Brazilin-Toluidine Blue O and Hematoxylin-Darrow Red Methods for Brain and Spinal Cord

Tissue fixed in 10% formalin, formalin-95% ethanol 1:s CaCO₂ or phosphate buffer neutralized formalin, or methanol-chloroform 2:1, was dehydrated and embedded in paraffin or double-embedded by infiltration in 1% celloidin followed by a chloroform-paraffin sequence. Sections were attached to slides with either albumen or gelatine adhesive and processed throughout at room temperature of 24-26 C. For either method, mordanting 30-60 min in 1% iron alum was followed by a 10 min wash in 4 changes of distilled water. For brazilin-toluidne blue O, myelin was stained for 20-60 min, depending upon section thickness, in a self-differentiating solution consisting of: 0.15% Li₂CO₃ 75 ml; 6% brazilin in 95% ethanol, 25 ml; and NaIO₃ 75 mg. After a thorough washing, Nissl material was stained for 3-8 min in a solution consisting of: 0.1 M acetic acid, 90 ml; 0.1 M sodium acetate, 10 ml; and 1% toluidine blue 0, 2.5 ml. For hematoxylin-Darrow red, myelin was stained for 2-6 hr in a self-differentiating solution consisting of: 0.15% Li₂,CO₃ 95 ml; 10% hematoxylin in 95% ethanol, 5 ml; and NaIO₃ 25 mg. After a thorough washing, Nissl material was stained for 20 min or less in a solution consisting of: 0.1 M acetic acid, 90 ml; 0.1 M sodium acetate, 10 ml; Darrow red, 25 mg. This mixture was first boiled, cooled to room temperature and filtered. In both methods, washing, dehydration, clearing, and mounting completed the process. In the brazilin-toluidine blue technic, myelin sheaths were stained reddish purple; neuronal nuclei light blue with dark granules of chromatin; nucleoli dark blue; and cytoplasm blue with dark blue Nissl granules. In the hematoxylin-Darrow red procedure, myelin sheaths were blue-black; nuclei light red with dark granules of chromatin; nucleoli almost black; and cytoplasm red with bright red Nissl granules.     

Selective staining methods for cartilage of rat fetal specimens previously treated with alizarin red S.

A convenient method for staining cartilage with several basic stains after alizarin red S staining of bone was investigated in rat fetuses. It was found that bromophenol blue was useful and effective for staining of the margin and center areas of cartilage, even in specimens stored in glycerin for over 10 years. The specimens were washed in running tap water for 1 hr, and subsequently were immersed in water or in 70% ethanol at pH 4 for 1 hr or longer. The specimens were then stained with 0.005% bromophenol blue in 40% ethanol adjusted to pH 4 for 2 hr, or with 0.001% bromophenol blue in 40% ethanol adjusted to pH 4 for 24 hr. Furthermore, the bromophenol blue stain color actually faded when the specimens were immersed in water or in 70% ethanol at pH 8. Descending order of the stain-effective action on fetal rat cartilage for the basic stains tested was bromophenol blue, aniline blue, Evans blue, methyl violet, trypan blue, and water blue.     

A method for the identification of sulfated glycopeptide by two-dimensional electrophoresis on cellulose acetate membrane

Two-dimensional electrophoresis on cellulose acetate membrane permits the clean separation of sulfated glycopeptide in a mixture of acidic glycans (glycosaminoglycans and acidic glycopeptides). Two systems were used. In system 1, 0.1 M pyridine-0.47 M formic acid buffer (pH 3.0) was used in the first and 0.1 M barium acetate (pH 8.0) in the second dimension. In system 2, 0.1 M pyridine-0.47 M formic acid buffer (pH 3.0) was used in the first and 0.1 M HCl in the second dimension. All of the acidic glycans on electrophoretogram were stained with alcian blue in 70% ethanol. On the other hand, sulfated glycans alone were made visible with alcian blue in 0.1 M HCl. Alcian blue in 70% ethanol or 0.1 M HCl, when combined with periodic acid-Schiff's reagent identified sulfated glycopeptides on cellulose acetate membrane.     

Staining of Acid Mucopolysaccharides after Chromatography on Filter Paper

Acid mucopolysaccharides obtained both from commercial sources and by isolation from human urine have been chromatographed on Whatman No. 1 filter paper, using propanol or ethanol in pH 6.5 M/15 phosphate buffer as solvent systems. The chromatograms are then fixed by immersion in 95% alcohol and in diethyl ether. After drying, they are stained in 0.06% toluidine blue O in 0.5% aqueous acetic acid. A final rinsing in 2% aqueous acetic acid removes the excess dye from the paper and exposes the stained mucopolysaccharide to a pH favoring orthochromasia.     

