscopy and histological staining of adjacent sections

Trypsin and protease V (pronase) were studied for their ability to enhance immunofluorescent labelling of papovavirus antigens in glycol methacrylate embedded sections of organs infected with murine K-papovavirus. Treatment of Bouin's fixed sections with 0.4% trypsin for 30 minutes resulted in specific immunofluorescent staining equal to that seen in frozen sections and produced little if any loss of histological detail. Treatment with protease V resulted in less brilliant fluorescence and less satisfactory tissue preservation. Studies were then conducted to determine the fluorescence and less satisfactory tissue preservation. Studies were then conducted to determine the fixative which would produce brightest specific fluorescent antibody staining of papovavirus-infected cells while providing clearest definition of intranuclear inclusions and best morphological detail in histologically stained adjacent sections. Brightest immunofluorescence staining was accomplished on material fixed in 96% ethanol/1% glacial acetic acid or Bouin's solution. These fixatives also gave clear definition of intranuclear inclusions with histological stains and provided excellent morphological detail. Phosphate buffered paraformaldehyde/picric acid and 3.7% formalin gave less satisfactory fluorescence and obscured intranuclear inclusions in histological preparations. Sections fixed in 4% paraformaldehyde, 4% paraformaldehyde/1% glutaraldehyde, and 0.5 M p-toluenesulfonic acid were negative for specific fluorescence. Glycol methacrylate, used with proper fixation and trypsin pretreatment of sections, provides a useful embedding medium for immunofluorescent identification of virus-infected cells, and the 1.0-2.0 micron sections routinely obtainable with GMA permit study of individual infected cells by fluorescent antibody and histological staining of adjacent sections.     

Evaluation of nine different fixatives. 2. Preservation of IgG, IgA and secretory component in an artificial immunohistochemical test substrate

An artificial substrate was developed for quantitative testing of the ability of various fixatives to preserve the reactivity of IgG and IgA isotypes (gamma and alpha chains) and the secretory component (SC) of secretory IgA as model antigens. Polymerized normal rabbit serum was used as matrix and defined amounts (10-0.1 g/l) of antigen were incorporated into it by diffusion before fixation and paraffin embedding. The various fixatives comprised alcohol, routine formalin, glutaraldehyde(1%)-formalin, Baker's formol calcium, formol sublimate, acetic acid(2%)-formol saline, Bouin's fluid, Susa fixative, and carbodiimide. The detection sensitivity afforded by these fixatives was defined as the immunofluorescence staining end point. Compared to the reference value obtained with alcohol (gamma and alpha chains, 0.06 g/l of IgG and IgA; SC, 0.12 g/l of colostral IgA), an antigen concentration at least 8 times higher was necessary for detection with most of the cross-linking fixatives. Bouin's and Susa fixatives were peculiar in that they required more than 150 times higher antigen concentration for detection of IgG but only 3-8 times higher for IgA. The determined sensitivities were compared with the immunofluorescence performance results obtained on human tissues prepared with the same fixatives; excepting carbodiimide (which produced unacceptable autofluorescence of the substrate matrix) a remarkably good correlation was found with regard to IgG- and IgA-producing cells (especially of the former isotype) and secretory epithelium (IgA and SC). However, the latter result depended on pronase treatment of the tissue sections to unmask epithelial antigens.(ABSTRACT TRUNCATED AT 250 WORDS)     

Resorcin Fuchsin Staining of Neurosecretory Cells

The resorcin fuchsin staining solution was prepared by dissolving 1 gm of the dry dye (Chroma) in 98 ml of 70% ethanol acidified by 2 ml of concentrated HCI. When applied to paraffin sections of vertebrate hypothalamus fixed in a modified Bouin's fluid (0.5% trichloroacetic acid replacing 5% acetic), the solution stained neurosecretory cells in a manner comparable to staining by Gomori's aldehyde fuchsin. The resorcin fuchsin solution requires no ripening and is said to keep for months. It showed no deterioration in the 20 day period of testing. Optional fixatives are: unmodified Bouin's, Heidenhain's SUSA, and alcoholic trichloroacetic acid.     

The importance of tissue fixation for light microscopic immunohistochemical localization of peroxisomal proteins: the superiority of Carnoy's fixative over Baker's formalin and Bouin's solution

We have compared the effects of fixation with three commonly used fixatives upon preservation of the antigenicity of six peroxisomal proteins in rat liver using both immunohistochemical staining and Western blotting of fixed tissue extracts. The immunoreactivity of all six peroxisomal proteins was well preserved and peroxisomes were clearly identified in material fixed in Carnoy's fixative. Moreover, the corresponding proteins stained well in Western blots prepared from extracts of Carnoyfixed material. The intensity of the immunohistochemical staining was reduced at different rates for individual peroxisomal proteins after fixation in Baker's formalin, but peroxisomes were still well visualized with antibodies to catalase and some -oxidation enzymes. No evidence of immunohistochemical staining for any peroxisomal antigens was obtained after fixation in Bouin's fluid. For detection of the antibody binding sites in Carnoy's fixed material, the avidin-biotin-peroxidase complex (ABC) with aminoethyl carbazole as chromogen was found to be superior to the methods of peroxidase-antiperoxidase/diaminobenzidine and protein A-gold with silver intensification. Using Carnoy-fixative and the ABC-method, we demonstrate light microscopic immunohistochemical localization of peroxisomal antigens in several rat tissues as well as in human post-mortem liver.     

