Histochemical Demonstration of Enzyme Activities in Plastic and Paraffin Embedded Tissue Sections

Histochemical staining for enzymes is usually performed on frozen sections. This report lists the longer incubation times required to demonstrate esterase, acid phosphatase, β-galactosidase, and cytochrome oxidase in plastic embedded and routine paraffin embedded tissues. The sections embedded in plastic, i.e. water soluble methacrylate (Polyscience's JB-4) and cut at 2 μm, were far superior to frozen Sections and paraffin embedded sections both in tissue detail and in the localization of the histochemical reaction product.     

A Teflon Disk for Processing Loose Serial Celloidin Sections

Celloidin sections are routinely used for Nissl, Golgi, or Golgi-Cox staining (e.g., Glaser and Van der Loos 1981) when sections thicker than 30 μm are required. In spite of the advantages of the celloidin method (see Voogd and Feirabend 1981, Buschke 1979), processing free-floating serial sections of celloidin embedded material, which may often be preferred, is not very convenient.     

A Method for the Preparation of Undecalcified Bone Sections for Light Microscopy and Microradiography

A method which gives good quality 1-2 μm thick sections of undecaldfied cancellous and thin cortical bones for light miuoscopy is described. Formalin fixed material is dehydrated in graded acetones and embedded in a modiEed formula of Spurr's low viscosity embedding medium. After a 16 hour polymerisation period at 60 C, sections are cut at 1-2 μm thickness on a Porter-Blum JB4A rotary microtome Using glass knives. Sections are attached to clean glass slides with heat, the resin degraded in bromine vapour and removed in acetone. This allows comparative ease of staining. The technique is rapid, does not interfere with tetracycline fluorescence and the same specimens can be used to prepare thick sections for microradiography.     

Diaminobenzidine as a Myelin Stain in Semithin Plastic Sections

A diaminobenzidine (DAB) stain for myelin in glutaraldehyde fixed, osmicated, semithin epoxy sections is described. One or 1.5 μm sections, dried onto slides, are first etched with a 1:2 dilution of saturated sodium ethox-ide:absolute ethanol, then incubated in 0.05% aqueous DAB with 0.01% hydrogen peroxide. DAB specifically stains osmium fixed myelinated nerve fibers. This permits high resolution light microscopic study of myelinated nerve fibers in semithin sections of tissues that also can be studied by electron microscopy.     

Hematoxylin Toluidine Blue-Phloxinate Staining of Glycol Methacrylate Sections of Retina and Other Tissues

For a detailed study of the developing chick retina a technique has been developed using glycol methacrylate embedding and a hematoxylin toluidine blue-phloxinate stain. After removal of the vitreous body, one half-segment of the eye is dehydrated through graded ethyl alcohols to 95%, infiltrated and embedded in glycol methacrylate, and sectioned at 2 μm. The sections are stained in alum hematoxylin and then in a mixture containing toluidine blue-phloxinate from a stock solution of the dye that has matured for 2-3 weeks. Differentiation is not required and there is only slight staining of the plastic matrix. The quality and clarity of the sections contrasts markedly with that of similarly stained 5 μm paraffin wax sections of the retina. This technique has also been applied to skin, spinal cord, dorsal root ganglia, pancreas and small intestine. The stained sections from these tissues have proved very useful in revealing structural components.     

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.     

Notes on Technic: “Clearing” Steel Knife Epon Sections in a Polystyrene Film Sandwich

Serial sectioning epoxy embedments by steel knife permits rapid light microscope survey of large tissue volumes, and preselection of areas of interest for electron microscopy. Acetate film (Hollander 1970) and Turtox plastic slides (West 1972) have been suggested as substrates upon which the sections may be “cleared” with an added layer of cured epoxy. In our experience, these substrates are excessively adherent to Epon, and “cleared” sections thinner than 40-50 μm cannot be released from them reliably. The following method is suitable for processing Epon sections 10 or more microns thick.     

Wrinkle-Free Plastic Sections for Light Microscopy

Plastic sections 0.5 to 2 μm thick are routinely used for light microscopy. Although plastic sections have several advantages over paraffin or celloidin sections, a problem that is often encountered with plastic sections is wrinkling (Fig. 1). Wrinkling occurs during staining when sections dried on glass slides are covered with stain and heated to hasten the penetration of the stain. Mounted sections heated on glass slides, but not stained, ordinarily lack wrinkles, even when examined with phase contrast optics. Similarly, mounted sections covered with stain, but not heated, lack wrinkles; unfortunately, such sections fail to stain adequately. Unmounted sections floated on heated drops of stain also lack wrinkles (Millonig 1980). Thus, it is clear that wrinkling occurs only when mounted sections are covered with stain and heated.     