Staining of Acid Mucopolysaccharides after Chromatography on Filter Paper

Acid mucopolysaccharides obtained both from commercial sources and by isolation from human urine have been chromatographed on Whatman No. 1 filter paper, using propanol or ethanol in pH 6.5 M/15 phosphate buffer as solvent systems. The chromatograms are then fixed by immersion in 95% alcohol and in diethyl ether. After drying, they are stained in 0.06% toluidine blue O in 0.5% aqueous acetic acid. A final rinsing in 2% aqueous acetic acid removes the excess dye from the paper and exposes the stained mucopolysaccharide to a pH favoring orthochromasia.     

Oil Blue Na as A Stain for Rubber in Sectioned or Ground Plant Tissues

Oil blue NA (Calco), a stain which colors rubber bright blue, has been used effectively in studying the distribution of rubber in several plant species. Fresh or fixed sections are cut, bleached with Javelle water or NaOCl solution, treated with 9% KOH in 95% ethanol, washed with several changes of water and finally with 95% ethanol, and stained with 0.05% oil blue NA in 70% ethanol. Sections are rinsed in 50%' ethanol, placed in 40% glycerin, and mounted in glycerin jelly.

For the detection of changes in the distribution and character of rubber in milled or ground tissues, much the same staining procedure is followed. The stained tissues usually are examined and dissected under a stereoscopic microscope, a procedure which permits rubber to be recognized by both its staining reaction and by a more specific property, elastic elongation.

A microscopic technic is presented whereby it is possible to determine approximately the relative proportion of dispersed and coagulated rubber latex in unstained tissues.     

Gallocyanin-Chrome Alum Counterstaining of Golgi-Kopsch Impregnations

A simple technique is described for counterstaining Golgi-Kopsch impregnations. The sections are first stabilized by the method of Geisert and Updyke and then stained in 0.15% gallocyanin and 5% chromium potassium sulfate for 45 minutes at 55-60 C. The sections are then rinsed, dehydrated to 70% ethanol, cleared in terpineol, mounted and coverslipped. This procedure results in a light to medium blue stain of those cells not impregnated by the silver chromate. The major advantages of this procedure over earlier methods are: (1) the counterstain does not fade and (2) since no differentiation is required, many sections may be stained simultaneously.     

Gallocyanin-chrome alum counterstaining of Golgi-Kopsch impregnations

A simple technique is described for counterstaining Golgi-Kopsch impregnations. The sections are first stabilized by the method of Geisert and Updyke and then stained in 0.15% gallocyanin and 5% chromium potassium sulfate for 45 minutes at 55-60 C. The sections are then rinsed, dehydrated to 70% ethanol, cleared in terpineol, mounted and coverslipped. This procedure results in a light to medium blue stain of those cells not impregnated by the silver chromate. The major advantages of this procedure over earlier methods are: (1) the counterstain does not fade and (2) since no differentiation is required, many sections may be stained simultaneously.     

A rapid procedure for routine double staining of cartilage and bone in fetal and adult animals

A simple, rapid procedure for dual staining of cartilage and bone in rodents, particularly in late gestation, has been developed for routine use. The procedure involves rapid, complete skinning of fresh eviscerated specimens following a 30 sec immersion in a 70 C water bath. The unfixed specimen is stained in a mixture of 0.14% Alcian blue and 0.12% alizarin red S in ethanol and glacial acetic acid. Specimens are then macerated in 2% KOH, cleared and hardened in 1:1 glycerin and distilled water, and stored in pure glycerin. Rapid staining of cartilage only is done in a mixture of 0.08% Alcian blue, glacial acetic acid, and ethanol, with subsequent maceration, clearing, and hardening as in the double staining procedure. Rapid staining of bone only, concurrent with maceration of soft tissue, can be done by placing fresh, unskinned specimens in a diluted mixture of alizarin red S in 2% KOH, with subsequent clearing and hardening in 1:1 distilled water and glycerin. Good quality fetal specimens can be prepared for examination by any of these procedures in a minimum of 11/2-2 days as compared to a minimum of 4-5 days for other procedures. Double stained specimens can be examined for abnormalities of the cartilage as well as bone.     

Luxol Fast Blue Mbs: A Stain for Phase Contrast Microscopy

A staining method to increase the contrast of sectioned material for phase contrast microscopy is described. Two stock solutions of the stain are required. The first is made by dissolving 2 gm of luxol fast blue MBS in 100 ml of 95% ethanol. The second solution is made up of 4 ml of a 29% aqueous solution of FeCl₃, 95 ml of 95% ethanol, and 1 ml of concentrated HCl. The staining solution is made by mixing equal parts of the two solutions. Sections are deparaffinized and taken to 70% alcohol, stained for 1.5 hr, dehydrated, cleared and covered as usual.     

