Immunohistochemical procedures for the demonstration of peptide- and tyrosine hydroxylase-containing nerve fibers in cryostat sections of unfixed rapidly frozen tissue stored for long periods of time

Summary Traditional protocols for the immunohistochemical localization of peptides and tyrosine hydroxylase (TH) in nerve fibers in cryostat sections require the tissue to be thoroughly fixed and rinsed and to be processed for the cryostat sectioning and the immunohistochemical staining more or less directly after freezing. In the present study it was tested whether also unfixed, rapidly frozen tissue, conforming to guinea pig and bovine heart specimens, can be used for the visualization of neuropeptides [neuropeptide Y (NPY) and substance P (S P)] and TH in cryostat sections. The following observations were made: 1) NPY-immunoreactive (IR) and S P-IR nerve fibers could be clearly identified in both fixed and unfixed sections of this type of tissue. 2) TH-IR nerve fibers could be detected in unfixed tissue if the sections were post-fixed with aldehydes by the use of a two-step fixation process related to a sudden change of pH. However, the outlines of the nerve fibers were sometimes diffuse. 3) Storage of unfixed tissue for periods of up to 2.5 yeart at –80° C did not lead to a decrease in immunoreactivity. 4) Somewhat higher concentrations of primary antibodies had to be used for sections of unfixed tissue than for sections of fixed tissue when the FITC method was used. This waste of antibodies was partly overcome by use of the biotin-streptavidin method. The glyoxylic acid induced catecholamine(CA)-fluorescence method for demonstration of sympathetic nerve fibers was also applied and was found to give optimal results after storage of tissue for up to 2.5 years. The study shows that the use of unfixed rapidly frozen tissue represents a fast and realistic method for the demonstration of neuropeptide immunoreactivity, that it to some extent can be used for the visualization of TH-containing nerve fibers and that it is a suitable method to maintain longterm neuropeptide and TH immunoreactivity as well as long-term CA-fluorescence reaction.     

Immunohistochemical procedures for the demonstration of peptide- and tyrosine hydroxylase-containing nerve fibers in cryostat sections of unfixed rapidly frozen tissue stored for long periods of time. A study on heart tissue

Traditional protocols for the immunohistochemical localization of peptides and tyrosine hydroxylase (TH) in nerve fibers in cryostat sections require the tissue to be thoroughly fixed and rinsed and to be processed for the cryostat sectioning and the immunohistochemical staining more or less directly after freezing. In the present study it was tested whether also unfixed, rapidly frozen tissue, conforming to guinea pig and bovine heart specimens, can be used for the visualization of neuropeptides [neuropeptide Y (NPY) and substance P (S P)] and TH in cryostat sections. The following observations were made: 1) NPY-immunoreactive (IR) and S P-IR nerve fibers could be clearly identified in both fixed and unfixed sections of this type of tissue. 2) TH-IR nerve fibers could be detected in unfixed tissue if the sections were post-fixed with aldehydes by the use of a two-step fixation process related to a sudden change of pH. However, the outlines of the nerve fibers were sometimes diffuse. 3) Storage of unfixed tissue for periods of up to 2.5 years at-80 degrees C did not lead to a decrease in immunoreactivity. 4) Somewhat higher concentrations of primary antibodies had to be used for sections of unfixed tissue than for sections of fixed tissue when the FITC method was used. This waste of antibodies was partly overcome by use of the biotin-streptavidin method. The glyoxylic acid induced catecholamine(CA)-fluorescence method for demonstration of sympathetic nerve fibers was also applied and was found to give optimal results after storage of tissue for up to 2.5 years.(ABSTRACT TRUNCATED AT 250 WORDS)     

A simple and highly efficient fixation method for Chrysochromulina polylepis (Prymnesiophytes) for analytical flow cytometry

BACKGROUND: To study the fragile Prymnesiophyte species Chrysochromulina polylepis by flow cytometry (FC), we needed an effective fixation method. This method must guarantee a high yield of fixed cells to achieve acceptable measurement times by FC and to allow quick processing of many samples. Moreover, we wanted a method that allows for storage of fixed samples when FC analysis cannot be done immediately. METHODS: Different aldehydes and methanol were tested at different final concentrations. Gravity sedimentation and centrifugation were applied to achieve higher cell concentrations. Storage of fixed samples was tested under different conditions. RESULTS: 0.25% glutaraldehyde (GA) fixation yielded a recovery rate of about 90%. The signals obtained by FC analysis were excellent. It is possible to centrifuge GA-fixed cells and to store them for several weeks. CONCLUSIONS: GA is the fixative of choice for FC analysis of C. polylepis (and possibly other small delicate species) because it yielded highly significant recovery rates and high-quality FC signals. Cells can be centrifuged to increase the cell concentration, thereby achieving short measurement times with FC. The possibility of long-term storage of fixed cells presents an additional advantage if FC analysis cannot be done immediately.     