Optimal fixation conditions for the immunoperoxidase identification of human J chain from tissue sections

Summary J chain can be used as a marker of plasmablasts and plasma cells at an earlier stage than intracellular immunoglobulin. Immunoperoxidase techniques were used to study optimal fixation conditions for the preservation of human J chain antigenicity in paraffin-embedded tissue sections. The most constantly positive staining for J chain combined with good morphological integrity was obtained with Bouin's fluid for 1.5 h at 20°C. All other fixatives studied showed less consistent staining results.Studies supported by the Sigrid Jesélius Foundation     

Evaluation of tissue preparation methods and paired immunofluorescence staining for immunocytochemistry of lymphomas

Eight cross-linking fixatives were tested for preservation of extracellular or intracellular IgG, IgA, IgM, IgD, kappa and lambda light chains, J chain and secretory component. Most of the selected fixatives have been used in recent immunohistochemical studies of lymphoproliferative processes and comprised routine formalin, glutaraldehyde(1%)-formalin, Baker's formalin-calcium, formalin-sublimate, acetic acid(2%)-formalin-saline, Bouin's fluid, Susa fixative, and carbodiimide. The results obtained in artificial test substrates with defined amounts of IgG or IgA and in biological substrates (colon mucosa, tonsils, and different types of lymphomas) were compared by immunofluorescence with the antigenic preservation afforded by fixation in cold 96% ethanol (with or without inclusion of a pre-fixation 48 h washing period). An antigen concentration at least an eight-fold higher was necessary for detection with most other fixatives. Bouin's and Susa fixatives were peculiar in that they required antigen concentration 150 times higher for detection of IgG but only 3-8 times higher for IgA. Light chains were relatively well preserved by all fixatives except glutaraldehyde. For all cross-linking fixatives, the extent of antigenic masking depended on the concentration of environmental proteins, and the efficiency of unmasking with pronase or trypsin, therefore, varied with the location in the tissue. The J chain was particularly vulnerable to degradation during proteolytic treatment. The extensive masking of extracellular immunoglobulin in formalin-fixed tissue afforded a relatively good signal-to-noise ratio for immunoglobulin-producing cells when kappa and lambda chains were traced. Thus, differentiation between polyclonal and monoclonal B-cell processes on the basis of cytoplasmic labelling was often better in undigested sections. However, the light-chain type of membrane immunoglobulin could usually not be determined in directly fixed tissue. Ethanol fixation preceded by washing in saline afforded such determination and also preserved certain T-cell and HLA-DR antigens as well as diffuse alpha-naphthylbutyrate esterase. Reactive and malignant macrophages could further be traced by their cytoplasmic expression of L1 antigen, both in formalin- and ethanol-fixed material.     

Double labeling of SIgG+ cells harboring a lymphotropic herpesvirus by avidin-biotin complex immunoperoxidase and immunogold-silver staining techniques

By reversing the usual order of double-staining procedures, we obtained optimal conditions for simultaneous detection of guinea pig lymphotropic herpesvirus (GPHLV) and surface immunoglobulin G-positive (SIgG+) cells in paraffin-embedded tissue sections. Of the different fixatives tested, Bouin's solution gave the best preservation of morphology and cell surface IgG. Double immunolabeling was best achieved when avidin-biotin complex immunoperoxidase (ABC-IP) staining was performed first for detection of intracellular viral antigen, followed by immunogold-silver staining (IGSS) for localization of cell surface IgG.     

