Nongraded Dehydration and Low-Pressure Infiltration for Rapid Celloidin Embedding of Brain Tissue

Various ways of shortening single steps in the celloidin process have been combined to form a routine method which may be completed, for tissues of average size, within a week following fixation. Fixed, washed tissue slices 5 mm thick are dehydrated in 1 or 2 changes of absolute ethanol and acetone, 1:1. This requires 24 hr in an incubator at 37 C, or 12-16 hr if a magnetic stirrer is used. After ether-alcohol for 4 hr. the tissues are transferred to 5% celloidin and infiltrated in a vacuum desiccator attached to a filter pump. When the volume of celloidin is reduced to half the original amount (about 2 hr), the tissues are removed from the infiltrating fluid and embedded in 10% celloidin. The blocks are hardened in chloroform and cleared by suspending them in 2 or 3 changes of terpineol agitated by a magnetic stirrer. Sections are cut in terpineol, using any type of microtome. After washing in 95% alcohol, they are mounted on albumenized slides for staining.     

Using Scrapings from Formalin-Fixed Tissues to Diagnose Leptospirosis by Fluorescent-Antibody Techniques

Small specimens of formalin-fixed tissues approximatey 1 × 1 × 0.2 cm were cut from the suspect specimen. Several clean microscope slides were dipped in 1% aqueous gelatin and air-dried or dried on a slide warmer. Each tissue specimen was washed in running tap water for 2-5 min and then lightly scraped with a straight knife blade, cutting edge perpendicular to the surface of the specimen. The scrapings were allowed to build up and cling to the knife blade, which was then turned so that the broad surface contacted the slide; thus, the scrapings could be smeared onto the slide in a single motion. Sufficient pressure was applied to embed the tissue fragments in the gelatin coating. Smears, dried in air or on a slide warmer, were stained immediately by a standard direct or indirect technique to detect fluorescein-labeled antigens. This scraping method, adapted to the study of leptospirosis by fluorescent-antibody technique, could reduce the need for cryostat-cut tissues and facilitate the observation of individual leptospires.     

Embedding and Sectioning Undecalcified Bone, and its Application to Radioautography

A method is described for embedding and sectioning hard, undecalcified bone, which is designed for use by technical personnel. Bone fixed in a variety of ways is progressed through alcohols to ether-alcohol and then infiltrated with ether-alcohol solvented plastic (plasticized nitrocellulose) by a combination of centrifugation and high pressure embedding technics. The ether-alcohol is evaporated in a partially closed container in a manner similar to that employed in celloidin embedding, but differs from the latter by the removal of all of the solvent. Celloidin is the source of nitrocellulose and Amoil-S, the added plasticizer. Undecalcified adult bone of all types is readily cut at a thickness of 5-8μ on a heavy duty sliding microtome. The sections are then mounted on gelatinized slides. The procedures for preparing strip film radio-autograms of bone sections and subsequent staining of the preparation are given. The results obtained are illustrated.     

Periodic Acid-Schiff-Toluidine Blue-Aurantia; A Stain for the Gland Cells of the Stomach

By a revised technique, human pulmonary elastic tissue can be isolated in a form suitable for examination under the stereoscopic microscope. Fresh human lungs from autopsy are fixed by intrabronchial infusion with 10% formalin for 24 hr. Slabs 1.5 cm thick are cut and the formalin removed in running water. One such slab is embedded under intermittent vacuum in an aqueous mixture containing 15% gelatin, 10% glycerol, and 1% phenol; then allowed to gel. Frozen sections 2 mm thick are cut on a large-section MSE sledge microtome. Squares 3 × 3 cm from such a section are corroded for 4-5 days in 88% formic acid at 45 C, washed once with distilled water, and mounted in glychrogel containing 6% gelatin. The elastic tissue network of the lung will have been freed from surrounding elements. The preparation should be stored in a refrigerator. Blocks for thin sections and large thick un-corroded sections can be prepared from the same lung as part of an over-all procedure.     