Advantages of picrate fixation for staining polypeptides in polyacrylamide gels

When acetic acid-urea polyacrylamide gels with or without Triton X-100 were immersed in 0.1 M Na picrate, pH 7, to which 1/4 vol Coomassie blue staining solution (0.2% in 45% methanol, 10% acetic acid, 45% water) was added, proteins stained rapidly (within a few minutes in gels without Triton and within an hour in gels with Triton) with little or no background staining. Thus protein bands could be observed in a single step with no destaining. The picrate-Coomassie blue method fixed and stained a small peptide (bradykinin, nine amino acids) that was not observed in gels stained with fast green, silver, or Coomassie blue following fixation in 50% trichloroacetic acid. The picrate-Coomassie blue method gave high-contrast bands suitable for densitometry. Gels containing sodium dodecyl sulfate were also stained by the picrate-Coomassie blue method if they were first washed briefly (1 h) in 45% methanol, 10% acetic acid, 45% water, presumably to remove the detergent. These gels also stained rapidly with almost no background.     

Fixation and Staining of Planaria for Histological Study

Fixation and staining of planaria can affect the interpretation of histopathological changes following their exposure to various agents. We assessed several fixation protocols with various stains in planaria to determine an optimal combination. Planaria were fixed in each of the following: 10% neutral buffered formalin, 2.5%, glutaraldehyde, Bouin's, Zenker's, 70% ethanol, and relaxant. In addition, planaria were fixed in relaxant and postfixed in each of the fixatives above. Paraffin embedded sections from each fixation protocol were stained with hematoxylin and eosin (H & E), toluidine blue, periodic acid-Schiff (PAS), or phosphotungstic acld-hematoxylin (PTAH). Relaxant fixed planaria were also stained with Steiner's, Holmes, trichrome, Giemsa, Grocott's methenamine silver (GMS) and antibodies for intermediate filaments (cytokeratin, vimentin and desmin). Relaxant and Zenker's gave the best fixation with minimal artifacts. Formalin, glutaraldehyde, and ethanol were unacceptable because they caused contortions of the body, crenation, and a darkly pigmented epidermis. Gastroderm could be differentiated from stroma best when stained with H & E, toluidine blue and PTAH. Other organ systems differentially stained included the epidermis, marginal adhesion gland, nervous tissue, and muscle. PAS, Steiner's, Holmes, trichrome and the intermediate filament stains were not useful for planaria staining. The most morphological information was obtained with relaxant fixative and a combination of sections stained with H & E and PTAH.     

New Uses for Calcium Chloride Solution as a Mounting Medium

Fresh cross sections of stems [Psilotum nudum, Coleus blumei, and Pelargonium peltatum] and roots (Setcreasea purpurea) 120 μm thick were fixed in FPA₅₀ (formalin: propionic acid: 50% ethanol, 5:5:90, v/v) for 24 hr and stored in 70% ethanol. The sections were transferred to water and then to 1% phloroglucin in 20% calcium chloride solution plus either hydrochloric, nitric, or lactic acid in the following ratios of phloroglucin-CaCl₂ solution:acid: 25:4, 20:2, or 15:5. The sections were mounted on slides either in one of the three mixtures or in fresh 20% calcium chloride solution. A rapid reaction of the acid-phloroglucin with lignin produced a deep red color in tracheary elements and an orange-red color in sclerenchyma. Fixed and stored leaf pieces from Nymphaea odorata were autoclaved in lactic acid, washed in two changes of 95% ethanol, transferred to water, and treated with the three acid-phloroglucin-calcium chloride mixtures. The abundant astrosclereids stained an orange-red color similar to that of sclerenchyma in the sections. In addition, a new method is reported for specifically staining lignified tissues. When sections or leaf pieces are stained in aqueous 0.05% toluidine blue O, then placed in 20% calcium chloride solution, all tissues destain except those with lignified or partially lignified cell walls. Thus, toluidine blue O applied as described becomes a reliable specific test for lignin comparable to the acid-phloroglucin test.     