Optimizing collagen antigen unmasking in paraffin-embedded tissues

In order to optimize collagen antigen unmasking in paraffin-embedded tissue sections, the effects of various fixatives and duration of fixation in relation to enzyme pretreatment and microwave irradiation for collagen antigen unmasking were studied. A streptavidin--biotin-- peroxidase complex method was used for the immunolocalization of type III and IV collagen antigens. Fixatives and fixation time had significant adverse effects on the immunoreactivity of the antigens. Enzyme pretreatment was found to be superior to microwave irradiation for collagen antigen unmasking. Fixation with paraformaldehyde required shorter enzyme pretreatment and yielded a more enhanced reaction than treatment with formalin and Bouin's fluid. The optimum conditions for type III and IV collagen unmasking were found to be fixation with 4% paraformaldehyde in 0.01 m phosphate-buffered saline, pH 7.4, for up to 3 weeks followed by enzyme pretreatment with 1 mg ml−1 pepsin in 0.01 n hydrochloric acid, pH 2.0, for 30 min (human tissues) or 60 min (rat tissues) at 37°C. It is concluded that collagen antigen unmasking by enzyme pretreatment in tissue sections fixed for a long period of time can be successful if appropriate enzyme(s) and incubation time(s) are employed with regard to the antigen under study and fixative and fixation time used for tissue preparation     

Optimizing collagen antigen unmasking in paraffin-embedded tissues

In order to optimize collagen antigen unmasking in paraffin-embedded tissue sections, the effects of various fixatives and duration of fixation in relation to enzyme pretreatment and microwave irradiation for collagen antigen unmasking were studied. A streptavidin--biotin-- peroxidase complex method was used for the immunolocalization of type III and IV collagen antigens. Fixatives and fixation time had significant adverse effects on the immunoreactivity of the antigens. Enzyme pretreatment was found to be superior to microwave irradiation for collagen antigen unmasking. Fixation with paraformaldehyde required shorter enzyme pretreatment and yielded a more enhanced reaction than treatment with formalin and Bouin's fluid. The optimum conditions for type III and IV collagen unmasking were found to be fixation with 4% paraformaldehyde in 0.01 m phosphate-buffered saline, pH 7.4, for up to 3 weeks followed by enzyme pretreatment with 1 mg ml−1 pepsin in 0.01 n hydrochloric acid, pH 2.0, for 30 min (human tissues) or 60 min (rat tissues) at 37°C. It is concluded that collagen antigen unmasking by enzyme pretreatment in tissue sections fixed for a long period of time can be successful if appropriate enzyme(s) and incubation time(s) are employed with regard to the antigen under study and fixative and fixation time used for tissue preparation     

The effect of different fixatives and length of fixation time on subsequent AgNOR staining for frozen and paraffin-embedded tissue sections

Summary The AgNOR technique has been used extensively in studies investigating the possibility that the numbers and appearances of the intranuclear structures stained are markers of malignancy. The method has the advantage of being applicable to many different types of histological material, including paraffin-embedded tissue. However, it has been suggested that the visualization of AgNORs is dependent on the type and time of fixation employed. This study set out to measure this effect with the following commonly-used fixatives: acetone, absolute ethanol, methanol, Carnoy's fluid, Bouin's fluid, 4% glutaraldehyde, 10% neutral buffered formalin and 10% formol-saline. Both frozen sections and blocks of fresh tonsil were fixed for varying times, the blocks of tissue then being processed routinely. With the frozen sections AgNORs were easier to discern than in sections of paraffin-embedded tissue, and more intranucleolar AgNORs were visible when alcoholic fixatives were used than with aldehyde fixation. The effects of different fixatives on AgNOR appearance in paraffin sections is, however, more complex. Despite the variation caused by different fixatives, AgNORs could be demonstrated adequately with all the fixatives studied. It is concluded that fixation is not a limitation to the study of AgNORs provided that the time and type of fixative is controlled.     

Differential Staining with a Mixture of Safranin and Fast Green FCF

Mounted deparaffinized sections were stained for 30-60 minutes at room temperature in a mixture of equal volumes of 0.1% aqueous solutions of safranin O and fast green FCF filtered before use. They were then washed in distilled water for 5 minutes, blotted, washed in 2 changes of absolute alcohol (2-3 min) and mounted from xylene. The nucleic acids are stained purplish-red, half esters of sulfuric acid orange, and proteins green. The procedure is applicable to a variety of materials fixed in a number of reagents though best results are obtained after acetic-alcohol fixation. Bouin's fluid and 10% neutral formalin are not suitable fixatives for this procedure. After acetic-alcohol fixation, the staining procedure may be used in conjunction with enzyme or extraction technics in order to characterize certain chemical components of cells or tissues. The safranin-fast-green technic has proved useful in investigations of pathological changes in tissues; in the visualization of secretory granules and in studies of cellular differentiation. The technic also would appear to greatly facilitate mitotic index determinations.     