A Rapid Technique for Preparing Microorganisms for Transmission Electron Microscopy

A rapid and efficient method of preparing microorganisms for transmission electors microscopy is reported. In developing the method Salmonella, streptococcal, ad protozoal specimens were fixed with glutaraldehyde. After fixation cells are collected on a membrane filter, washed with buffer, postfixed with osmium tetroxide, then washed with distilled water and stained en bloc with uranyl acetate. Specimens are dehydrated using a graded series of acetone and then infiltrated with graded mixtures of acetone and Spurr embedding medium. Finally the membrane filter is cut into small pieces and embedded in fresh embedding medium polymerized in polyethylene capsules. By collecting and processing the specimens on membrane filters, numerous centrifugations are eliminated from standard procedures. The use of a low viscosity embedding medium allows for rapid infiltration and embedding of the specimen. Using this technique microbial specimens can be sectioned after less than 4 hours preparation.     

A rapid technique for preparing microorganisms for transmission electron microscopy.

A rapid and efficient method of preparing microorganisms for transmission electron microscopy is reported. In developing the method Salmonella, streptococcal, and protozoal specimens were fixed with glutaraldehyde. After fixation cells are collected on a membrane filter, washed with buffer, postfixed with osmium tetroxide, then washed with distilled water and stained en bloc with uranyl acetate. Specimens are dehydrated using a graded series of acetone and then infiltrated with graded mixtures of acetone and Spurr embedding medium. Finally the membrane filter is cut into small pieces and embedded in fresh embedding medium polymerized in polyethylene capsules. By collecting and processing the specimens on membrane filters, numerous centrifugations are eliminated from standard procedures. The use of a low viscosity embedding medium allows for rapid infiltration and embedding of the specimen. Using this technique microbial specimens can be sectioned after less than 4 hours preparation.     

Processing tissue and cells for transmission electron microscopy in diagnostic pathology and research

In transmission electron microscopy (TEM), electrons are transmitted through a plastic-embedded specimen, and an image is formed. TEM enables the resolution and visualization of detail not apparent via light microscopy, even when combined with immunohistochemical analysis. Ultrastructural examination of tissues, cells and microorganisms plays a vital role in diagnostic pathology and biologic research. TEM is used to study the morphology of cells and their organelles, and in the identification and characterization of viruses, bacteria, protozoa and fungi. In this protocol, we present a TEM method for preparing specimens obtained in clinical or research settings, discussing the particular requirements for tissue and cell preparation and analysis, the need for rapid fixation and the possibility of analysis of tissue already fixed in formalin or processed into paraffin blocks. Details of fixation, embedding and how to prepare thin and semi-thin sections, which can be used for analysis complementary to that performed ultimately using TEM, are also described.     

A new antigen retrieval technique for human brain tissue

Immunohistochemical staining of tissues is a powerful tool used to delineate the presence or absence of an antigen. During the last 30 years, antigen visualization in human brain tissue has been significantly limited by the masking effect of fixatives. In the present study, we have used a new method for antigen retrieval in formalin-fixed human brain tissue and examined the effectiveness of this protocol to reveal masked antigens in tissues with both short and long formalin fixation times. This new method, which is based on the use of citraconic acid, has not been previously utilized in brain tissue although it has been employed in various other tissues such as tonsil, ovary, skin, lymph node, stomach, breast, colon, lung and thymus. Thus, we reported here a novel method to carry out immunohistochemical studies in free-floating human brain sections. Since fixation of brain tissue specimens in formaldehyde is a commonly method used in brain banks, this new antigen retrieval method could facilitate immunohistochemical studies of brains with prolonged formalin fixation times.     

