Preservation and Long-Term Storage of Feulgen-Stained Mouse Tissues for Subsequent Autoradiography

Tissue of the jejunal crypts of mouse intestine was fixed for 24-48 hr in acetic-ethanol, 1:3, and stained en bloc by the Feulgen reaction. The stained preparations were then stored 4 mo at -25 C in either 45% acetic acid alone or in dimethyl sulfoxide (DMSO) or glycerol to which 45% acetic acid had been added to make 15% of the total volume. Such storage preserved not only the stain but allowed autoradiographs to be made. No loss of silver grains or a decrease of labeling index was observed. The procedures are equally successful when used with double-labeling experiments. Solid, transplantable, experimental carcinomas can be preserved in a manner identical to that suggested for the epithelial cells of the crypts.     

Acid Orcein-Iron and Acid Orcein-Copper Stains for Elastin

Paraffin sections of formol-fixed tissues stained 4-18 hr in 70% alcohol containing 1% orcein and 1% of concentrated (12 N) HCl by volume yield the familiar purple brown elastin and red nuclei on a pink background. When sections so stained are transferred directly from the stain to 70% alcohol containing 0.02% ferric chloride (FeCl₃·6 H₂O) or 0.02% copper sulfate (CuSO₄·5 H₂O) for a 15 sec to 3 min period, elastin coloration is changed to black or reddish black and chromatin staining to reddish black. The procedure can be counterstained with picro-methyl blue to yield blue collagen and reticulum or with our flavianic acid, ferric chloride, acid fuchsin mixture to give deep yellow background and deep red collagen.     

A Versatile Stain for Pollen Fungi, Yeast and Bacteria

A versatile stain has been developed for demonstrating pollen, fungal hyphae and spores, bacteria and yeasts. The mixture is made by compounding in the following order: ethanol, 20 ml; 1% malachite green in 95% ethanol, 2 ml; distilled water, 50 ml; glycerol, 40 ml; acid fuchsin 1% in distilled water, 10 ml; phenol, 5 g and lactic acid, 1-6 ml. A solution has also been formulated to destain overstained pollen mounts. Ideally, aborted pollen grains are stained green and nonaborted ones crimson red. Fungal hyphae and spores take a bluish purple color and host tissues green. Fungi, bacteria and yeasts are stained purple to red. The concentration of lactic acid in the stain mixture plays an important role in the differential staining of pollen. For staining fungi, bacteria and yeasts, the stain has to be acidic, but its concentration is not critical except for bacteria. In the case of pollen, staining can be done in a drop of stain on a slide or in a few drops of stain in a vial. Pollen stained in the vial can be used immediately or stored for later use. Staining is hastened by lightly flaming the slides or by storing at 55±2 C for 24 hr. Bacteria and yeasts are fixed on the slide in the usual manner and then stained. The stock solution is durable, the staining mixture is very stable and the color of the mounted specimens does not fade on prolonged storage. Slides are semipermanent and it is not necessary to ring the coverslip provided 1-2 drops of stain are added if air bubbles appear below the coverslip. The use of differentially stained pollen mounts in image analyzers for automatic counting and recording of aborted and nonaborted pollen is also discussed.     

Effects of Ph on Post-Mortem Retention of Trypan Blue Vital Staining in Tissues of Mice

Vital staining of aortas from mice injected subcutaneously (daily for 5 days) with trypan blue was studied. In routine paraffin sections elastic membranes were observed to be well stained and other medial elements unstained following fixation in 10% formaldehyde (25% formalin) at pH 7-9. An identical pattern of vital staining was observed in specimens that had been immersed for 48 hr in saline solutions at pH 7-11. Elastic membranes were not stained, but intermembranous connective tissue was stained after the following: (1) fixation in 10% formaldehyde at pH 1-4 and in Lavdowsky's solution (ethanol, formaldehyde, water and glacial acetic acid), pH 2.3-2.8; and (2) immersion in saline for 48 hr at pH 14. Aortic elastic membranes were vitally stained after fixation by intracardiac perfusion with 10% formaldehyde (pH 7-8) but not after perhion with Lavdowsky's fixative (pH 2.3-2.8). Vital staining was limited to medial elastic membranes in sections of fresh aorta made in a cryostat or by a regular freezing microtome. The vital staining (coarse cytoplasmic granules of dye) within macrophages (Kupffer cells and others) and in cytoplasm of renal tubular epithelium was well demonstrated following use of all methods discussed above     