A Method for Histological Preparation of Undecalcified Bone Sections Containing Acrylic Bone Cement

An improved and time reducing method is presented for the histological evaluation of bone containing polymethylmethacrylate (PMMA) bone cement. The undecalcified bone was embedded in epoxy resin and sections of 50-100 μm thickness were produced using a commercially available cutting grinding system. The sections were stained with Stevenel's blue and van Gieson picrofuchsin or a modified hematoxylin-eosin. PMMA bone cement was not dissolved and remained enabling examination in situ of an intact cement bone interface and tissue reaction without decalcification.     

Plastic Embedding of thick Celloidin Sections of nerve Tissue

A method is described for mounting Golgi-impregnated and Weigert-stained thick celloidin sections of brain and spinal cord in transparent plastic. Finished mounts have good optical properties and are suitable for macroscopic and microscopic observation. The durability of such preparations makes them superior to similar material prepared by the more conventional methods. Holes of suitable size were cut in matrices of 2.5 × 5 × 3/16 inches Plexiglas. Ward's Bio-plastic was used to form a base for the holes and also as the embedding medium for the sections. Plate glass formed a working substrate and gave a polished surface to the plastic base and later to the top of the preparation. For Golgi material (200μ) the celloidin was removed by dioxane. A dioxane-plastic bath preceded plastic embedding. For Weigert material (30-40μ) celloidin was not removed due to fragility of sections. Prior to plastic embedding, they were subjected first to benzol and then to a benzol-plastic bath.     

Rapid Three-Dimensional Reconstruction at the Light Microscopic Level and a Technique for Re-Embedding the Same Semithin Sections for Electron Microscopic Examination

Rapid three-dimensional reconstruction of serial sections at the light microscopic and ultrastructural levels was accomplished using a two-step technique. Fixed specimens were embedded in Epon and 1 μm sections were cut and placed on glass slides. One of every four sections was drawn onto transparency film for rapid three-dimensional reconstruction. The semi-thin sections were re-embedded in Epon and sectioned at 90 nm for examination in the electron microscopy.     

Giemsa Poststaining of Sections Stained for Acetyl-Cholinesterase Improves Sensitivity and Contrast

During investigations into the cholinergic innervation of blood vessels in skeletal muscle, it was found that poststaining of sections with Giemsa's stain (Gurr, R66) after incubation to reveal acetylcholinesterase activity as copper ferrocyanide (El-Badawi and Schenk 1967) not only produced nuclear and cytoplasmic counter-staining, but also resulted in intensification of the reaction, resulting in deep blue-black nerve endings (Fig. 1). Areas previously distinguishable only by phase contrast were easily recognizable after Giemsa staining. The method described was originally used on 10 μm cryostat sections, pre- or postfixed in formolcalcium and stained in the reaction mixture described by El-Badawi and Schenk (1967) for 30-60 minutes. After rinsing in distilled water (5 min), sections were stained in Giemsa's stain (3 min), washed well in distilled water, rapidly dehydrated, cleared and mounted.     

Paraffin Section Thickness—A Direct Method of Measurement

Paraffin section thickness may be directly measured by re-embedding the sections wider consideration, cutting them again at right angles to the original plane of sectioning, and taking direct measurements with a filar micrometer after staining and mounting. Conditions and materials with which relatively un-distorted 3 and 5 μ sections were secured include (a) a hand-honed knife with a 23° facet bevel, set at a clearance angle of 7°, and (b) a hard paraffin (56-58°) embedding medium, preferably with 5% beeswax and 5% bayberry wax added. By taking direct measurements, it was found that bull testis tissue cut at a microtome setting of 10μ averaged 10.82 μ in thickness. Settings of 5 μ and 3 m resulted in sections averaging 5.25 and 3.31 μ in thickness respectively. Stages in sporogenesis of Onoclea sensibilis, Lewitsky fixed, were examined after sectioning at settings of 10, 5, and 3 μ to determine necessity for thin sections. For this material, it was indicated that mitochondrial preparations as thick as 10 μ were worthless, regardless of good fixation and proper staining. Three-micron sections give the best results.     

Demonstration of Sensory-Motor Innervation of Postmetamorphic Forelimb Regenerates of Triturus Alpestris (Urodela) on Cryotome Serial Sections Using Horseradish Peroxidase

A method has been developed to obtain horseradish peroxidase-treated serial sections containing spinal cord as well as bilateral ventral and dorsal roots, dorsal root ganglia and spinal nerves. Young postmetamorphic newts (Triturus alpestris) served as experimental animals. After cryotome cross sectioning the forelimb region of the trunk, slices 80 μm in thickness were mounted serially with up to 15 sections per slide. This facilitated subsequent staining manipulations and made partial loss of sections less likely.     

