Producing Frozen Sections of Calcified Bone

We describe a procedure for the rapid production and maintenance of fresh frozen bone biopsies which can be used for a variety of immunohistochemical techniques. Within 5 min of excision. tissue is placed in cold 5% polyvinyl alcohol, surrounded with 3% carboxymethylcel-lulose in a hand made aluminum foil embedding mold and frozen by immersion in an absolute ethanol/dry ice slurry at -70 C. The tissue block is attached to the specimen stub with cryocom-pound and installed in a -32 C cryostat whose tungsten carbide D profile knife is maintained at -70 C. Automatic controls are set at a slow cutting speed and the “sectioning window” is adjusted to fit the biopsy size. Knife angle, thickness gauge and antiroll bar are changed to produce a complete section. The block face is smoothly “papered” with a polyvinylpyrrolidone (PVP) impregnated Ross lens paper strip. A single section is cut and positioned on a sequentially numbered, acid cleaned, double dipped chrome-alum gelatin coated slide: adhesion is aided by “press-blotting” with bibulous paper. Sections are stored at -20 C or in a desiccator at room temperature. A brief fixation followed by removal of the water soluble PVP and lens paper generates fresh frozen bone sections suitable for further analysis.     

Direct tissue isoelectric focusing on mini ultrathin polyacrylamide gels followed by subsequent western blotting, enzyme detection, and lectin labeling as a tool for enzyme characterization in histochemistry.

Application of cryostat sections directly onto mini ultrathin polyacrylamide isoelectric focusing gels allows an elution of proteins out of the sections into the gels under conventional focusing conditions. Protein bands representing alkaline phosphatases can easily be identified on nitrocellulose after performing a modified Western blot procedure. Furthermore, carbohydrate residues of several isoforms of alkaline phosphatases separated by isoelectric focusing can be demonstrated in a single blot strip by subsequent incubation of this strip with substrates for alkaline phosphatase and peroxidase, the latter being employed as the enzyme to which the applied lectins are covalently linked. This simple and reproducible procedure is likely to enable histochemists to determine isoforms of enzymes from a single cryostat section.     

Staining method for whole-body autoradiography.

Sagittal whole-body sections of frozen mice were cut on a hydraulicly driven microtome in a cryostat at--15 C by applying cotton or nylon-backed adhesive tape to the mouse before cutting. Section thickness was 20 mu. The sections, still adhering to the tape, were dried in the cryostat (-15C) under atmospheric pressure. After autoradiography, the sections were pressed to a glass slide spread with a mixture of albumin and glycerin. The slide was immersed in xylene at 30 C for 15 min. The tape was then removed from the slide, where the section remained to be stained with hematoxylin-eosin. The section thus obtained enabled the tissue histology to be related to the autoradiogram. This method may also be applied to histochemical studies of substances insoluble in xylene.     

Enzyme histochemical reactions in unfixed and undecalcified cryostat sections of mouse knee joints with special reference to arthritic lesions

Summary The use of unfixed and undecalcified cryostat sections of mouse knee joints is described for the study of enzyme histochemical reactions. Non-inflamed knee joints and knee joints of mice with antigen induced arthritis have been used. Joints were embedded in gelatin and subsequently cut at low speed with a motor-driven cryostat fitted with a tungsten carbide knife at an obtuse angle (10°). The sections were attached to transparent tape to keep the integrity of the tissue intact. The following histochemical reactions were carried out succesfully: the tetrazolium salt reaction for dehydrogenase and reductase activity, the post-azocoupling method for acid phosphatase and cathepsin B activity and the simultaneous azo-coupling method for esterase activity. In all cases the morphology and integrity of the sections were well kept and serial sections were obtained without any difficulty. Nonspecific staining of the tape did not occur. The localization of the final reaction product was meeting criteria for specific and precise histochemical methods with the exception of the metal salt method because of nonspecific staining of undecalcified bone. Cytophotometry of the final reaction product appeared to be reproducible and valid as demonstrated by reaction for glucose-6-phosphate dehydrogenase activity in synoviocytes from knee joints with induced arthritis. End point measurements as well as kinetic measurements of the formazan production were performed and linear relationships were found between the specific formazan formation and section thickness or incubation time, respectively. It is concluded that cryostat sections attached to transparent tape are an excellent tool for the study of the metabolism in tissues adjacent to bone matrix. Changes of enzyme activities in synoviocytes, chondrocytes and osteoclasts during induced arthritis are discussed.     