Quad-Type Stain for the Simultaneous Demonstration of Intracellular and Extracellular Tissue Components

This technic for the simultaneous demonstration of several different tissue components works equally well on invertebrate and vertebrate tissue if they have been treated with nonchromate fixatives Sections 4-7 μ thick are stained 30 min in 1% Alcian blue, then treated with alkaline alcohol for 2 hr. They are stained in Verhoeff's hematoxylin for 4-6 hr, and rinsed in alcohol; stained in woodstain scarlet-acid fuchsin for 3 min, decolorized in 5% phosphotungstic acid for 20 min and finally stained 5-8 min in alcoholic saffron. Collagen and bone are stained yellow; elastin, myelin and nucleic acids, purple to black; muscle, chitin, cytoplasm, fibrinoid and acid secretion, bright red to lavender; ground substances and mucus, blue-green. Fibrous connective tissue, cartilage, bone and glandular epithelia are exceptionally well demonstrated by this method. Slides stained in this manner are well suited for color photomicrography and as demonstrations in the classroom.     

Silver Staining, Featuring Rapid Reduction, For Whole Mounts of Retina and Optic Pathways in Chick Embryos

Developing and established nerve fibers in the retina and in superficial tracts of the brain can be stained and viewed en bloc. The method was developed on chick embryos of 2 days of incubation to several months post-hatching but could be used on other material provided that the objects of interest were within 35 μ of the surface. Procedure: (1) Place the entire eye or head in 50% pyridine for at least 16 hr. (2) Wash well for 5-7 hr with hourly changes of distilled water or with running tap water for 4-6 hr followed by several changes of distilled water. (3) Transfer to 95% ethanol for 16-48 hr. (4) Impregnate with 1.5% AgNO₃ for 2 days at 37 C. (5) Submerge in water and, when staining the retina, remove the vitreous body and apply an aqueous solution of 0.25% pyrogallic acid in 1.25% formalin by directing a narrow stream of this reducer against the retina for 2-5 sec. Wash the eye with distilled water 30-60 sec after applying the reducer. When staining the brain, remove the meninges under water, direct the stream of reducer against the brain for 20-30 sec, and rinse the brain immediately after the nerves have stained. (6) Dissect the specimen and make temporary mounts in glycerol; or, dehydrate and clear for resin mounting. The technique stains both mature and growing axons with their growth cones and sometimes their cell bodies. The fiber patterns show best on the surfaces of the retina and brain. The stain works consistently and is suited to the study of both normal and abnormal development.     

Acetic Acid as a Diluent and Dehydrant in the Preparation of Whole, Stained Helminths

Aqueous 45% acetic acid can be used successfully as a diluent for Ehrlich's haematoxylin and for Horen's trichrome stain (chromotrope 2 R, 0.6 gm; phosphotungstic acid, 0.7 gm; glacial acetic acid, 1.0 ml; water, 100 ml). Glacial acetic acid is used for dehydration of the stained helminths, and followed by a glacial acetic acid-methyl salicylate series for clearing. The whole process can be completed within 1 hr, from fixation to the cleared specimen, with helminths up to 5 mm in length. A satisfactory fixative for Monogenea, Digenea and Acanthocephala is: 85% ethanol, 85; formalin (40% HCHO), 10; and glacial acetic acid, 5—parts by volume. For Cestoda, 5% aqueous formalin is preferable because they are hardened excessively by the alcoholic fixative.     

A nitrous acid procedure as a selective histochemical means of eliminating the N-sulphates of glycoconjugates

Summary A nitrous acid procedure has been shown to lead to the elimination of N-sulphates in sections of a series of tissues containing sulphated glycoconjugates. Two groups of sulphated glycoconjugate-containing tissues were used; one contained N-sulphates and other was devoid of such groupings. In the first group of tissues, mast cells of different origins and renal glomeruli in the rat were employed. Xiphoid and tracheal cartilage matrix, submandibular and sublingual gland acini and gastric, duodenal and colonic mucosae were used in the second group. Sections were treated with nitrous acid and then stained with Alcian Blue pH 1.0, high iron diamine or Aldehyde Fuchsin for sulphated glycoconjugates. Such treatment was found to diminish the staining intensities exclusively in N-sulphated glycoconjugate-containing structures such as mast cell granules and renal glomerular basement membrane, providing a means of chemically eliminating N-sulphates of glycoconjugates in tissues.     

