A Simple Technique for Osmicating and Flat Embedding Large Tissue Sections for Light and Electron Microscopy

Many investigators now use thin hand-sliced, tissue chopper, or Vibratome sections of fresh tissue in various procedures. In our experience brain and nerve sections varying in thickness from less than 40 to more than 300 μm, with or without prior embedding in agar, have a tendency to roll up or curl during aldehyde fixation and buffer washes. Once osmicated, such curled sections cannot be flattened. When the entire cut face of such thin slices is to be studied, sufficiently flat embedding so that some regions are not completely sectioned before others are even sampled is critical. This report describes fixation and flat embedding procedures, developed for light and electron microscopic autoradiographic studies of plastic embedded brain slices about 200 μm thick (Schwartz 1981), which can be applied to any comparable thin slice of nervous tissue (or potentially of many other tissues) to achieve maximally flat tissue faces. Since osmicated tissue slices are usually too thick to be transilluminated for direct examination with the light microscope, the methods described simplify preparation of the semithin sections required for this purpose.     

Rapid method to prepare mammalian oocytes and embryos for transmission electron microscopy

A method for the preparation of mammalian oocytes and embryos for transmission electron microscopy employing agar embedding of oocytes and re-embedding of semithin sections is described. This method offers rapid and safe handling of small specimens, and it allows analyses of even very small structures in the oocytes.     

Modification of the Liquid Used in Spreading Polystyrene Embedded Sections

The new method of embedding histological specimens in polystyrene (Frangioni and Borgioli 1979) prescribes spreading and mounting the embedded sections on slides using a 10% paraldehyde solution on a hot plate set at 80 C; time required about 10 min. During this operation, analogous to that used for paraffin mounts (including the use of Mayer's albumen), sections rich in connective tissue or particularly hard often cannot be adequately spread due to the rapidity with which the paraldehyde solution evaporates. This disadvantage, which results in opacity where the mounted sections have not adhered to the slide, can be eliminated by modifying the solution as follows:     

A Pre-embedding Reaction Method for Localizing NADH Reductase and Succinic Dehydrogenase in Skeletal Muscle

Paraffin wax embedding methods suitable for demonstrating the distribution of enzyme activity in tissues sections are uncommon; most procedures rely on the use of frozen section techniques. This paper describes a system for demonstrating certain enzymes which involves incubation of the tissue with appropriate substrates before a Paramat wax embedding procedure. While it has distinct merits of its own, the procedure is eminently suitable for use where a cryostat is not available; it can also be readily applied to other enzymes and tissues.     

The influence of embedding media and fixation on the postembedment ultrastructural demonstration of complex carbohydrates. III. High iron diamine staining for sulfated glycoconjugates

The high iron diamine (HID) method for detection of sulfated complex carbohydrate has been applied directly on thin sections of variably fixed tissues embedded in epoxy and nonepoxy resins. Results with postembedment HID staining in mouse intestinal epithelium are compared to those previously obtained using preembedment methods. Sections from epoxy-embedded tissues have been found to exhibit the weakest staining intensity. Intense, specific staining was obtained in tissues not postfixed with osmium tetroxide and embedded in polystyrene, polyester resins, styrene-methacrylate, and especially the styrene-Vestopal W embedding mixture. Postosmication of tissues abolished HID staining in epoxy resins and the styrene-Spurr's resin embedding mixture, but only reduced the staining intensity in tissues embedded in nonepoxy resins.     

Immunohistochemistry on Resin Sections: A Comparison of Resin Embedding Techniques for Small Mucosal Biopsies

We have modified resin embedding methods to provide optimal information from en-doscopic biopsies. Mucosal biopsies were fixed either in buffered formalin and processed for embedding in Araldite or in acetone containing protease inhibitors and embedded in glycol meth-acrylate (GMA). GMA embedding generated an im-munophenotypic profile similar to that obtained in frozen sections while yielding far superior morphology and greater numbers of sections from small biopsies. The phenotypic markers included those for T cells, macrophages, mast cells, eosin-ophils and neutrophils. We have also demonstrated collagens, cell adhesion molecules and integrin molecules. Sections of similar quality were obtained with Araldite but the repertoire of antibodies was restricted to those which can be applied to formalin fixed, paraffin embedded tissues. We suggest that for optimal results, small biopsies to be subjected to immunochemistry are fixed in acetone at -20 C with the inclusion of protease inhibitors and embedded in GUIA with careful temperature control.     