Enzyme histochemical reactions in unfixed and undecalcified cryostat sections of mouse knee joints with special reference to arthritic lesions

The use of unfixed and undecalcified cryostat sections of mouse knee joints is described for the study of enzyme histochemical reactions. Non-inflamed knee joints and knee joints of mice with antigen induced arthritis have been used. Joints were embedded in gelatin and subsequently cut at low speed with a motor-driven cryostat fitted with a tungsten carbide knife at an obtuse angle (10 degrees). The sections were attached to transparent tape to keep the integrity of the tissue intact. The following histochemical reactions were carried out successfully: the tetrazolium salt reaction for dehydrogenase and reductase activity, the post-azo-coupling method for acid phosphatase and cathepsin B activity and the simultaneous azo-coupling method for esterase activity. In all cases the morphology and integrity of the sections were well kept and serial sections were obtained without any difficulty. Nonspecific staining of the tape did not occur. The localization of the final reaction product was meeting criteria for specific and precise histochemical methods with the exception of the metal salt method because of nonspecific staining of undecalcified bone. Cytophotometry of the final reaction product appeared to be reproducible and valid as demonstrated by reaction for glucose-6-phosphate dehydrogenase activity in synoviocytes from knee joints with induced arthritis. End point measurements as well as kinetic measurements of the formazan production were performed and linear relationships were found between the specific formazan formation and section thickness or incubation time, respectively. It is concluded that cryostat sections attached to transparent tape are an excellent tool for the study of the metabolism in tissues adjacent to bone matrix.(ABSTRACT TRUNCATED AT 250 WORDS)     

Measuring the resolution of uncompressed plastic sections cut using an oscillating knife ultramicrotome

Thin sections of biological tissue embedded in plastic and cut with an ultramicrotome do not generally display useful details smaller than approximately 50 A in the electron microscope. However, there is evidence that before sectioning the embedded tissue can be substantially better preserved, which suggests that cutting is when major damage and loss of resolution occurs. We show here a striking example of such damage in embedded insect flight muscle fibres. X-ray diffraction of the embedded muscle gave patterns extending to 13A, whereas sections cut from the same block showed only approximately 50 A resolution. A possible source of this damage is the substantial compression that was imposed on sections during cutting. An oscillating knife ultramicrotome eliminates the compression and it seemed possible that sections cut with such a knife would show substantially improved preservation. We used the oscillating knife to cut sections from the embedded muscle and from embedded catalase crystals. Preservation with and without oscillation was assessed in Fourier transforms of micrographs. Sections cut with the knife oscillating did not show improved preservation over those cut without. Thus compression during cutting does not appear to be the major source of damage in plastic sections, and leaves unexplained the 50 A versus 13A discrepancy between block and section preservation. The results nevertheless suggest that improvements in ultramicrotomy will be important for bringing thin-sectioning and tomography of plastic-embedded cells and tissues to the point where macromolecule shapes can be resolved.     

The Rapid Preparation of Frozen Tissue Sections

The essential feature of this procedure involves the rapid freezing of the tissue following excision and keeping it frozen until the desired chemical or fixative has been applied. For freezing, either carbon dioxide or liquid air is used, as desired. The microtome knife is thoroughly cooled by taping blocks of dry ice to its surface. The cut sections, still frozen, are manipulated by a camel's hair brush so that they lie flat upon the knife. They are then transferred to a slide by a special section lifter. This has the form of a double-bottomed scoop packed with dry ice. Thus the section remains frozen while it is transferred to a clean microscope slide held at an angle above a Coplin jar of the desired reagent. The sections must be immersed just prior to melting. They curl and do not adhere to the slide if still rigidly frozen, and are distorted if immersed after melting.

With this technic sections showing a minimum of cellular distortion may be obtained. Consequently, it facilitates the use of many cytological technics, chemical tests, and enzymatic studies, such as the Gomori technics, on a variety of tissues.     

Sections from Double Mesas Obtained at the Same Tissue Plane

A method for obtaining sections from two areas in the face plane of a tissue block is described. It facilitates ultrathin sectioning where virtually identical planes of section are essential but where areas of interest are too far apart to be included in a single section. Two horizontally separated mesas are prepared; sections are cut from the first with the knife rotated around its vertical axis by 2-3° to provide clearance for the other. The second mesa is then sectioned with the knife rotated 4-6° in the opposite direction. Similarly, by changing the vertical inclination of the block, two additional vertically separated mesas can be cut. This procedure is of great value for comparative morphometric studies of material from opposite sides of individual specimens.     

Sections from double mesas obtained at the same tissue plane

A method for obtaining sections from two areas in the face plane of a tissue block is described. It facilitates ultrathin sectioning where virtually identical planes of section are essential but where areas of interest are too far apart to be included in a single section. Two horizontally separated mesas are prepared; sections are cut from the first with the knife rotated around its vertical axis by 2-3 degrees to provide clearance for the other. The second mesa is then sectioned with the knife rotated 4-6 degrees in the opposite direction. Similarly, by changing the vertical inclination of the block, two additional vertically separated mesas can be cut. This procedure is of great value for comparative morphometric studies of material from opposite sides of individual specimens.     