Staining Mitochondria With Hematoxylin After Formalin-Sublimate Fixation; A Rapid Method

Mitochondria were stained in liver, kidney, pancreas, adrenal and intestinal mucosa of rat and mouse. Tissues 1 mm thick, were fixed in a mixture of saturated aqueous HgCl₂, 90 ml; formalin (37-38% HCHO), 10 ml, at room temperature (25°C) for 1 hr. Deparaffinized sections 3-4μ thick were treated with Lugol's iodine (U.S.P.) followed by Na₂S₂O₃ (5%), rinsed in water and the ribonucleic acid removed by any of the following procedures: 0.2 M McIlavaine's buffer, pH 7.0, 2 hr, or 0.2 M phosphate buffer, pH 7.0, 2 hr at 37°C; 0.1% aqueous ribonuclease, 2 hr at 37°C; 5% aqueous trichloracetic acid overnight at 37°C; or 1% KOH at room temperature for 1 hr. After washing in water, sections were treated with a saturated solution of ferric ammonium alum at 37°C for 8-12 hr and colored by Regaud's ripened hematoxylin for 18 hr. They were then differentiated in 1% ferric ammonium alum solution while under microscopic observation.     

Chromosome preparations in the field from mammals long after death

Chromosome preparations of high quality can be obtained from bone marrow cells of small mammals that have been dead for 20 hr or longer. The bone marrow is rinsed out of the femurs with RPMI medium supplemented with 15% fetal calf serum. Add 0.05-0.1 ml of a 0.01% colchicine solution to 5 ml of medium-cell suspension. After 1/2-1 hr of colchicine treatment at 37 C the cells are spun down and the supernatant replaced by 5 ml of hypotonic (0.075 M) KCl. After 12 min in the hypotonic solution at 37 C the cells are fixed in methanol:acetic acid 3:1. Air dried preparations are made after repeating the fixation procedure three times and the chromosomes are stained with Giemsa, if required after pretreatment of the preparations for banding, e.g., GTG. Technical hints for field work are given. The technique has proven successful with several species of rodents and shrews.     

Staining Plant Tissues with Chlorazol Black E and Pianese III-B

The staining schedule was developed for a study of the mycorrhizae of red pine, Pinus resinosa Ait. From 70% alcohol, sections are stained in a saturated solution of chlorazol black E in 70% alcohol, 10-30 min; free dye removed by washing in 95% alcohol; stained 18-24 hr in Pianese III-b; rinsed in 95% alcohol, acidified by the addition of 2 ml of saturated aqueous picric acid per 100 ml, 3-4 changes or until the last change is pale yellow or light green; and rinsing in 95% alcohol to remove the acid. If the acid fuchsin is too intense, a cautious differentiation with 95% alcohol containing 1-3% of a 0.1 N solution of NaOH is made. If too much chlorazol black is removed, the effect can be compensated by overstaining with this dye at the beginning of the process. Sections are dehydrated, cleared, and covered in the usual manner. This stain has applications to plant tissues generally, and is particularly effective for meristematic tissues. It shows details of cytoplasmic structures and gives sharp delineation of primary cell walls.     

Chromosome Preparations in the Field from Mammals Long After Death

Chromosome preparations of high quality can be obtained from bone marrow cells of small mammals that have been dead for 20 hr or longer. The bone marrow is rinsed out of the femurs with RPMI medium supplemented with 15% fetal calf serum. Add 0.05-0.1 ml of a 0.01 % colchicine solution to 5 ml of medium-cell suspension. After Vi-1 hr of colchicine treatment at 37 C the cells are spun down and the supernatant replaced by 5 ml of hypotonic (0.075 M) KC1. After 12 min in the hypotonic solution at 37 C the cells are fixed in methanokacetic acid 3:1. Air dried preparations are made after repeating the fixation procedure three times and the chromosomes are stained with Gietnsa, if required after prclieatment of the preparations for banding; e.g., GTG. Technical hints for field work are given. The technique has proven successful with several species of rodents and shrews.     