Formic Acid Corrosion for the Demonstration of Pulmonary Elastic Tissue

By a revised technique, human pulmonary elastic tissue can be isolated in a form suitable for examination under the stereoscopic microscope. Fresh human lungs from autopsy are fixed by intrabronchial infusion with 10% formalin for 24 hr. Slabs 1.5 cm thick are cut and the formalin removed in running water. One such slab is embedded under intermittent vacuum in an aqueous mixture containing 15% gelatin, 10% glycerol, and 1% phenol; then allowed to gel. Frozen sections 2 mm thick are cut on a large-section MSE sledge microtome. Squares 3 × 3 cm from such a section are corroded for 4-5 days in 88% formic acid at 45 C, washed once with distilled water, and mounted in glychrogel containing 6% gelatin. The elastic tissue network of the lung will have been freed from surrounding elements. The preparation should be stored in a refrigerator. Blocks for thin sections and large thick un-corroded sections can be prepared from the same lung as part of an over-all procedure.     

Staining Germinating Pollen and Pollen Tubes

Germinating pollen on stigmas and pollen tubes in styles of Antirrhinum, Brassica, Oenothera, Raphanus, Rosa, solatium and Tagetes spp. were prepared for examination as follows: The styles were fixed in ethyl alcohol-acetic acid 3:1 for 1 hr, and hydrolyzed at 60°C for 5 to 60 min (depending on the species) in 45% acetic acid. The stigma with its attached strand(s) of stigmatoid tissue was then dissected out under a stereoscopic microscope, placed in a few drops of a staining solution made by dissolving 150 mg of safranin O and 20 mg of aniline blue in 25 ml of hot 45% acetic acid. After 5-15 min in this stain, the tissue was placed in a fresh drop of stain on a microscope slide and gently squashed under a cover glass. Because of a gradual precipitation of the aniline blue component, the stain had to be filtered regularly before use. However, a staining solution could be kept at room temperature for several weeks.     

Diethylene Glycol Distearate Embedding and Ultramicrotome Sectioning for Light Microscopy

Diethylene glycol distearate can be used as an embedding medium for light microscopy. Two infiltration changes of about 6 hr each in the melted wax (melting point 47-52 C) are required before the final embedding which is done in 00 gelatin capsules for sectioning in the ultramicrotome by the procedure used in electron microscopy. Serial sections 1-2 μ thick can be cut without difficulty. No cooling devices are necessary for trimming and sectioning at laboratory temperature. Sections rarely become detached from the slides. The staining characteristics of the tissues are the same as when embedded in paraffin. For fluorescence microscopy, essentially the same procedure is followed. Tissues are not distorted and the intracellular structures are well preserved.     

Application of a rapid avidin--biotin--peroxidase complex (ABC) technique to the localization of pituitary hormones at the electron microscopic level

The new avidin--biotin--peroxidase complex (ABC) technique was applied to ultrathin sections of rat pituitary that were fixed with glutaraldehyde and embedded in Araldite 6005. The primary antisera dilutions that are normally applied for 24-48 hr with the peroxidase-antiperoxidase (PAP) complex technique were used. High background was observed with the ABC method when incubation times were 12-48 hr. Tests were then conducted with shorter incubation times. The staining intensity was measured with a densitometer. Detectable stain was seen after only 15 min in dilutions of 1:10,000 anti-bovine luteinizing hormone (bLH beta), 1:8000 anti-rat thyroid-stimulating hormone (rTSH beta), and 1:20,000 anti-25-39-adrenocorticotropic hormone (25-39ACTH). Optimal LH staining was seen after 30 min, whereas optimal staining for TSH or ACTH required 1 hr. Stain was detectable with a dilution of 1:4000 anti-human follicle-stimulating hormone (hFSH beta) after 30 min and was optimal after 4 hr. Prolonged incubation times with these dilutions decreased the staining intensity because a deposit of high background was produced that appeared as a filigreed network over the cells. When higher dilutions were tested with 2-hr incubation times, optimal staining was seen with 1:30,000 anti-bLH beta, 1:24,000 anti-rTSH beta, 1:30,000 anti-25-39ACTH, and 1:8000 anti-hFSH beta. These tests demonstrate the potential of the ABC method for the rapid detection of small amounts of specific and nonspecific antibodies that are bound to pituitary cells.     