Visualisation of microtubules and actin filaments in fixed BY-2 suspension cells using an optimised whole mount immunolabelling protocol

Excellent visualisation of microtubules and actin filaments was obtained in fixed tobacco BY-2 suspension cells after optimising a protocol for whole mount immunolabelling. The procedure is based on modification of fixation, cell wall digestion, dimethyl sulfoxide (DMSO) treatment, post fixation, and blocking. The most critical aspects of successful preservation and visualization of cytoskeletal elements appeared to be: a two-step fixation with paraformaldehyde and glutaraldehyde before enzymatic cell wall digestion and a post fixation with aldehydes thereafter. The method allows the improved visualization of the organisation of the microtubular and actin filament arrays during the successive stages of cell division and at interphase. Although we present the application of our protocols for cytoskeleton labelling, the excellent results show the potential of using this method for the analysis of various proteins and molecules in plant cells.Electronic Supplementary Material Supplementary material is available for this article at     

Special symposium: fixation and tissue processing models

Abstract

Fixation and processing of tissue to paraffin blocks permit thin (4-5 µm) sections of tissues to be cut. Tissues and their subcellular components and surrounding stroma are visualized by cutting thin sections and staining them histochemically or immunohistochemically and viewing the sections using a bright field microscope. During the last century, anatomists and pathologists have used fixation with 10% neutral buffered formalin (10% NBF) as the fixative of choice. Also, both human and veterinary pathologists have trained to use fixation with 10% NBF, so these professionals are reluctant to change the familiar microscopic appearance of diagnostic tissues by using different fixatives. In addition, the effects of tissue processing on the microscopic appearance of tissue essentially has been ignored in most studies. Archives of paraffin blocks of pathological tissue contain essentially paraffin blocks fixed in 10% NBF. Therefore, if retrospective studies use archival paraffin blocks to correlate the molecular features of diseases with their outcomes, the studies must be based on tissue fixed in 10% NBF. Studies of how fixation in 10% NBF interacts with histochemical and immunohistochemical staining are limited in number and most are based on relatively long fixation times (≥36 h). Currently, fixation times in 10% NBF have been reduced to <24 h. Little is known about fixation in 10% NBF and its interaction with tissue processing for any period of fixation, especially short times. Less is known about how fixation of tissues with 10% NBF interacts with more modern assays using immunohistochemistry, real time quantitative polymerise chain reaction (PCR), and techniques that depend on analysis of proteins extracted from paraffin blocks including multiplex immunoassays or mass spectrometry. In general, multiple antibody–antigen combinations are reported not to work in tissues fixed in 10% NBF, i.e., loss of immunorecognition is nearly complete for such antibody–antigen combinations as Ki67/MIB, estrogen receptor alpha (ERα) and Progesterone receptor (PR), and partial for Bcl-2. Several models have been developed to study the interactions of tissue fixation and immunorecognition, but most have viewed the problem with immunorecognition as completely caused by fixation. Also, some of the models discussed in this special symposium do not predict the effects of fixation on frozen tissues fixed in 10% NBF and not processed to paraffin blocks. This article is a brief review of issues attending the use of 10% NBF combined with tissue processing as an interrelated process to study biomarkers identified by immunohistochemistry.     

An improved method for preparing cryostat sections of undecalcified bone for multiple uses.

We developed a technique that permits the use of serial sections (7-20 microns) from a single fixed piece of bone tissue for immunofluorescence, measurement of fluorescent bone labels, enzyme histochemistry, and general staining. This technique combines modifications of previously established methods with perfusion of the polymer polyvinylpyrrollidone (PVP) to improve sectioning, and produces reliable sections with good preservation of both hard and soft tissues. The combination of techniques from several workers, the use of perfusion with a polymer to increase the sectionability of the bone, and the addition of a gelatin adhesive on top of pressure-sensitive adhesives represent a significant improvement over previously described methods. The sections obtained are usable for immunocytochemistry, general staining, enzyme histochemistry, and visualization of fluorescent bone labels. We have consistently used tissues prepared in this manner for immunohistochemical demonstration of neuropeptides in skeletal tissues and for localizing tartrate-resistant acid phosphatase (TRAP). In addition, other tissues obtained from PVP-perfused rats, such as brain, spinal cord, muscle, gut, and sympathetic ganglia, are also well preserved and demonstrate immunohistochemical staining comparable to and possibly superior to that obtained with normal fixation protocols.     

Rapid method of visualizing endothelium in unfixed tissue

An express method of visualization of endotheliocytes has been described. It is based on the combined use of vital dye-thioflavin and silver nitrate. The method requires no fixation, "h?utchen" preparation and scanning electron microscopy. It is very simple, needs no special training or facilities and allows visualization of the endothelium already 2 min after the tissue is obtained.     