Modern acrylics for post-embedding immunostaining techniques

We describe two methods for rapid processing of biological tissues into LR White acrylic plastic. Both methods make use of LR White's compatibility with small amounts of water, enabling non-osmicated tissue to be only partially dehydrated before infiltration with the plastic, a procedure that improves the sensitivity of post-embedding immunocytochemistry. In addition, both methods are designed to reduce the time for which tissue is exposed to the damaging influence of the plastic monomer, which can cause extraction and sudden shrinkage. The tissue example used in the first method is immersion-fixed, surgically removed human pituitary which, by virtue of its thorough fixation, can be processed quickly at 50 degrees C using catalytic polymerization at room temperature. The concentration of the catalyst is critically set to prevent the temperature rising above 60 degrees C in the tissue blocks. Penetration of immunoperoxidase reagents into 330-nm LR White sections is demonstrated and possible modes of action are discussed. When "lightly" fixed tissue is processed as above, serious polymerization artifacts can result from autocatalysis. A second method, based on the first but employing slower polymerization at 0 degrees C, has therefore been developed. The high level of fine structure that can be retained using this method is illustrated by the demonstration of the trans-tubular Golgi in perfusion-fixed kidney of rat. Biotinylated lectin is localized to cells of the kidney proximal tubule with streptavidin-colloidal gold, to illustrate tissue reactivity. In a second example, the structure of the bacterial cell envelope is shown to be similar in appearance after partial dehydration and LR White embedding to that seen after progressive lowering of temperature, dehydration, and Lowicryl embedding.     

Histological Methods for Assessing Myelin Sheaths and Axons in Human Nerve Trunks

Although there are many histological techniques for assessing myelin sheaths and axons in paraffin embedded or frozen sections of the peripheral nervous system, modern approaches usually use plastic embedded material. Although plastic embedding is superior for small cutaneous branches, this method has limited value for histological assessment of nerve trunks. We report three methods which together yield a comprehensive approach for thorough and detailed investigation of human nerve trunks. The rapid osmication method permitted assessment of myelinated nerve fibers from frozen sections at operation, thus providing the surgeon with guidance on the extent of nerve resection. The modification presented here resulted in permanent slides, allowing comparison of results with those of the other two procedures. The new osmium-hematoxylin technique could be performed on paraffin embedded nerves. Paraffin, unlike plastic, permitted the study of the whole cross sectional area of the nerve in single sections. Moreover, the sharp image of the myelin permitted computerized morphometry. The significantly modified axonal silver impregnation technique was performed on frozen sections mounted on glass slides, as opposed to the time-consuming impregnation of free-floating sections. The latter technique had a high success rate and permitted semiquantitative assessment of axons in nerve trunks. These methods can be performed in any routine histology laboratory and resulted in greater accuracy compared to conventional methods.     

In Situ Embedding of Cell Monolayers Cultured on Plastic Surfaces for Electron Microscopy

Various procedures suitable for routine in situ embedding of cell monolayers were tested including: (1) the use of different Epon substitutes, (2) the use of different types of plas-ticware obtained from different sources, and (3) different methods of preparing capsules for sectioning. Different resins reacted differently with different plastics and type of preparation. Merck Epon substitute bound to most of the plastics tested. Ladd Epon substitute released cleanly from all plastics tested when a suitable method of preparation was used. The results show that for routine embedding of cell monolayers it is necessary to select an appropriate Epon substitute and method of preparation of capsules for the type of plasticware used. A routine method is described, with various alternative steps which can be applied when particular difficulties are encountered.     

Improved Methods for Molding, Facing and Sectioning Glycol Methacrylate Embedded Tissue Blocks

Improvements in glycol methacrylate embedding, block facing, trimming, and sectioning are described. The improvements are derived from a novel molding system, a multipurpose instrument for rapid block facing, trimming and examination, and a device for removing unwanted sections from the microtome knife while sectioning is in progress. Together, these methods facilitate specimen preparation and result in a significant reduction of the time required to prepare high resolution, very thin sections for light microscopy.     