A simple two-dye basic stain facilitating recognition of mitosis in plastic embedded tissue sections

Semithin sections of buccal and palatal mucosa fixed in 2.5% glutaraldehyde followed by 1% osmium and embedded in Durcupan (an araldite-based resin) were stained with 2% malachite green in 50% ethanol at 80 C and poststained in 0.05% crystal violet in Sorensen's phosphate buffer (pH 6.4) at 45 C. Nuclear envelopes and chromatin stain vivid purple in contrast to the surrounding green cytoplasm and cell borders. Chromosomes of dividing cells stain bluish violet. Nucleoli, depending on their level in the epithelium, stain differing shades of greenish blue. The distinct and differential staining of each of these components facilitates recognition of mitoses in oral epithelium, where the small size and crowding of cells in the proliferative compartment renders more conventional stains for plastic sections inadequate.     

A Cytochemical Technique for Demonstration of Lipids,Polysaccharides and Protein Bodies in Thick Resin Sections

An effective cytochemical technique for the simultaneous demonstration of lipids, polysaccharides and protein bodies in the same section from the tissue embedded in Epon 812 is described. Thick sections of peanut cotyledon are used for a typical sample according to the following procelures. Firstly, PAS reaction: (1) Oxidize sections in 0.5% periodic acid in 0.3% nitric acid for 10 min, (2) Wash in running water for 1–2 min and then pass through distilled water, (3) Stain in Schiff's reagent for 30 min, (4) Wash in sodium metabisulfite 3 times, 2 min for each time, (5) Wash in running water for 5 min and then pass through distilled water. Secondly, Sudan black B staining: (1) Rinse section in 70% ethanol for 1-2 min, (2) Stain in fresh 1% Sudan black B in 70% ethanol for 30–60 min at 40–60℃, (3)Rinse in 70% ethanol for 1 min and then in distilled water. Thirdly, Coomassie brilliant blue R staining: (1) Rinse sections in 7% acetic acid for 1–2 min, (2) Stain in I% Coomassie brilliant blue R in 7% acetic acid for 20 min at 60℃, (3) Differentiate in 0.1% acetic acid for I min, (4) Rinse in lunning water for 5 min and then pass through distilled water, (5) Dry at room temperature or in oven, 40℃. The dry sections mount in glycerin-gelatin. After the above three step staining, the three main compounds of the cell can be stained simultaneously. Starch grains and cellulose cell wall take cherry red colour, lipids appear in black, protein bodies are blue. The sealed slides can be kept permanently.     

A Simple Two-Dye Basic Stain Facilitating Recognition of Mitosis in Plastic Embedded Tissue Sections

Semithin sections of buccal and palatal mucosa fixed in 2.5% glutaraldehvde followed by 1% osmium and embedded in Durcupan (an araldite-baaed resin) were stained with 2% malachite green in 50% ethanol at 80 C and poststained in 0.05% crystal violet in Sorensen's phosphate buffer (pH 6.4) at 45 C Nuclear envelopes and chromatin stain vivid purple in contrast to the surrounding green cytoplasm and cell borders. Chromosomes of dividing cells stain bluish violet. Nucleoli, depending on their level in the epithelium, stain differing shades of greenish blue. The distinct and differential staining of each of these components facilitates recognition of mitoses in oral epithelium, where the small sice and crowding of cells in the proliferative compartment renders more conventional stains for plastic sections inadequate.     

A Tribasic Stain for Thin Sections of Plastic-Embedded, OsO4-Fixed Tissues

Thin (0.5-1 μ) sections of plastic-embedded, OsO₄-fixed tissues were attached to glass slides by heating to 70 C for 1 min. A saturated solution combining toluidine blue and malachite green was prepared in ethanol (8% of each dye) or water (4% of each dye). Methacrylate or epoxy sections were stained in the ethanol solution for 2-5 min. The water solution was more effective for some epoxy sections (10-80 min). Epoxy sections could be mordanted by 2% KMnO₄, in acetone (1 min) before use of the aqueous dye, reducing staining time to 5-10 min and improving contrast. Aqueous basic fuchsin (4%) was used as the counter-stain in all cases; staining time varied from 1-30 min depending upon the embedding medium and desired effects, methacrylate sections requiring the least time. In the completed stain, nuclei were blue to violet; erythrocytes and mitochondria, green; collagen and elastic tissue, magenta; and much and cartilage, bright cherry red. Sections were coated with an acrylic resin spray and examined or photographed with an oil-immersion lens.     