Techniques for Studying Adipocytes

Various fixatives as well as tissue and slide handling procedures have been evaluated in attempts to demonstrate adipocytes histochemically while maintaining cell and tissue integrity. The optimal procedure for analysis of immature adipose depots consists of the following steps: 1) fresh, unfixed tissues are frozen rapidly in isopentane quenched in a liquid nitrogen bath; 2) cryostat sections are cut, removed from the knife with a room temperature slide, and then air dried for 5-10 minutes; 3) slides can be stained directly with picro-Ponceau or toluidine blue procedures or with oil red O following fixation for 30 minutes in cold (4 C) 10% formalin-CaCl₂ (1.25%). For analysis of mature rat adipose depots steps 2 and 3 are modified as follows: 2) cryostat sections are removed from the knife with a cold slide (-20 C) and dried for 30 minutes at 4 C; 3) the mounted sections are stained with oil red O following fixation for 30 minutes in cold (4 C) 10% formalin-HgCl₂ (2.5%). When procedures described above for immature adipose depots are combined with esterase fining, adipocyte cytoplasm is clearly demonstrated. These procedures allow the routine use of fresh frozen, unfixed cryostat sections in studies of adipose cellularity.     

A new method of preparing embeddment-free sections for transmission electron microscopy: applications to the cytoskeletal framework and other three-dimensional networks

Diethylene glycol distearate is used as a removable embedding medium to produce embeddment -free sections for transmission electron microscopy. The easily cut sections of this material float and form ribbons in a water-filled knife trough and exhibit interference colors that aid in the selection of sections of equal thickness. The images obtained with embeddment -free sections are compared with those from the more conventional epoxy-embedded sections, and illustrate that embedding medium can obscure important biological structures, especially protein filament networks. The embeddment -free section methodology is well suited for morphological studies of cytoskeletal preparations obtained by extraction of cells with nonionic detergent in cytoskeletal stabilizing medium. The embeddment -free section also serves to bridge the very different images afforded by embedded sections and unembedded whole mounts.     

Techniques for studying adipocytes

Various fixatives as well as tissue and slide handling procedures have been evaluated in attempts to demonstrate adipocytes histochemically while maintaining cell and tissue integrity. The optimal procedure for analysis of immature adipose depots consists of the following steps: 1) fresh, unfixed tissues are rapidly in isopentane quenched in a liquid nitrogen bath; 2) cryostat sections are cut, removed from the knife with a room temperature slide, and then air dried for 5-10 minutes; 3) slides can be stained directly with picro-Ponceau or toluidine blue procedures or with oil red O following fixation for 30 minutes in cold (4 C) 10% formalin-CaCl2 (1.25%). For analysis of mature rat adipose depots steps 2 and 3 are modified as follows: 2) cryostat sections are removed from the knife with a cold slide (-20 C) and dried for 30 minutes at 4 C; 3) the mounted sections are stained with oil red O following fixation for 30 minutes in cold (4 C) 10% formalin-HgCl2 (2.5%). When procedures described above for immature adipose depots are combined with esterase staining, adipocyte cytoplasm is clearly demonstrated. These procedures allow the routine use of fresh frozen, unfixed cryostat sections in studies of adipose cellularity.     

The chemical determination of section thickness

Summary In quantitative histochemistry it is frequently desirable to know the exact thickness of the sections. The nucleic acid content of the tissue has been used as the basis of a method for determining section thickness. Such determinations agree remarkably well with the setting on the cryostat microtome although considerable variations in thickness can occur in sections cut at different speeds.     

The light-induced unrolling of the grass leaf — A study of polarity, light-piping and stimulus transmission

Primary leaves of dark-grown barley ( Hordeum vulgare L. cv. Weibull's Ida) unroll in darkness when cut into sections shorter than about 2 cm; the shorter the more unrolling. The unrolling pattern of irradiated leaf sections longer than about 2 cm indicates a polarity in the leaves: the top end of the basal section of a divided leaf unrolls more than the base end of the distal section. Earlier reported findings of a stimulus transmission from irradiated to non-irradiated areas can be fully explained by light-piping and by mechanical, mutual influence between irradiated and non-irradiated areas.     