A precise radiographic technique for the measurement of dimensional changes in heart valve biomaterials following fixation

Accurate tissue thickness measurements are difficult to acquire by present techniques. Error is introduced by tissue compression during measurements or by tissue processing prior to measurement. In the field of valve replacement, tissue dimensional changes from fixation prior to implantation may predispose implants to premature tissue failure and it becomes important to have an accurate method for comparing cusp dimensions pre- and post-fixation. A new approach is to use high-resolution digital radiography to make thickness maps of entire specimens. For 25 matched porcine aortic valve cusps, we have evaluated this technique's ability to measure and compare thickness, surface area and volume before and after 7 days of aldehyde fixation. Digital radiographs were acquired pre- and post-0.5% glutaraldehyde (n=13) or 10% formaldehyde (n=12) fixation. Mean thickness, surface area, volume and four measurements to evaluate shape differences with fixation were obtained and compared pre- and post-fixation using paired t tests. The results demonstrate that this X-ray imaging technique can provide dimensions of matched fresh and fixed specimens and is sensitive enough to show statistically significant changes due to fixation. These findings also illustrate that aldehyde fixation can cause tissue contraction resulting in a significant overall increase in tissue thickness and a decrease in surface area. This technique could be used to gain further insights into tissue anatomy and mechanics.     

Model systems for the immunolocalisation of cis,trans abscisic acid in plant tissues

To explore the feasibility of immunolocalisation of endogenous abscisic acid (ABA), model systems were developed for testing quantitatively the sensitivity of the second antibody peroxidase/antiperoxidse (PAP) method for immunolocalisation of ABA on plant tissues. Exogenous (±)ABA was fixed to carrot sections on glass slides or to homogenised pea cotyledon material on microtitre plates, either directly by carbodiimide fixation or by glutaraldehyde fixation of ABA-protein conjugates linked through the C1 carboxyl by 1-ethyl-3(3-dimethyl-amino-propyl) carbodiimide hydrochloride (EDC). Backgrounds were decreased by including 0.1% normal goat serum in the incubations, by including 0.1% Triton X-100 as a wetter, by including glycine in the rinses after EDC fixation and by using low-pH rinses after incubation with the primary antibody. Serum antibodies recognising the peptide bond between the protein and abscisic acid were removed by preincubating the serum with acetic acid conjugated to protein. Positives were only accepted when they could be eliminated by adding an excess of ABA-protein conjugate in the primary antiserum. By using a soluble peroxidase reaction product to facilitate quantitation, the limit of reliable exogenous ABA detection was found to be only of the order of 1 pmol. For the histochemical immunolocalisation of endogenous ABA, better antisera and lower backgrounds will be required.The efficiency of fixation of exogenous ABA was determined using [³H] or [¹⁴C]ABA. When aqueous EDC or di-isopropyl carbodiimide (IPC) were used the fixation efficiency was low (up to 5%), but much higher efficiencies (up to 80%) were obtained using IPC vapour with freeze-dried material. Similarly efficient fixation of endogenous ABA in pea cotyledon material, as determined by gas chromatography-mass spectrometry analysis, was obtained using the same technique. The PAP method failed to detect fixed endogenous ABA in pea cotyledons, even though the total tissue amounts present exceeded 1 pmol, evidence that not enough of the ABA was accessible to the antibody.Abbreviations ABA abscisic acid - ACE-ALP acetic acid-alkaline phosphatase - EDC 1-ethyl-3(3-dimethyl-amino-propyl) carbodiimide hydrochloride - GC-MS gas chromatographymass spectrometry - IgG Immunoglobulin G - HSA humanserum albumin - IPC dinsopropyl carbodiimide - LINK goat anti-rabbit IgG - OD optical density - PAP peroxidase/rabbit antiperoxidase complex     

Optimization of immunohistochemical techniques to detect extracellular matrix proteins in fixed skin specimens