Processing techniques for the demonstration of myelin basic protein in paraffin-embedded optic nerve: an immunoperoxidase study of the developing albino rat

A comparison was made of the effects of various fixation and processing conditions upon the antigenicity of myelin basic protein (MBP) in sections of paraffin-embedded optic nerve from the developing albino rat as judged by the unlabeled peroxidase-antiperoxidase technique. The fixatives used were: Perfix, 4% and 2% buffered paraformaldehyde (pH 7.4), 10% buffered formalin (pH 7.4); Bouin's, Clark's, and Carnoy's fixatives, and 20% formalin in a solution of HgCl2 that had been saturated at 1 degrees C. Perfix appeared to be the best fixative for the preservation of morphology and MBP antigenicity during the early stages of myelinogenesis but was not satisfactory during the later stages. The buffered aldehydes were slightly more destructive of MBP antigenicity than was Perfix, but they produced satisfactory results following the first postnatal week. Bouin's fixative was similar in effect to the buffered aldehydes, but nonspecific background staining was higher. HgCl2/formalin, Clark's and Carnoy's fixatives were unsuitable. No differences were noted in staining between material processed for embedding using 5, 30, or 60 min schedules.     

Fixation and Staining of Planaria for Histological Study

Fixation and staining of planaria can affect the interpretation of histopathological changes following their exposure to various agents. We assessed several fixation protocols with various stains in planaria to determine an optimal combination. Planaria were fixed in each of the following: 10% neutral buffered formalin, 2.5%, glutaraldehyde, Bouin's, Zenker's, 70% ethanol, and relaxant. In addition, planaria were fixed in relaxant and postfixed in each of the fixatives above. Paraffin embedded sections from each fixation protocol were stained with hematoxylin and eosin (H & E), toluidine blue, periodic acid-Schiff (PAS), or phosphotungstic acld-hematoxylin (PTAH). Relaxant fixed planaria were also stained with Steiner's, Holmes, trichrome, Giemsa, Grocott's methenamine silver (GMS) and antibodies for intermediate filaments (cytokeratin, vimentin and desmin). Relaxant and Zenker's gave the best fixation with minimal artifacts. Formalin, glutaraldehyde, and ethanol were unacceptable because they caused contortions of the body, crenation, and a darkly pigmented epidermis. Gastroderm could be differentiated from stroma best when stained with H & E, toluidine blue and PTAH. Other organ systems differentially stained included the epidermis, marginal adhesion gland, nervous tissue, and muscle. PAS, Steiner's, Holmes, trichrome and the intermediate filament stains were not useful for planaria staining. The most morphological information was obtained with relaxant fixative and a combination of sections stained with H & E and PTAH.     

Immunohistochemical application of monoclonal antibodies against myelin basic protein and neurofilament triple protein subunits: advantages over antisera and technical limitations

Four monoclonal antibodies against guinea pig myelin basic protein (MBP), and four against subunits of bovine neurofilament triplet proteins (NF) were produced and their activity determined by enzyme-linked immunosorbant assay. The specificity and cross-reactivity of these eight monoclonal antibodies and one heterologous antiserum against each of the two central nervous system (CNS) antigens were examined in a histological study using the immunoperoxidase, antibody sandwich technique in rat and human brain tissue. Tissue sections were prepared from paraffin-embedded or fresh brain tissue that had been fixed with one of five different fixatives. The resulting immunoperoxidase labeling was then graded for intensity and examined for artifacts. One monoclonal antibody against MBP and one against NF resulted in labeling that was superior to that given by each of the antisera against their respective antigens. Of the five fixatives tested, a mercuric chloride-formalin solution gave the best preservation of these two antigens in rat and human brain tissue. The mercuric chloride-formalin solution was found to be superior to the other fixatives when immersion fixation was used, and was especially optimal when brains were perfused fixed. Three artifacts were encountered among the various antibody-fixative combinations that produced erroneous, but seemingly specific staining of Purkinje cells, neurons and axons, or astrocytes.     

An investigation of aldehyde fuchsin staining of unoxidized insulin

Aldehyde fuchsin is a standard stain for the secretion granules of pancreatic B cells. The participation of either insulin or proinsulin in aldehyde fuchsin staining is in dispute. There is some evidence that permanganate oxidized insulin is stained by aldehyde fuchsin. Aldehyde fuchsin staining of unoxidized insulin has not been investigated adequately despite excellent staining results with tissue sections. Unoxidized insulin and proinsulin suspended by electrophoresis in polyacrylamide gels were fixed with Bouin's fluid and placed in aldehyde fuchsin for one hour. Because the unoxidized proteins were not stained by aldehyde fuchsin, it was concluded that neither insulin or proinsulin are responsible for the intense aldehyde fuchsin staining of unoxidized pancreatic B cell granules in tissue sections. A series of controlled experiments was undertaken to test the effects of fixatives, oxidation and destaining procedures on aldehyde fuchsin staining of insulin, proinsulin and other proteins immobilized in polyacrylamide gels. It was demonstrated that only oxidized proteins were stained by aldehyde fuchsin and that cystine content of the proteins had no apparent relation to aldehyde fuchsin staining. It was concluded that neither insulin nor proinsulin is likely to be responsible for the intense aldehyde fuchsin staining of unoxidized pancreatic B cell granules in tissue sections.