Plastic Embedding, Orientation in the Mold and Tape-Supported Sectioning of Sclerotized Insects and Other Hard Objects

Sections of large specimens such as whole honeybees or beetle adults embedded in plastic usually are difficult to cut with a constant thickness. The sections also compress and roll. Sections of even thickness have been obtained by using a mixture of methacrylates (ethyl, 1:butyl, 3) and by firmly supporting the block in the microtome with a special holder. Scotch tape #810 applied to the block before each section is cut eliminates section compression and rolling. The sections are attached to slides with 2% celloidin in an absolute alcohol-methyl benzoate mixture (5:5-7:3); and the tape is removed with heptane. Large sections can also be cut from blocks of styrene mixed with butyl methacrylate. The specimens are oriented in the monomer in gelatin capsules by directing them into the desired plane among the fibers of a wad of absorbent cotton previously placed in the bottom of the capsule. The cotton is sectioned with the specimen but its fibers do not interfere, and remain outside the tissue.     

Oriented Embedding of Single-Cell Organisms

The dexribed technique facilitates oriented embedding of individual cells in various media for both light and electron microscopy. A fixed Specimen is embedded in a small cube of 2% agar at 40 C and subsequently sealed in the desired orientation to a strip of black paper which then serves as a tab for transferring the specimen during dehydrating and embedding procedures. The beveled ends of the strip indicate the exact location of the specimen in the cube. This technique can be employed for the embedding media used in both light and electron microscopy. It ah permits photomicrographs of the whole specimen to be made which can be compared with photomicrographs of individual sections cut from the specimen in a selected plane.     

Thin sectioning of slice preparations for immunohistochemistry

Many investigations in neuroscience, as well as other disciplines, involve studying small, yet macroscopic pieces or sections of tissue that have been preserved, freshly removed, or excised but kept viable, as in slice preparations of brain tissue. Subsequent microscopic studies of this material can be challenging, as the tissue samples may be difficult to handle. Demonstrated here is a method for obtaining thin cryostat sections of tissue with a thickness that may range from 0.2-5.0 mm. We routinely cut 400 micron thick Vibratome brain slices serially into 5-10 micron coronal cryostat sections. The slices are typically first used for electrophysiology experiments and then require microscopic analysis of the cytoarchitecture of the region from which the recordings were observed. We have constructed a simple device that allows controlled and reproducible preparation and positioning of the tissue slice. This device consists of a cylinder 5 cm in length with a diameter of 1.2 cm, which serves as a freezing stage for the slice. A ring snugly slides over the cylinder providing walls around the slice allowing the tissue to be immersed in freezing compound (e.g., OCT). This is then quickly frozen with crushed dry ice and the resulting wafer can be position easily for cryostat sectioning. Thin sections can be thaw-mounted onto coated slides to allow further studies to be performed, such as various staining methods, in situ hybridization, or immunohistochemistry, as demonstrated here.     

Interferometric analysis of intrasection and intersection thickness variability associated with cryostat microtomy

Summary Mach-Zehnder interferometric measurements were used to assess the extent of section thickness variability (inter- and intrasection) associated with cryostat microtomy of adrenal sections over a typical working range of 10–20 m. Sections were obtained using a Bright's Cambridge rocking type and a Damon rotary type cryostat microtome to allow comparative analyses. The effective thickness of tissue sections after being mounted onto slides by flash drying was reduced by 90% relative to microtome section thickness setting. A linear relationship between measured thickness and microtome setting was obtained with both instruments. Thickness variability between replicate sections over the range of microtome settings approximated 11% for the rocking microtome and 5% with the rotary microtome. Average intrasection variability was found to be 7% for rocking microtome sections and 4% for sections obtained with the rotary microtome. However, this variability is a negligible source of error in cytophotometric analyses, providing replicate sections are used and an adequate number of measurements are made on mask-delimited individual cells or tissue specimen areas.     

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.     

Photographic Mapping of a Tissue Surface to Locate Fields for Electron Microscopy; Mouse Lung

Precise sampling from whole lobes of mouse lungs fixed in the inflated state and embedded in epoxy resin can be not only feasible but also efficient. A 1 μm section is cut from an embedded lobe with a rotary microtome and a steel knife. This section is stained and photographed, and from it a 35 × enlarged print is prepared. A grid of transparent plastic scored with 35 mm squares, lettered vertically and numbered horizontally, is superimposed over the photograph. The area chosen for electron microscopy thus becomes identifiable by a letter-number designation obtained from the grid. This area is then located by light microscopy on a 2 mm slice taken from the block from which the 1 μm section was cut, by use of oblique illumination and the calibrated mechanical stage of the light microscope. A block of 1.3 mm diameter is removed for electron microscopy from the tissue by a rotatable circular spring-loaded punch screwed into the objective turret of the microscope. The removed cylinder is mounted on a metal stub and ultrathin sections cut from the faced tissue. The method is as equally suitable for the examination of other tissues, particularly when large areas and multiple sampling may be required.