Adaptation of the Millon, Sudan Black B, and Periodic Acid-Schiff Technics for Block Staining of Insect Tissues

Spermatophores and reproductive systems of the beetle, Lytta nuttalli Say, fixed in Bouin's aqueous picroformol or buffered 10% neutral formol were stained in toto by the Millon, Sudan black B and periodic acid-Schiff reactions as follows. Millon: after excess fixative is removed in 70% ethanol, specimens are brought to water, stained in Millon's reagent at 60 C for 1 hr, rinsed in 2% aqueous nitric acid at 40-50 C, dehydrated rapidly, cleared, embedded and sectioned as usual. Sudan black B: specimens are taken to absolute ethanol, stained in a saturated solution of Sudan black B in absolute ethanol at room temperature for 24-48 hr, rinsed and cleared in xylene, embedded and sectioned. PAS: specimens are brought to water, oxidized in 0.5 aqueous HIO₄ at 37 C for 30 min, washed in 2 changes of water, stained in Schiif reagent at room temperature for 1 hr, rinsed in 3 changes of 0.5% aqueous potassium metabisulfite, washed in running water for 10-15 min, dehydrated, cleared, embedded and sectioned. All 3 methods produced their characteristic staining in specimens up to 3 mm thick     

Ultrastructural histochemistry of the surface lamina of normal articular cartilage

Summary Two collagen-poor, ultramicroscopic layers are described at the surface of canine articular cartilage. They are distinguished by staining with an electron-dense cationic dye, Cupromeronic Blue, in a critical electrolyte concentration technique and by digestion with testicular hyaluronidase. The superficial layer, approximately 50 nm thick, stained at low electrolyte concentrations but failed to stain in conditions specific for sulphated glycosaminoglycans. It was hyaluronidase-resistant and may be either glycoprotein or protein in nature. The deeper layer, 100–400 nm thick, stained positively at electrolyte concentrations specific for sulphated glycosaminoglycans but not in conditions specific for keratan sulphate. It was removed by hyaluronidase digestion. This layer probably represents a chondroitin sulphate-rich proteoglycan.These surface layers may be important in the lubrication of the articular surface and in the permeability and compression resistance of the superficial cartilage zone.     

An Improved Squash Technique for Human Male Meiotic Chromosomes: Softening and Concentration of Cells; Mounting in Hoyer's Medium

Human testicular material obtained from autopsies was processed as follows: (1) swelled with 0.3% sodium citrate 1-6 hr; (2) softened with 3 M glucono-delta-lactone 2 hr; (3) stained with aceto- or propiono-carmine overnight; (4) washed in 70% alcohol; (5) macerated in 1:1 alcohol-acetic acid; (6) filtered through gauze to remove tubules and connective tissue; (7) filtrate centrifuged to separate spermatocytes from debris; (8) a drop of supernate from just above the precipitate, containing stained cells, mixed with Hoyer's medium; (9) cover slip applied, preparation warmed, and (10) squashed. Chromosomes remained in good condition for 8 mo.     

Camwood (Baphia nitida) Extract as a Histological Stain for Interglobular Dentine, Striated Muscle, and Counterstaining

The shavings of the dried heartwood of the tree Baphia nitida are ground to a fine powder, and 6 gm of the powder are extracted in 100 ml absolute ethanol at 27-30 for 6-24 hr. The extract is filtered with Whatman No. 1 paper and stored in a screw-capped bottle. For staining the interglobular dentine of nondecalcified sections of formlin-fixed teeth, sawed cross sections 20-30 μ thick were dehydrated in ethanol and stained in the undiluted extract for 6-12 hr at room temperature. The interglobular dentine was stained a bright golden brown on a pale brown background. For staining striated muscle, the extract was diluted 1:1 with distilled water and filtered. After mordanting formalin-fixed paraffin sections with 0.25% KMnO₄ for 5 min, and bleaching with 5% oxalic acid for 10 min, they were washed in water and stained for 2-24 hr at room temperature. The striations were stained light to deep golden brown. For use as a counterstain, a 1:6 dilution of the original extract was required. When applied after haematoxylin for 15-30 min, it stained tissue components in varying shades of golden brown with distribution comparable to that produced by 1% eosin.     