Complete antigen visualization in the context of well-preserved tissue architecture is the goal of all immunohistochemical techniques. Frozen tissue section techniques achieve optimal antigen visualization but preserve tissue architecture poorly. On the other hand, formalin-fixed tissue section techniques preserve tissue architecture very well but result in antigen masking. Enzymatic digestion or salt extraction of formalin-fixed sections has been used to reestablish antigen expression. Recently acid-alcohol-fixed tissue has been used as a successful compromise between tissue architecture preservation and the visualization of cytoskeletal antigens. In an attempt to find an improved immunohistochemical process for non-cytoskeletal antigens, we compared avidin-biotin immunofluorescence staining in frozen, formalin-fixed, and acid-alcohol-fixed tissues. The fixed tissues were either untreated or treated with enzyme digestion or salt extraction. For this study, we examined healing cutaneous wounds in Yorkshire pigs with antibodies to fibronectin, laminin, von Willebrand factor VIII, and keratin. Although tissue architecture was poor, frozen sections provided the best antigen visualization and were therefore used as the standard for complete antigen expression. Formalin-fixed tissues had excellent tissue architecture, but most antigens were completely masked. Pre-treatment technique only partially overcame the antigen masking caused by formalin. In contrast, acid-alcohol fixation preserved tissue architecture almost as well as formalin and sometimes allowed complete antigen visualization; however, laminin and fibronectin were partially masked. Total recovery of the expression of these antigens could be obtained by pre-treating the acid-alcohol-fixed tissue with either hyaluronidase or 1 M NaCl. Therefore, acid-alcohol-fixed tissue appears best for extracellular matrix (ECM) protein immunostaining as well as for cytoskeletal staining. However, certain ECM antigens require hyaluronidase or 1 M NaCl treatment for optimal visualization.     

Ultrafiltration membranes for chemical bonding of urease

Asymmetric ultrafiltration membranes suitable for covalent bonding of urease can be prepared from membranes based upon polyamide or polysulfone. Because the original membrane polymers are not chemically reactive, they have to be converted in such a way that known reactions for enzyme fixation can be used such as the diazo, the acyl-acid, the carbodiimide, and the methylbromide reaction. The enzyme was fixed within the porous substructure of the membrane. The amount of enzyme immobilized at the membrane dense skin was found to be negligible. The kinetics can be described according to the Michaelis-Menten model. Compared to the native urease, the activity of the membrane-bonded enzyme was very low. The reasons can be sought in the transmembrane transport and in the fixation procedure as well.     

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.     

Macromolecular changes caused by formalin fixation and antigen retrieval

Although the mechanics of formalin fixation and antigen retrieval have been studied extensively and reviewed periodically, little attention has been directed toward conformational changes in target molecules. Formaldehyde changes the shape of tissue molecules by appending small hydroxymethyl groups to them. These adducts, in turn, can react with other tissue molecules to form crosslinks, or they can participate in a variety of reactions during tissue processing, including formation of imines, ethoxymethyl adducts, and further crosslinks. Under the influence of alcohol dehydration, fixed DNA may fragment and form a variety of depurination products. The situation becomes even more complex with short fixation times because under these conditions, the dehydrating agent used for tissue processing denatures macromolecules in other ways, most notably through rearrangement of molecular shape to move hydrophobic realms outward and hydrophilic areas inward (hydrophobic inversions). How tissue molecules are modified affects the outcome of immunohistochemical staining and prospects for restoration of antigenicity. Immunoreacitivity may be compromised because epitopes are either sterically hidden, but otherwise unaffected, or they have been altered more directly. Enzyme-based retrieval methods are best suited for the former because they literally snip the molecule apart to reveal the portions of interest. Heat-induced retrieval with buffers can demodify affected epitopes by removing adducts and breaking crosslinks. The choice of temperature and pH is usually critical for optimal retrieval. Effective temperatures are directly related to the strength of bonds-higher temperatures are needed to break stronger bonds. The pH of the retrieval solution determines the charge on the tissue molecule; the goal is to create a charge that causes the demodified molecule to assume a near natural conformation. Rational use of these concepts should lead to better control of immunohistochemical reactions.     