Oriented Embedding of Biological Materials and Accurate Localization for Ultrathin Sectioning

Gelatin capsules with rounded ends clipped off and open ends moistened, affixed to a glass slide and sealed with a 15% gelatin solution are used to embed blocks of tissue in plastic. The surface of the slide serves as an orientation plane for structures of the tissue. The plane end of capsules of polymerized plastic containing no tissue is used in embedding frozen tissue sections. The plastic-infiltrated section is flattened against the capsule end under the weight of a 3/4 inch square of plate glass so that larger sections may be cut and surveyed. Embedding cultured cell monolayers grown on coverslips is accomplished in a comparable manner, but the square of plate glass is not needed as a weight. Block-face localization methods depend on the type of material embedded. With blocks of tissue it is achieved by moistening the face with xylene to develop relief. Thin tissue sections are examined by transmitted light, while cell monolayers are stained on the capsule end with methylene blue.     

The Surface Staining of Embedded Tissues

The staining procedure is based on the theory that the freshly cut surface of embedded material will absorb stain only in the exposed tissue elements, provided that the embedding compound itself will not absorb the staining fluid. Concentrated stains are used for short intervals to insure minimum penetration. For paraffin embedded materials: (1) Cut block, preferably on microtome, to the desired tissue surface. (2) Rinse in absolute alcohol. (3) Float face down in stain. (Ripe, concentrated alum hematoxylin—Galigher's formula recommended—will stain in 10 to IS minutes. Heidenhain's iron hematoxylin works exceptionally well in some cases.) Mordant 20% alum 5 to 10 minutes, briefly rinse, and stain comparable 5 to 10 minutes in 1 to 1.5% hematoxylin. (4) Allow to become blue in tap water (for hematoxylin stains). (5) Counter-stain if desired. (6) Dehydrate in absolute alcohol for not more than 10 minutes. (7) Dry for 15 to 20 minutes. (8) Trim block to 2-3 mm. and mount between two cover glasses by use of microflame. Attach mount to slide with balsam. For celloidin embedded materials: (1) Dehydrate block with 90% alcohol, phenol-toluene, finally pure toluene. (2) Rinse cut surface with 90% alcohol, then apply stain. (3) Wash, after hematoxylin stains, counterstain if desired. (4) Dehydrate surface, 90% alcohol, phenol toluene, pure toluene, and mount in medium dissolved in toluene.

Possible applications of surface staining technic are suggested and illustrated.     

Polyester Resin Embedding for Sectioning of Hard and Soft Tissues

Soft and calcareous tissues embedded in polyester resin may be cut on a sledge microtome to produce thin sections of 3-4 β thickness. Fixed tissues, dehydrated in ethyl alcohol, cleared in methyl benzoate and chloroform, are taken into a wide-necked bottle containing equal parts of polyester resin and chloroform with 0.75% catalyst. The bottle kept in water bath at 37°C is connected to a vacuum pump. With the evaporation of the chloroform under reduced pressure (approximately 10 mm Hg) infiltration is complete. Tissues transferred into a blocking form containing pure polyester resin with 1.5% catalyst are polymerized at 37° C until blocks are firm (48 hr or more). Blocks are prepared with at least 5 mm margin of plastic surrounding the tissue. The edge of the block adjacent to the knife is then filed at an angle of 45° to the cutting movement. Sections are cut with a wide-backed biplanar knife having a cutting edge of 40-44° positioned at an angle of 30° to the plastic block. As the resin is permeable to most stains, staining is carried out through the plastic Sections carried through staining procedures in wire baskets are floated onto slides and mounted in polystyrene; the cover-glass is compressed with a spring-clamp. Microscopic examination shows no staining of plastic, minimal shrinkage and good cellular detail.     

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.     

