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.     

Glycol for Controlling Evaporation in Mounting of Frozen Brain Sections

Mounting individual frozen sections which are wrinkle free requires manipulations which expose them to fragmentation. Large and fragile sections are especially vulnerable. We wish to report a method which minimizes handling and damage to these sections during mounting. The techniques described by Heringa and ten Berge (1923), Iwanoff (1936), Albrecht (1954) and Case (1969) have been used successfully for many years but require blotting or transfer to ethanol solutions and as a result sections may be lost or damaged and wrinkles which develop may be difficult to avoid during rapid or at times uneven drying.     

Alginate Gel; An Embedding Medium for Facilitating the Cutting and Handling of Frozen Sections

Small pieces of formalin-fixed tissue are infiltrated first with a 1% and then with a 2% solution of a low viscosity sodium alginate (a salt of a polymannuronic acid obtained from seaweed). This tissue is then transferred to a solution of a high molecular weight sodium alginate containing colloidally dispersed tricalcium phosphate. When a freshly prepared solution of gluconolactone is added, a calcium alginate gel is gradually formed—the lactone slowly hydrolyses to produce the free acid which liberates calcium ions from the colloidal phosphate. A block of gel containing the tissue is then cut out. If desired, it can be further hardened in a buffered calcium acetate solution and its cutting properties improved by soaking in 20% alcohol. At room temperature, enzymes such as the cholinesterases and phosphatases are not affected, but the procedure can be carried out at 0° C if desired. The gel does not crack and makes possible the cutting of coherent, serial frozen sections of many tissues. The alginate preparations used were supplied by Messrs. Alginate Industries Limited, Walter- House, Bedford Street, Strand, London, W.C.2.     

Cutting Frozen Sections on a Paraffin Microtome

Into a hole drilled in a block of dry ice, a metal microtome object disk is placed to cool. A drop of water is placed on the disk, and the specimen to be cut is fixed in place. By setting the dry ice in a well-insulated box, the specimen is thoroughly frozen. The disk is then clamped in the microtome, and chips of dry ice are wedged between the metal disk and the object clamp of the microtome. This ensures the continued cooling of the specimen while the tissue is being cut.     

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.     

Indirect Immunofluorescence on Frozen Sections of Mouse Mammary Gland

Indirect immunofluorescence is used to detect and locate proteins of interest in a tissue. The protocol presented here describes a complete and simple method for the immune detection of proteins, the mouse lactating mammary gland being taken as an example. A protocol for the preparation of the tissue samples, especially concerning the dissection of mouse mammary gland, tissue fixation and frozen tissue sectioning, are detailed. A standard protocol to perform indirect immunofluorescence, including an optional antigen retrieval step, is also presented. The observation of the labeled tissue sections as well as image acquisition and post-treatments are also stated. This procedure gives a full overview, from the collection of animal tissue to the cellular localization of a protein. Although this general method can be applied to other tissue samples, it should be adapted to each tissue/primary antibody couple studied.     

A Plastic-Seal Method for Mounting Sections of Ground Bone

If sections of ground bone are first coated with a plastic solution before applying the usual mounting medium and a cover glass, excellent optical differentiation results. The solution consists of 28 g. of Parlodion dissolved in 250 ml. of either butyl or amyl acetate. Bone sections are prepared by grinding to the desired thinness, dehydrated with alcohol, air dried, dipped in the solution, freed of surface bubbles by agitation, and placed on a slide. After allowing the preparation to dry thoroughly, the customary mounting medium and cover glass are applied. The plastic seal prevents the escape of air from the lacuni and canaliculi, preserves the natural differentiation of bone tissue, and also permits it to be viewed with a polarizing microscope.     

Mounting and Thionin Counterstaining of Fink-Heimer-Stained Sections of Dog Brain

The efficient use of thionin as a counterstain for large sections stained by the Fink-Heimer procedure (1967) requires mounting on slides before applying the thionin. The following modifications of the standard methods are recommended.     