Investigations on ultrathin cryosections from cryoprotected and non-cryoprotected tissues by electron energy loss spectroscopy: Advantages and limits of application

The use of ultrathin cryosections for ultraimmunohistochemical investigations has gained in importance as technical and methodological improvements have been achieved. The well-known disadvantages of the synthetic resin technique (e.g. antigen denaturation, washing effects) have made it necessary to look for a more gentle method. In fact, material thus prepared offers the advantage that artefacts caused by dehydration and embedding in synthetic resin can be avoided. Besides, it also has a higher antigenicity compared with material prepared by means of the synthetic resin technique.Due to the different steps of incubation one has to face loss of substance and orientation when employing cryoprotected samples. Therefore it would be best to employ non-cryoprotected samples but this is nearly impossible in the case of ultraimmunohistochemical investigations because recrystallization of ice in the tissue leads to destruction of the ultrastructure.In order to quantify the extent of the changes we have compared the elemental distribution for several light elements of cryoprotected material, which was prepared following the Tokuyasu-technique, with non-cryoprotected samples. The latter were frozen in cryogen and the ultrathin sections were carefully freeze-dried. Although the loss caused by washing is low for membrane-linked structures, cryoprotected samples lose on average 50% of the analysed elements in the course of preparation in comparison with unprotected and only freeze-dried samples.     

Frozen Sections from Bouin-Fixed Material in Histopathology

It has become almost a dogma that, for obtaining satisfactory frozen sections, fixation of the tissues in formalin is necessary; formalin is exclusively recommended for this purpose in the textbooks of microscopical and pathological technic.¹ It has, however, several important disadvantages, which become the more acutely felt when fixation in more than one fixative is impossible, as happens so often in surgical pathology. When, after the preparation of the frozen sections, embedding in paraffin is necessary, formalin-fixed tissues show a marked shrinkage, especially when rapid embedding methods (e. g. dioxane) are used. This shrinkage can only be prevented by the time-consuming hardening of the blocks in K₂Cr₂O₇. The trichrome stains, the phosphotungstic-hematoxylin stain and the azan method, which are slowly superseding the hematoxylin-eosin and van Gieson stains in histopathology, give only mediocre or inferior results after formalin fixation, unless the sections are refixed.     

Quantitative Determination of the Spatial Distribution of Nitrosomonas europaea and Nitrobacter agilis Cells Immobilized in kappa-Carrageenan Gel Beads by a Specific Fluorescent-Antibody Labelling Technique

A novel technique, combining labelling and stereological methods, for the determination of spatial distribution of two microorganisms in a biofilm is presented. Cells of Nitrosomonas europaea (ATCC 19718) and Nitrobacter agilis (ATCC 14123) were homogeneously distributed in a kappa-carrageenan gel during immobilization and allowed to grow out to colonies. The gel beads were sliced in thin cross sections after fixation and embedding. A two-step labelling method resulted in green fluorescent colonies of either N. europaea or N. agilis in the respective cross sections. The positions and surface areas of the colonies of each species were determined, and from that a biomass volume distribution for N. europaea and N. agilis in kappa-carrageenan gel beads was estimated. This technique will be useful for the validation of biofilm models, which predict such biomass distributions.     

高度木质化材料的冰冻切片技术

高度木质化植物材料的切片难度很大,应用常规切片方法不容易取得高质量的图版。本文介绍的冰冻切片方法,不需要进行长时间的软化处理、以及繁琐的脱水、包埋等过程,切片还进行不同的染色或组织化学测定,是一种快速、简捷和有效的制片方法。 其关键步骤是选好甘油浓度, 冰冻温度和展片步骤。     

高度木质化材料的冰冻切片技术

高度木质化植物材料的发片难度大,应用常规切片方法不容易取得高质量的图版。本文介绍了冰切片方法,不需要进行长时间的软化处理、以及繁琐的脱水、包埋等过程,切片还进行不同的染色或组织化学测定,是一种快速、简捷和有效的制片方法。其关键步骤是选好甘油浓度,冰冻温度和展片步骤。     

Histochemical and immunohistochemical protocols for routine biopsies embedded in Lowicryl resin

Tissue processing and analysis require good preservation of both the shape and content of cells. Lowicryl resin is one of the few embedding media that allow good preservation of both tissue architecture and cellular contents. Therefore, different histochemical and immunohistochemical reactions can be applied to semithin sister sections from one biopsy. Further examination of a zone of interest can be carried out under the electron microscope. The hydrophilic property of Lowicryl resins makes possible different histochemical reactions; however, the technique used for paraf?n sections must be adapted for each reaction. Antigenic preservation of cells by low temperature embedding allows immunolabeling on either semithin sections or in the zone of interest on ultrathin sections. We have shown the application and adaptation of different histochemical and immunohistochemical reactions on semithin and ultrathin sections from hepatic biopsies that were large, but thin. The variety of techniques that can be used on sister Lowicryl sections of a single biopsy makes this medium useful for extensive pathological studies of precious needle biopsies.     