Silver Impregnation of the Golgi Apparatus, with Subsequent Nitrocellulose Embedding

The appearance of silver impregnation of the Golgi apparatus can be enhanced by the use of nitrocellulose as an embedding medium. Fixation of 1.5 mm thick pieces of fresh tissue for 8 hr in: glycine, 1.7 gm; 15% formalin, 100 ml; HNO₃, conc., 0.5 ml, at pH 2.6 followed by rinsing in water, 4 hr in 1.5% AgNO₃, another rinse, and 2 hr reduction in 1.5% hydroquinone in 15% formalin. This staining procedure yields consistently good results for rat, rabbit, and human tissues. Low-viscosity nitrocellulose embedding is done by infiltrating at 56 C in 7% nitrocellulose for 0.5 hr, 15% for 4 hr, and 27% for 1 hr. The nitrocellulose is hardened 2 hr in chloroform, after which, sections as thin as 5 μ can be cut on a sliding microtome. Gold toning and counterstaining can be done with the tissue affixed to the slide. The Golgi apparatus is stained dark brown to black, and there is better preservation of cellular detail than in tissues processed in paraffin.     

Autoradiography of Water-Diffusible Substances in Sections of Whole Baby Rats

Rats, 7 days postnatal which had been injected with a radioactive nuclide, were quick frozen and sectioned in the frozen state. An adhesive cellulose tape (Sellotape) was used to support the section during cutting, through freeze-drying, and attaching to slides. Dehydration of the frozen sections consisted of 1 hr in a chilled desiccator containing silica gel, then at reduced pressure of 2-3 mm Hg until quite dry. The exposed side of the section was sprayed with celloidin dissolved in amyl acetate and allowed to dry. This side of the section was attached to a slide, previously coated with 1% gelatin containing 0.1% chrome alum, by means of an adhesive consisting of 4% gelatin and 5% formalin in 60% glycerol. In applying this adhesive it is mandatory that a border of about 3 mm of bare glass be left outside the adhesive, to allow intimate contact between the sticky side of the tape and the glass. The adhesive was allowed to set for 20 min, the slide immersed in water lor 50 sec, and the cellulose layer of the tape peeled off. The rubber base from the tape was removed with chloroform, the slide dried, and the exposed surface of the section coated with celloidin in amyl acetate, by dipping. After this treatment, the slides could be coated by dipping in autoradiographic emulsion without affecting water-soluble radioactive substances in the tissue.     

The Presence of Lipids But Absence of Tannins in Elodea Idioblasts

The presence of tannins in the idioblasts of Elodea densa is conclusively disproved. Ten reagents for histochemical detection of tannin (K₂Cr₂O₇, K₃Fe(CN)₆, FeCl₃, (NH₄)₂MO₄, Nessler's reagent, Fehling's reagent, methylene blue, gelatin, iodine-KI and lead acetate) gave negative tests in Elodea idioblasts. Two reagents (1% aqueous caffeine and a saturated solution of Ca(OH)₂) gave apparently positive reactions that could be explained by the presence of lipids. Positive tests for lipids were obtained by direct microscopic examination of the removal of lipid materials from freeze-dried leaves, using a 1:1 ether-alcohol mixture. The lipid material was not removed when acetone was substituted for ether-alcohol. A lipoprotein complex was demonstrated by using Serra's method for masked lipids.     

Masking of pleomorphic glycogen sites by methanolic uranyl acetate.

Rat liver tissue was fixed in 2.5% glutaraldehyde buffered with cacodylic acid (pH 7.3) for 2 hr, washed twice in buffer, and postfixed in 2% osmium tetroxide at 4 C for 1 hr. The tissue then was dehydrated, infiltrated with and embedded in Epon by routine procedures. The ultrathin sections from this tissue, when stained with spectroscopic grade methanol saturated with uranyl acetate (SMUA) for 1 min followed by aqueous lead citrate (PbCi) (Reynolds 1963) for 5 min at room temperature, showed a uniform staining of all major cellular components except glycogen. The SMUA appeared to be specific for ribonuceloprotein granules, rendering them more prominent in the cytoplasm due to the lack of glycogen staining. The question of glycogen removal from the sections due to SMUA treatment was evulated using various extractions and staining methods. It appeared that SMUA pretreatment alters the subsequent binding ability of lead salts, resulting in lack of glycogen staining, although it does not remove the glycogen from the sections.     