Staining of interphase nuclei and mitotic figures in cultured cells with alcian blue 8GX

Cultured endothelial cells derived from bovine calf pulmonary artery were subjected to a variety of fixatives and stained with 1% Alcian blue 8GX at pH 2.59 to 3.26. Within this range of pH, interphase nuclei and especially mitotic figures were (a) strongly stained in cells fixed with 10% formalin (phosphate buffered or unbuffered) or 2.5% buffered glutaraldehyde, (b) weakly stained or unstained in cells fixed in formaldehyde containing divalent cations, and (c) unstained in cells fixed in acetic acid-containing fluids. However, optimal nuclear staining with Alcian blue under the conditions of this study was judged to be achieved after fixation with neutral phosphate buffered 10% formalin. Endothelial cell cytoplasm exhibited a similar fixative-dependent staining. At pH 2.59 the cytoplasm of interphase cells fixed in formaldehyde (containing no divalent cations) or glutaraldehyde remained unstained; however, at higher pH cytoplasmic staining did occur and it increased as pH increased. In contrast, when these latter fixatives were employed the cytoplasm of mitotic cells stained at all pH levels tested. In cultured endothelial cells after appropriate fixation, 1% Alcian blue 8GX (pH 2.59) was found to possess the ability to stain nuclei with a selectivity and intensity that compared favorably to those of the Feulgen reaction of Heidenhain iron hematoxylin but without the latters' length and complexity. Therefore, this procedure may provide a rapid, simple, and selective method for visualizing interphase nuclei or mitotic figures, or both in the majority of cultured cells.     

Modified Whipf's Polychrome: A Connective Tissue Stain with Special Application for Demonstrating Leishmania

A polychrome stain procedure was developed to demonstrate amastigotes of the protozoan parasite Leishmania braziliensis as well as cytoplasmic and other tissue components in cutaneous lesions of infected animals. The procedure is as follows: stain nuclei for 10 minutes with an iron hematoxylin containing 0.5% hematoxylin and 0.75% ferric ammonium sulfate dissolved in 1:1 0.6 N H₂SO₄:95% ethanol; rinse 4 minutes in distilled water. Cytoplasmic staining is achieved by exposing tissues for 10 minutes to a solution containing 0.25% Biebrich scarlet, 0.45% orange G, 0.5% phosphomolybdic acid and 0.5% phosphotungstic acid in 1% aqueous acetic acid. These first two solutions are modified from Whipf's polychrome stain. Sections are differentiated for 10 seconds in 50% ethanol, rinsed in water, stained 3 minutes in 0.1% aniline blue WS in saturated aqueous picric acid, rinsed in water and differentiated for 1 minute in absolute ethanol containing 0.05% acetic acid. Mordanting overnight in 6% picric acid in 95% ethanol produced optimal results.

This procedure was applied to sectioned material from experimental animals with various protozoa. Trypanosoma cruzi, Besnoitia Jellisoni, Toxoplasma gondii and especially Leishmania braziliensis were well demonstrated. Combining cytoplasmic dyes and phosphomolybdic-phosphotungstic acids into one solution afforded differential staining of tissues by Biebrich scarlet and orange G; connective tissues were stained by this solution. Substantially improved definition of connective tissues resulted after counterstaining. This procedure differs from the Massou sequence in which connective tissues are first stained by cytoplasmic dyes along with other tissues and then destained prior to specific counter-staining. in comparing dyes structurally related to Biebrich scarlet, it was found that Crocein scarlet MOO, but not Poncenu S, was an acceptable substitute. Sirius supra blue GL and Sirius red FSBA were not useful as replacements for aniline blue WS in this procedure.     

Ethanol induced apoptosis in human HL-60 cells

In this study flow cytometric and morphologic methods of apoptosis detection in human promyelocytic leukemia cell line HL-60 were compared. HL-60 cells were harvested at 4, 7, 16, 24 a 48 hours after induction of apoptosis by 3 % ethanol. Little changes were observed both by flow cytometry (decrease of forward scatter, increase of unprocessed cells staining with APO2.7 antibody) and viability determination by Trypan-blue staining until after 7 hours. However, after 4 hours morphologic changes were observed in the nuclear and cytoplasmic structures using Diff-Quik stained cytospin preparations and standard light microscopic techniques (50% apoptotic cells). The same results were obtained by flow cytometric measurement of sub-diploid DNA content (sub-G1 cells), and an increase of staining with APO2.7 antibody in cells permeabilised by digitonin prior to staining. After 7 hours almost all cells exhibited apoptotic morphology. After 16 hours the cell size (forward scatter) decreased significantly, and 54% of unprocessed cells were APO2.7 positive. After 24 hours only 6% of cells were alive (high forward scatter) and these cells were APO2.7 negative. The HL-60 cells did not proliferate during the cultivation in 3% ethanol, and after 48 hours all stained by Trypan blue. HL-60 leukemic cells were CD34-/AC133-, CD33+/CD15+, and only 2% of the cells were CD95+. Induction of apoptosis by ethanol did not enhance CD95 antigen expression.