Out with the old and in with the new: rapid specimen preparation procedures for electron microscopy of sectioned biological material

This article presents the best current practices for preparation of biological samples for examination as thin sections in an electron microscope. The historical development of fixation, dehydration, and embedding procedures for biological materials are reviewed for both conventional and low temperature methods. Conventional procedures for processing cells and tissues are usually done over days and often produce distortions, extractions, and other artifacts that are not acceptable for today’s structural biology standards. High-pressure freezing and freeze substitution can minimize some of these artifacts. New methods that reduce the times for freeze substitution and resin embedding to a few hours are discussed as well as a new rapid room temperature method for preparing cells for on-section immunolabeling without the use of aldehyde fixatives.     

Histochemical and immunohistochemical protocols for routine biopsies embedded in Lowicryl resin.

Tissue processing and analysis require good preservation of both the shape and content of cells. Lowicryl resin is one of the few embedding media that allow good preservation of both tissue architecture and cellular contents. Therefore, different histochemical and immunohistochemical reactions can be applied to semithin sister sections from one biopsy. Further examination of a zone of interest can be carried out under the electron microscope. The hydrophilic property of Lowicryl resins makes possible different histochemical reactions; however, the technique used for paraffin sections must be adapted for each reaction. Antigenic preservation of cells by low temperature embedding allows immunolabeling on either semithin sections or in the zone of interest on ultrathin sections. We have shown the application and adaptation of different histochemical and immunohistochemical reactions on semithin and ultrathin sections from hepatic biopsies that were large, but thin. The variety of techniques that can be used on sister Lowicryl sections of a single biopsy makes this medium useful for extensive pathological studies of precious needle biopsies.     

A New Time-Saving Device for Embedding in Paraffin

A simple device to be used in place of the usual paper boxes or watch crystals used for embedding in paraffin in the preparation of histological sections is described. Short lengths of cooled rubber tubing are placed on a glass surface, which has previously been painted with glycerin, and are filled with melted paraffin. The rubber tubing sections are best cut by stretching the tubing on a wooden rod and cutting while the wood is turning in a lathe.     

Immunocytochemical localization of carbonic anhydrase in the spinal cords of normal and mutant (shiverer) adult mice with comparisons among fixation methods

The peroxidase-antiperoxidase technique was used for immunocytochemical localization of carbonic anhydrase in the mouse spinal cord to detect whether this antigen was normally present in myelinated fibers, in oligodendrocytes in both white and gray matter, and in astrocytes, and to determine where the carbonic anhydrase might be localized in the spinal cords of dysmyelinating mutant (shiverer) mice. The most favorable methods for treating tissue were: 1) immersion in formalin-ethanol-acetic acid followed by paraffin embedding, or 2) light fixation with paraformaldehyde and preparation of vibratome sections. Carnoy's solution, followed by paraffin embedding, extracted myelin from the tissue, while aqueous aldehydes, when used before paraffin embedding, reduced staining everywhere except at sites of compact myelin. The latter conclusion was based, in part, on the almost complete loss of this antigen from the shiverer cord, where compact myelin is known to be virtually absent but where membrane-bound carbonic anhydrase was demonstrated enzymatically. When the optimal methods were used with normal mouse cords, carbonic anhydrase was found throughout the white matter columns and in the oligodendrocytes in gray and white matter. The staining of the white matter was attributed to myelinated fibers because of the similarity in distribution to both a histological myelin stain and the immunocytochemical staining for myelin basic protein. In the mutant mice the oligodendrocyte cell bodies and processes, which were stained in all areas of the spinal cord, were particularly numerous at the periphery of the sections. In contrast to the oligodendrocytes, the fibrous astrocytes appeared to lack carbonic anhydrase, or to have lower than detectable levels, since the astrocyte marker, glial fibrillary acidic protein, had a very different distribution from that of carbonic anhydrase. Even finer localization was obtained in vibratome sections, where the antibody against carbonic anhydrase permitted visualization of the processes connecting oligodendrocytes to myelinated fibers in the normal adult spinal cord.