Dye-coupling and the formation and fate of the hypoblast in the teleost fish embryo, Barbus conchonius.

The present report describes Lucifer Yellow (LY) transfer between the syncytial layer of the yolk cell (YSL) and blastodermal cells during epiboly in the teleost fish Barbus conchonius. The fate of a group of labeled cells is described until germ layer formation. At the onset of epiboly, LY seems to be transferred from the YSL to all blastodermal cells. Between 10% and 40% epiboly, dye-coupling appears to be restricted to the marginal region. Within 60 min individually labeled cells are distributed among unlabeled cells within the blastoderm. Between 40% and 60% epiboly, we observed a ring-shaped group of labeled cells, which probably have involuted during early gastrulation. Consequently, this cell group may correlate with the leading edge of the hypoblast layer within the germ ring. At 60% epiboly and later, the blastodermal cells are dye-uncoupled from the YSL. A gradual translocation of the ring-shaped hypoblast towards a dorsally located bar-like structure is observed between 50% and 100% epiboly. At 100% epiboly, fluorescent cells were located in contact with the YSL within the embryo proper, with the brightest fluorescence in the future head region. The translocation is due to dorsalwards convergent cell movements during the gastrulation process. The appearance of the hypoblast as a dye-coupled cell layer may correlate with some restriction in cell fate since the hypoblast differs in fate from the epiblast.     

Masking of Pleomorphic Glycogen Sites by Methanolic Uranyl Acetate

Rat liver tissue was fixed in 2.5% glutaraldehyde buffered with cacodylic acid (pH 7.3) for 2 hr, washed twice in buffer, and postfixed in 2% osmium tetroxide at 4 C for 1 hr. The tissue then was dehydrated, infiltrated with and embedded in Epon by routine proocdures. The ultra thin sections from this tissue, when stained with spectroscopic grade methanol saturated with uranyl acetate (SMUA) for 1 min followed by aqueous lead citrate (PbCi) (Reynolds 1963) for 5 min at room temperature, showed a uniform staining of all major allular components ercept glycogen. The SMUA appeared to be specific for ribonucleoprotein granules, rendering them more prominent in the cytoplasm due to the lack of glycogen staining. The question of glycogen removal from the sections due to SMUA treatment was evaluated using various extractions and staining methods. It appeared that SMUA pretreatment alters the subsequent binding ability of lead salts, resulting in lack of glycogen staining, although it does not remove the glycogen from the sections.     

Whole Mounts of Rabbit Lens Epithelium for Cytological Study

The eye globe is cut equatorially just posterior to the equator and the anterior part fixed in acetic-acid:akohol (1:3) for 24 hours. After washing, the lens is removed, hydrolyzed, and stained by the Feulgen technic. In the SO₂ wash solution, the lens epithelium is dissected free of the lens in one piece under a binocular microscope and laid on a cover slip, cell side down. It is flattened, after radial incisions, by absorbing water around the edge, and inverted on to a drop of glychrogel on a slide. Cell and nuclear structure are observed with the aid of phase contrast.     

A novel thin section preparation and staining protocol to increase contrast and resolution of cell details for light microscopy

ABSTRACT

We developed a novel sectioning and staining method to make high contrast, high resolution sections of plant tissue for light microscopy. Specimens of teosinte (Zea mays L., ssp. mexicana) root tips were fixed and embedded in Technovit 7100? plastic resin. Thin sections, 1?2.5 μm, were cut and mounted on glass slides. The sections were either treated with RNase or not, then stained with 0.1% toluidine blue O and observed through ∞/0 objective lenses. For light microscopy, the enzyme staining procedure increased resolution and contrast. High magnification ∞/0 objective lenses produced high quality images for digital photography without using a coverslip or immersion oil. Our slide preparation and microscopic analysis were less labor intensive and more rapid than previous methods and enabled rapid and precise alignment of serial transverse sections for both tracking cell lineages and tissue measurements.