Macromolecular changes caused by formalin fixation and antigen retrieval

Although the mechanics of formalin fixation and antigen retrieval have been studied extensively and reviewed periodically, little attention has been directed toward conformational changes in target molecules. Formaldehyde changes the shape of tissue molecules by appending small hydroxymethyl groups to them. These adducts, in turn, can react with other tissue molecules to form crosslinks, or they can participate in a variety of reactions during tissue processing, including formation of imines, ethoxymethyl adducts, and further crosslinks. Under the influence of alcohol dehydration, fixed DNA may fragment and form a variety of depurination products. The situation becomes even more complex with short fixation times because under these conditions, the dehydrating agent used for tissue processing denatures macromolecules in other ways, most notably through rearrangement of molecular shape to move hydrophobic realms outward and hydrophilic areas inward (hydrophobic inversions). How tissue molecules are modified affects the outcome of immunohistochemical staining and prospects for restoration of antigenicity. Immunoreacitivity may be compromised because epitopes are either sterically hidden, but otherwise unaffected, or they have been altered more directly. Enzyme-based retrieval methods are best suited for the former because they literally snip the molecule apart to reveal the portions of interest. Heat-induced retrieval with buffers can demodify affected epitopes by removing adducts and breaking crosslinks. The choice of temperature and pH is usually critical for optimal retrieval. Effective temperatures are directly related to the strength of bonds-higher temperatures are needed to break stronger bonds. The pH of the retrieval solution determines the charge on the tissue molecule; the goal is to create a charge that causes the demodified molecule to assume a near natural conformation. Rational use of these concepts should lead to better control of immunohistochemical reactions.     

Porcine Intestinal Mast Cells. Evaluation of Different Fixatives for Histochemical Staining Techniques Considering Tissue Shrinkage

Staining of mast cells (MCs), including porcine ones, is critically dependent upon the fixation and staining technique. In the pig, mucosal and submucosal MCs do not stain or stain only faintly after formalin fixation. Some fixation methods are particularly recommended for MC staining, for example the fixation with Carnoy or lead salts. Zinc salt fixation (ZSF) has been reported to work excellently for the preservation of fixation-sensitive antigens. The aim of this study was to establish a reliable histological method for counting of MCs in the porcine intestinum. For this purpose, different tissue fixation and staining methods that also allow potential subsequent immunohistochemical investigations were evaluated in the porcine mucosa, as well as submucosa of small and large intestine. Tissues were fixed in Carnoy, lead acetate, lead nitrate, Zamboni and ZSF and stained subsequently with either polychromatic methylene blue, alcian blue or toluidine blue. For the first time our study reveals that ZSF, a heavy metal fixative, preserves metachromatic staining of porcine MCs. Zamboni fixation was not suitable for histochemical visualization of MCs in the pig intestine. All other tested fixatives were suitable. Alcian blue and toluidine blue co-stained intestinal goblet cells which made a prima facie identification of MCs difficult. The polychromatic methylene blue proved to be the optimal staining. In order to compare MC counting results of the different fixation methods, tissue shrinkage was taken into account. As even the same fixation caused shrinkagedifferences between tissue from small and large intestine, different factors for each single fixation and intestinal localization had to be calculated. Tissue shrinkage varied between 19% and 57%, the highest tissue shrinkage was found after fixation with ZSF in the large intestine, the lowest one in the small intestine after lead acetate fixation. Our study emphasizes that MC counting results from data using different fixation techniques can only be compared if the respective studyimmanent shrinkage factor has been determined and quantification results are adjusted accordingly.Key words: mast cell, swine, fixation, tissue shrinkage factor     

Collagenase predigestion on paraffin sections enhances collagen immunohistochemical detection without distorting tissue morphology

Reliable immunohistochemical detection of collagen in formalin fixed, paraffin embedded tissues requires protease digestion. While these pan-proteases (pepsin, trypsin, protease K, etc.) enhance collagen detection, they also digest many other tissue proteins and produce poor cellular morphology and unrecognizable cellular structures. Balancing the conditions (protease type, concentration, incubation time and temperature) to digest some, but not all, proteins in a tissue section while optimizing collagen detection requires one to compromise improved collagen immunolabeling with adequate cellular morphology. Furthermore, optimal conditions for digesting tissue proteins to enhance collagen detection vary among tissue types and their fixation. Although brain is not typically subject to these deleterious consequences, structures such as epithelium, spermatids, stroma etc. and other tissues with complicated histology are profoundly affected. To resolve this technical dilemma, we discovered a novel use for collagenase to enhance collagen immunodetection without affecting the noncollagen proteins, thereby preserving tissue morphology. Collagenase, which is typically used in vitro for disassociation of cells, has never been used reliably on formalin fixed, paraffin embedded tissue sections. This new use of collagenase for immunohistochemistry promotes increased collagen immunolabeling, is easy to use, is versatile, and allows preservation of tissue structure that provides maximal and accurate histological information.