A Rapid lmmunostaining Method for Frozen Sections

A simple and rapid one-step method for demonstrating immunohistochemical markers (leukocyte common antigen, cytokeratin, etc.) is described, which can help define the nature of poorly differentiated neoplasms for diagnosis using frozen section. Microwave irradiation was used to speed immunohistochemical analysis using “Enhanced Polymer One-step Staining” (EPOS) reagents on cryostat sections from a variety of pathologic samples. Reproducible results were obtained using EPOS reagents for leukocyte common antigen and cytokeratin. The overall procedure takes less than 10 min and can be completed during surgery.     

Rapid Nissl Staining for Frozen Sections of Fresh Brain

Working with X-ray film autoradiography of soluble isotopes, we needed a staining technique for the localization of nuclei in frozen sections of fresh brain. We have found no Nissl staining method in the literature concerning autoradiography specially recommended for this purpose, nor have we found in handbooks on staining a Nissl method clearly recommended for unfixed, frozen sections of brain. The methods described are intended for paraffin or celloidin sections, and require fixation of brain before sectioning (which must be avoided when working with soluble isotopes). Because autoradiography is a time-consuming method, any technique which shortens time needed for the overall procedure is welcome. Most Nissl techniques described in the literature require long preprocessing of the tissue. We found two rapid methods, described by Humason (1967) and LaBossiere and Glickstein (1976), but their application to frozen sections did not give good results. After trials with several types of techniques, we succeeded in developing two Nissl modifications with slightly different qualities, one of 12 min and the other of 2-3 h. The longer method includes conventional steps in staining; the shorter method does not include fixation or lipid extraction. These methods were applied to 20-60 μm brain sections cut in the cryostat at -10 to -12 C and dried on gelatinized slides.     

Some Improvements in the Preparation of Fresh Frozen Sections

For the histochemical demonstration of sensitive enzymes it is necessary to use fresh unfixed tissue sections. With the following procedure one can constantly obtain such sections 10-20μ thick with relative ease. Schanze's sliding microtome is employed. The microtome knife is deeply cooled by placing blocks of dry ice on its surface, and is provided with a device for preventing the sections from rolling up. The microtome is operated in an ordinary refrigerator maintained at a temperature of 0-3°C. For this purpose, the door of the refrigerator is replaced by a wooden door provided with a glass window, gloved arm holes, and a small door.     

A Rapid Plastic Embedding Technique for Preparation of Three-Micron Thick Sections of Decalcified Hard Tissue

A 24 hour start-to-finish method is described for the preparation of three-micronthick sections of decalcified hard tissues. Following acetone dehydration, the tissue to be embedded is infiltrated under vacuum with a series of graded clearing solutions which approach the content of the final methyl methacrylate mixture. After overnight in a 35 C oven, the plastic is polymerizd by four hours heating at 42 C. Three-micron-thick sections are then easily prepared using a Jung microtome for high resolution histologic or detailed autoradiographic procedures.     

An Apparatus for Rapid Attachment of Frozen Tissue to Cryostat Tissue Carriers

A brass cylindrical container 11.5 cm high and 7.5 cm in diameter was housed in an insulated wooden box. A 2.2 cm diameter hole was drilled in the centre of the removable brass lid on the underside of which a holder was attached for a cryostat tissue carrier. The container was filled with a mixture of acetone and solid CO₂ to within 1.5 cm of the lid. The frozen tissue was placed in a drop of water on a tissue carrier which was then lowered into the holder through the hole in the lid. The tissue carrier was rapidly cooled by the acetone-solid CO₂ mixture thus freezing the water and attaching the tissue to the carrier.     

The Rapid Preparation of Celloidin Serial Sections Following India Ink Injections

For the study of capillary penetration in the central nervous system of the chick embryo, following India ink injections, celloidin serial sections are superior to those prepared by the paraffin technic. The celloidin sections are arranged on a moist cigarette paper mat, which when filled is inverted and applied to a microscope slide so that the sections contact the glass surface. Subsequent to dehydration and clearing the sections are isolated on the slide by peeling off the cigarette paper. Forty-five minutes are required to prepare a slide of thirty sections from the time the block is trimmed until the cover slip is mounted with Clarite.     