Fluorescent Staining of Juxtaglomerular Cells in Frozen Sections

Enzymatic investigations of the juxtaglomerular apparatus often creates the need for visualisation of granulated juxtaglomerular cells (JGC) in preparations subjected to histochemical procedures. In our investigations, Pitcock and Hartroft's (1958) modification of Bowie's method and the Endes et al. (1969) combined trichrome staining proved to be inadequate when applied to fresh cryostat sections, or to formol- or glutaraldehyde-fixetl, gum sucrose-impregnated frozen sections. Friedberg and Reid's (1966) crystal violet procedure for waxembedded kidneys also failed to give uniformly reproducible results. In attempting to find a satisfactory technique for both enzyme and granule staining, we noted Janigan's (1965) and Haratla's (1969) observations on paraffin-embedded JGC, and tested the following fluorochromes: thioflavine T—Fluka, C. I. 49005; auramine O—Merck, C. I. 41000; acridine orange—E. Gurr, C. I. 46005; berberine sulfate—Fluka, C. I. 75160 on 10 μ sections of albino mouse kidneys prepared in 4 different ways as follows:     

The Mounting of Carbowax Sections with Lighter-Fluid and Rubber Cement

Serial sections cut from plant tissues embedded in Carbowax have been affixed to slides with rubber cement. A rather thick layer of undiluted rubber cement was first spread on the slides. The Carbowax ribbons were added next. Lighter-fluid, essentially petroleum ether which can be substituted for it, was then run under the sections to dissolve the rubber cement and to float the ribbons. This notation medium did not dissolve the Carbowax and the ribbons could be manipulated in it for accurate location. The slides were dried on a 45° C warming table which also helped to flatten the sections. Adhesion was best when drying times were held to 4 hr or less. All excess rubber cement was washed away with xylene immediately prior to covering and the cover slips were carefully applied with a very thin resinous mounting medium to prevent dislodging the sections. Both aqueous and alcoholic stains have been used successfully and the slides have been left in them for as long as 3 days without loss of sections. The method was developed for fluorescence microscopy but serves equally well for visible light microscopy. Slides stained with a safranin-fast green combination have been used for both purposes, the safranin staining and fluorescing in a manner similar to rhodamine B.     

Paraffin-Embedded and Frozen Sections of Drosophila Adult Muscles

The molecular characterization of muscular dystrophies and myopathies in humans has revealed the complexity of muscle disease and genetic analysis of muscle specification, formation and function in model systems has provided valuable insight into muscle physiology. Therefore, identifying and characterizing molecular mechanisms that underlie muscle damage is critical. The structure of adult Drosophila multi-fiber muscles resemble vertebrate striated muscles ¹ and the genetic tractability of Drosophila has made it a great system to analyze dystrophic muscle morphology and characterize the processes affecting muscular function in ageing adult flies ². Here we present the histological technique for preparing paraffin-embedded and frozen sections of Drosophila thoracic muscles. These preparations allow for the tissue to be stained with classical histological stains and labeled with protein detecting dyes, and specifically cryosections are ideal for immunohistochemical detection of proteins in intact muscles. This allows for analysis of muscle tissue structure, identification of morphological defects, and detection of the expression pattern for muscle/neuron-specific proteins in Drosophila adult muscles. These techniques can also be slightly modified for sectioning of other body parts.     

Contraction-Free, Fume-Fixed Longitudinal Sections of Fresh Frozen Muscle

Contraction damage occurring when longitudinal frozen sections of fresh unfixed muscles are thawed on microscope slides has limited histological examination of this tissue mainly to cross sections. Longitudinally oriented sections are advantageous for investigating properties that vary along the length of the muscle fibers. A fume fixation technique has been developed for preventing contraction of thick longitudinal frozen aections. The technique is compatible with histochemical staining of enzymes.     

Serial Sections; Simplified Handling of Paraffin Ribbons on a Floating-Out Bath

Pieces of para & ribbon containing serial sections are arranged in overlapping rows on a microscope slide coated with albumen or glycerol. The assembly of sections is then floated free by immersing the slide in a bath of warm water. The rows of sections forming the assembled unit adhere to each other along their overlapping edges. After the sections have softened and expanded, the unit is picked up on a slide, covered with wet filter paper, rolled flat with a photographic print roller, and allowed to dry.     

Effects of Mounting Media on Fading of Toluidine Blue and Pyronin G Staining in Epoxy Sections

Available mounting media cause fading of histological preparations over time. A study was designed to find the most suitable medium for durable mounting of Araldite embedded semithin sections of rabbit cerebral cortex stained with toluidine blue and pyronin G. Among four synthetic mounting media tested, only DePeX prevented fading of the sections during the first month. All mounting media tested helped preserve staining intensity after one month, since the fading rate after one year is only about half that in sections prepared without mounting medium. The average optical density of sections after one year was higher in preparations mounted with DePeX than in sections treated with the other mounting techniques tested in this study. After one year, the average optical density of sections mounted with DePeX had decreased approximately 20%.