Visualization of Legionella Pneumophila in Paraffin Sections using Hexamine Silver

A modification of Gomori's hexamine silver technique is given as a simple, reliable method for the nonspecific demonstration of Legionella pneumophila in paraffin sections. When tested against serogroups I to VI it was found that pretreatment with potassium dichromate rendered L. pneumophila demonstrable by the Gomori-Burtner hexamine silver solution when buffered to pH 7.8. Tissue was fixed in 10% buffered formalin and sections were cut at 3-5 μm. After treatment with 10% potassium dichromate for 1 hour at room temperature, sections are placed in the silver solution at 56 C until they develop a pale golden yellow color, at which point they are checked periodically under the microscope for optimal staining (approximately 3-4 hours). Sections are then toned, fixed and counterstained in 1% neutral red. The L. pneumophila coccobacilli stain black against a clear background, while nuclei stain red/black.     

Cutting Unfixed Frozen Sections for Fluorescence Antibody Studies

A simplified method of section cutting, dispensing with guide attachment on microtome blade, and suitable for serial sections of unfixed frozen tissue of 4μ is described. Essential features are low temperature maintenance (—13°C), critical angle of knife and moistening of slides in cold alcohol or isopentane. This method has been found suitable for fluorescence antibody studies where maintenance of low temperatures is necessary.     

Preparation of Large Epoxy Sections for Light Microscopy as an Adjunct to Fine-Structure Studies

Tissue blocks 2 × 2 × 0.4 cm were fixed 6-24 hr in phosphate-buffered 5% glutaraldehyde then sliced to 2 × 2 × 0.1 cm and soaked in 0.1 phosphate-buffer (pH 7.3) for at least 12 hr. Fixation was continued for 2 hr in phosphate-buffered 1-2% OsO₄. The slices were dehydrated, infiltrated with Araldite, and embedded in flat-bottomed plastic molds. Sectioning at 1-8 μ with a sliding microtome was facilitated by addition of 10% dibutylphthalate to the standard epoxy mixture. The sections were spread on warm 1% gelatin and attached to glass slides by drying, baking at 60 C, fixing in 10% formalin or 5% glutaraldehyde and baking again. Sections were mordanted in 5% KMnO₄ (5 min), bleached with 5% oxalic acid (5 min) and neutralized in 1% Li₂CO₃ (1 min). Several stains could then be applied: azure B, toluidine blue, azure B-malachite green, Stirling's gentian violet, MacCallum's stain (modified), tribasic stain (modified) and phosphotungstic acid-hematoxylin. Nuclei, mitochondria, specific granules, elastic tissue or collagen were selectively emphasized by appropriate choice of staining procedures, and cytologic detail in 1-3 μ sections was superior to that shown by conventional methods. Selected areas from adjacent 4-8 μ sections could be re-embedded for ultramicrotomy and electron microscopy.     

An Improved Polychrome Staining Method for Thick Epoxy Sections

Improved polychrome staining of 1-1.5 μm epoxy sections is achieved with sequential applications of a single basic fuchsin-methylene blue mixture at two different pH values. The dye solution is applied for 2-3 min at 50-52 C first at pH 7.9, then at pH 6.7. In sections of mouse mammary tissue, epithelial ells are stained deep blue, connective tissue pink, and fat ells bright olive-green. This simple technique consistently yields uniform, vivid, contrasting colors that sharply delineate the elements of the complex glandular architecture of the mammary gland. Similar polychromatic effects are obtained in applications to other tissues, such as stomach, adrenal gland, mammary tumor and artery.     

Pyronin Y For Staining Stripped Autoradiographs Prepared from Plastic Embedded Sections of Rat Tissues Containing Plutonium

Autoradiography prepared by the stripping film technique from 1 μm sections of semithin plastic embedded liver and bone tissues were poststained for examination with a 1% pyronin Y solution. The use of this dye avoids heating the tissue section and the overlying photographic emulsion. It also allows the staining of the tissue section without excessive uptake of the stain by the gelatin of the stripping film.     

Surface Staining of Sawed Sections of Undecalcified Bone Containing Alloplastic Implants

A simple new method is described for the histological evaluation of bones containing alloplastic implants of ceramic and/or metallic materials. the undecalcified bone is embedded in acrylic resin and section at 50-200 μm using a sawing microtome. One surface of the preparation is stained up to 10 μm deep by floating the preparation on Giemsa stain. Other staining procedures are possible. Microscopic detail is Satisfactory for histological and morphometric evaluation.