Histochemical localization of protein-polysaccharides in renal tissue

The purpose of this study was to investigate the distribution of protein-polysaccharides in the glomerular and non-glomerular regions of the nephron. The techniques used include the digestion of kidney slices with specific polysaccharidases: neuraminidase, hyaluronidase, chondroitinase ABC, and collagenase followed by several cytochemical techniques to identify the glycosaminoglycans and glycoproteins at the light and electron microscope levels. Differential staining of hyaluronic acid and sulphated glycosaminoglycans was accomplished with Alcian Blue at pH 2.5 and pH 0.5, respectively. Sialoproteins were stained with Alcian Blue at pH 2.5. The periodic acid Schiff’s reaction technique was employed for the visualization of collagen. At the electron microscope level the polysaccharides were identified with the periodic acid-chromic acid-silver methenamine reaction. Our results indicated that the major polysaccharide components of the glomerular basement membrane were sialoproteins and collagen, with smaller amounts of hyaluronic acid and various sulphated glycosaminoglycans. Hyaluronidase digestion resulted in partial detachment of epithelial processes from the glomerular basement membrane indicating the hyaluronic acid may have a role in the stability of the attachment of these processes. Tubular basement membranes also contain sialoproteins and sulphated glycosaminoglycans but in considerably lower concentrations than the glomerular basement membrane. Bowman’s capsule appears to contain mostly sulphated glycosaminoglycans and has a lower concentration of sialoproteins and hyaluronic acid.     

A Method for Staining Pollen Tubes in Pistil

A quadruple staining procedure has been developed for staining pollen tubes in pistil. The staining mixture is made by adding the following in the order given: lactic acid, 80 ml; 1% aqueous malachite green, 4 ml; 1% aqueous acid fuchsia, 6 ml; 1% aqueous aniline blue, 4 ml; 1 % orange G in 50% alcohol, 2 ml; and chloral hydrate, 5 g. Pistils are fixed for 6 hr in modified Carnoy's fluid (absolute alcohol:chloroform:glacial acetic acid 6:4:1), hydrated in descending alcohols, transferred to stain and held there for 24 hr at 45±2 C They were then transferred to a clearing and softening fluid containing 78 ml lactic acid, 10 g phenol, 10 g chloral hydrate and 2 ml 1% orange G. The pistils were held there for 24 hr at 45±2 C, hydrolyzed in the clearing and softening fluid at 58±1 C for SO min, then stored in lactic acid for later use or immediately mounted in a drop of medium containing equal parts of lactic acid and glycerol for examination. Pollen tubes are stained dark blue to bluish red and stylar tissue light green to light greenish blue. This stain permits pollen tubes to be traced even up to their entry into the micropyle.     

Grimelius' Silver Stain for Endocrine Cell Granules, as Shown by Electron Microscopy

The silver impregnation method of Grimelius has been applied to 100-150 μ thick sections of tissues fixed 2 hr to 1 mo in mixtures containing formaldehyde, glutaraldehyde or picric acid. After silvering, the sections (partly postfixed in 1% OsO₄, for 0.5 hr) were processed for electron microscopy. Endocrine granules of pancreatic A cells, enter-ochromaffin and some nonenterochromaffin cells of the gastrointestinal mucosa, thyroid C cells and adrenal medullary cells were found to be selectively stained by silver grains 10-30 nm in diameter, either as a peripheral “halo” or covering the entire granule. At least in some cells, the reactive material should not be identified with the hormonal products known to be stored in the granules.     

Staining Mitochondria With Hematoxylin After Formalin-Sublimate Fixation; A Rapid Method

Mitochondria were stained in liver, kidney, pancreas, adrenal and intestinal mucosa of rat and mouse. Tissues 1 mm thick, were fixed in a mixture of saturated aqueous HgCl₂, 90 ml; formalin (37-38% HCHO), 10 ml, at room temperature (25°C) for 1 hr. Deparaffinized sections 3-4μ thick were treated with Lugol's iodine (U.S.P.) followed by Na₂S₂O₃ (5%), rinsed in water and the ribonucleic acid removed by any of the following procedures: 0.2 M McIlavaine's buffer, pH 7.0, 2 hr, or 0.2 M phosphate buffer, pH 7.0, 2 hr at 37°C; 0.1% aqueous ribonuclease, 2 hr at 37°C; 5% aqueous trichloracetic acid overnight at 37°C; or 1% KOH at room temperature for 1 hr. After washing in water, sections were treated with a saturated solution of ferric ammonium alum at 37°C for 8-12 hr and colored by Regaud's ripened hematoxylin for 18 hr. They were then differentiated in 1% ferric ammonium alum solution while under microscopic observation.