A Rapid Method for Demonstrating Skeletal Muscle Motor Innervation in Frozen Sections

Longitudinal 50-100 μm-thick frozen sections of muscle are picked up on slides coated with 3% EDTA and after drying are incubated to demonstrate acetylcholinesterase. Subsequent incubation in 0.5% K₃Fe(CN)₆ is followed by fixation for 30 minutes in formol-calcium or formol-saline. After washing, the slides are incubated in 20% aqueous AgNO₃ containing 0.1% CuSO₄ for 2-30 minutes at 37 C. Following development in a 1% solution of quinol (w/v) 5% with respect to Na₂SO₃ (w/v), axons and subneural apparatus stain dark brown to black in contrast to the less well stained muscle fibers and nuclei. This procedure permits study of the pattern of neuromuscular innervation in skeletal musk 31/2-4 hours after receipt of a sample, and makes possible determination of the terminal innervation ratio.     

Rapid Preparation of Thick Sections of Fleshy Plant Tissues

Methods are described for permanent micro-slide preparations of soft, large-celled plant tissues such as ripe fruit. Thick sections (200-800 [t) cut on a sliding microtome are aspirated in an aqueous killing agent; after fixing and washing, the sections are dehydrated and cleared in an alcohol-xylene series. Infiltration with 20, 30, and 40% solutions of mountant prior to mounting the sections is necessary to avoid too abrupt changes in the cleared tissues. Several staining methods have been successfully used for different purposes. The final preparations showed nearly perfect preservation of intact cells and intercellular spaces in their 3-dimension-al structure.     

Staining Pericellular Boutons of Glutaraldehyde-Fixed Nervous Tissue; A Chromation-Silvering Sequence for Frozen Sections

After fixing in phosphate-buffered 5% glutaraldehyde, pH 6.8, by perfusion, brains were sliced to 3-5 mm pieces which were placed in the fixative for 5-7 days. The pieces were washed through several changes of 2.26% NaH₂PO₄ for 12 hr, 30 μ frozen sections cut, and mordanted 2 days in an equal-parts mixture of 3.5% CrO₃ and 5% Na-tartrate, which had been aged at 20-25 C for 20 days prior to use. After washing in distilled water, the sections were put into a solution containing AgNO₃, 20 gm; and KNO₃, 15 gm, in distilled water, 80 ml; at 30 C for 1.5-2 hr, then reduced at 40-45 C in three pyrogallol solutions as follows: 1-2 sec in 1% pyrogallol in 55% alcohol; 3-4 sec in a 0.67% solution in 33% alcohol, and 5-7 sec in a 0.5% solution in 25% alcohol. Gold toning is optional; dehydration, clearing and covering, routine. The technic shows particularly the perisomatic fibers, boutons en passant and boutons termineaux. Fibers in nerve tracts may be visible but lightly stained; cell nuclei may be dark, but the cytoplasm remains pale.     

Mounting Frozen Sections with Gelatin

Frozen sections, 15-50 µ thick, are soaked for 5 minutes or longer in a mixture of equal parts of 1.5% aqueous gelatin and 80% alcohol, and teased onto a slide. After allowing excess fluid to evaporate, sections will be moist and can be blotted with filter paper that may require dampening with 95% alcohol. Immersed in 95% alcohol, the remaining gelatin will congeal, anchoring the section to the slide. If necessary, the sections can subsequently be coated with celloidin.     

Rapid Otan Method for Localizing Unsaturated Lipids in Lung Tissue Sections

The OTAN treatment, which is the only histochemical method available at present for the simultaneous localization of hydrophobic and hydrophilic unsaturated lipids in tissue sections, requires unduly long exposure to O₃O₄ and use of free-floating sections, which makes handling the sections difficult and often results in their loss or damage. Simple modifications using O₃O₄ treatment at 37 C and slide-mounted sections eliminate the practical drawbacks of the existing method and provide as good or better localization in less than one-eighth of the time. The modified method is applicable to fixed as well as fresh frozen tissues.     

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.