Decomposition of Sudan Black B by Ultraviolet Light and Gases; its Lipid and Protein Staining Properties

The bluish-black spots of lipid-containing materials stained with a saturated solution of Sudan black B in 55% ethanol were found to fade and change color to brownish-pink shades in 5 min if exposed to ultraviolet light. Spots that were exposed to daylight for 6 hr on a sunny day lost 14% of their original color intensity but the decrease was less on cloudy days. Exposure to H₂S initiated fading and color change in 2 hr. Exposure to HCl vapors restored the original color but not its intensity. Spots kept in darkness and wrapped airtight showed a decline of 2.5% in color intensity after 96 hr and no obvious color change. The speed and extent of change of color and fading of the various fractions of the dye separated by means of paper chromatography were different. Heat coagulated serum proteins were stained blue with commercial Sudan black B solution in 55% ethanol.     

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     

Effect of phosphomolybdic acid on the binding of Sudan black B

Paraffin sections of tissues fixed in absolute alcohol or Carnoy's fluid were mordanted in a 1% aqueous solution of phosphomolybdic acid, stained in saturated solutions of Sudan black B, acetylated Sudan black, various solvent and basic dyes in 70% ethyl alcohol for 5 min at room temperature, dehydrated in alcohol and covered in Permount. Sudan black B and other dyes with basic groups stained basement membranes, reticulum and collagen fibers intensely. Acetylated Sudan black, Sudan IV and oil red 0 did not color any tissue structures. Control sections, without pretreatment, did not bind Sudan black B. These findings indicate interaction between basic groups of the dye and free acid groups of phosphomolybdic acid.     

Simultaneous Demonstration of Lipids and Starch in Plant Tissues

A rapid and easy technique for the simultaneous demonstration of lipids and starch in the same histological section is described. Tissues are prepared by the clamical fixing and Araldite in embedding techniques of election microscopy. Semithin sections are directly stained for 1 hour at 60C with saturated Sudan black B in 70% ethanol without removing the embedding resin. Lipids stain black; stain is shown as white grains contrasting with the blue-grey embedding resin.     

Simultaneous demonstration of lipids and starch in plant tissues.

A rapid and easy technique for the simultaneous demonstration of lipids and starch in the same histological section is described. Tissues are prepared by the classical fixing and Araldite M embedding techniques of electron microscopy. Semithin sections are directly stained for 1 hour at 60C with saturated Sudan black B in 70% ethanol without removing the embedding resin. Lipids stain black; starch is shown as white grains contrasting with the blue-grey embedding resin.     

Loss of Rna and Protein, And Changes in Dna During A 30-Hour Cold Perchloric Acid Extraction of Cultured Cells

KB cells derived from human carcinoma were fixed in acetic-alcohol (1:3) and extracted with 10% perchloric acid (PCA) at 4 C for 1, 3, 6, 9, 12, 24 and 30 hr. Cells were then washed in water and stained for nucleic acids, proteins, polysaccharides, and lipids. Control cells were kept in water for 30 hr prior to staining. Acridine orange (AO) fluorochroming revealed color changes in residual cytoplasmic and nucleolar RNA as well as DNA during extraction--interpreted as indicative of molecular alterations. All nucleic acid stains (AO, gallocyanin chromalum, and azure B bromide) demonstrated a differential extraction of RNA, with cytoplasmic RNA being removed in about 6 hr and nucleolar RNA requiring 6 more hours for complete extraction. Large granules appeared early in nuclei. These were positive for DNA by azure B, gallocyanin chromalum, Feulgen, and fluorescent-Feulgen. These same granules stained for protein by mercuric bromphenol blue and alkaline Biebrich scarlet. At 24 hr, there was visual and Feulgen-cytophotometric evidence for a slight loss of DNA, which may amount to 10-20%. There was a progressive loss of cytoplasmic and nuclear but not nucleolar protein during PCA treatment. Concurrently, large protein-positive granules appeared in the cytoplasm. Apparently, PCA treatment in combination with an aqueous wash was responsible for some protein loss. Glycogen was gradually lost (fluorescent PAS) and redistributed in cells. Lipids were unaffected (Sudan black B).     

Propylene and Ethylene Glycol as Solvents for Sudan IV and Sudan Black B

Propylene or ethylene glycol is recommended as a solvent for Sudan IV and Sudan black B to replace the commonly used alcohol-acetone mixtures for general lipid staining in tissue sections. Either glycol is used as a dehydrating agent, dye solvent, and differentiating solution. They offer the advantages of a stable solution, inert with respect to solubilities of lipid material in it, and excellent control of differentiation without loss of dye from lipid particles. Sections remain pliable and are not shrunken by the glycols. Counterstains may be used after staining with Sudan IV but are generally not necessary after staining with Sudan black B. With the use of propylene glycol as a solvent, Sudan IV appears to equal the staining ability of Sudan black B as regards the type of lipid material detected, and the choice of dye to be used would depend on the color contrast desired.     

The Use of Sudan Black B as a Bacterial Fat Stain

Sudan black B was introduced as a specific fat stain for the detection of lipids in tissue sections by L. Lison in 1934. Saturated solutions of Sudan black B in 70% alcohol or in ethylene glycol stain the fat bodies of bacteria a deep blue-black color, and this dye is recommended as superior to the other Sudans.

The method used in staining the bacteria was to suspend a loopful of the cells in a drop of the stain solution and to prepare flat wet mounts. The organisms giving positive fat tests with Sudan black B included Bacillus cereus, Bacillus mycoides, Azotobacter beijerinckii, Rhizobium leguminosarum, Mycobacterium avium, Mycobacterium leprae, Oospora lactis, Bacillus tumescens, water spirilla, and fungi.     

Sudanophilia and lipids in the blood and marrow cells

Summary The method of Sheehan and Storey, used for demonstrating stable Sudanophilia of neutrophils in smears, was modified by substituting other alcohols (from methanol to amyl alcohol) for ethanol, and the effect of this on the resulting staining reactions was investigated. The intensity of the staining of the neutrophil granules decreases with increasing number of carbon atoms in the alcohol, with a gradation of staining from black to yellow, while, at the same time the staining of the erythrocytes increases. The best solvent for Sudan black B for haematological purposes is methanol. This solvent was further used for investigations on various procedures for detecting so-called masked sudanophilia. The most constant and interesting results were obtained after the action of mercuric ions on smears fixed in formalin vapour. Under certain conditions, a characteristic binding of different fractions of Sudan black B on different blood cells can be attained, so that neutrophil granules are stained brown, monocytes mostly grey, lymphocytes, platelets, megakaryocytes, plasmocytes and perinuclear areas of normoblasts blue. The present experiments with various substrates indicate that demasked blue staining in the cytoplasm may be conditioned by phospholipids, although a reaction with other components of the cytoplasm cannot be excluded. The method described may be useful in haematology for studying cytogenetic relations in the monocytic and granulocytic series.Technical Assistance: V. LodrovÁ.     

Some aspects of the value of Sudan Black B in lipid histochemistry

Summary The lipid dye Sudan Black B, as generally used to demonstrate lipids in the interior of the cell nucleus, was studied with regard to its staining properties for isolated nuclei in relation with its chromatographic characteristics in solution, as well as with a model system consisting of lipid containing polyacrylamide films.Isolated nuclei are stained with Sudan Black B dissolved in ethylalcohol, only when the dye-solution is at least one month old. Extraction with chloroform-methanol (21) before stainig resulted in a decrease of 35% in intensity. Treatment with proteolytic enzymes and DNA-se caused a complete disappearance of the staining capacity. The binding of Sudan Black B with phospholipids enclosed in the form of liposomes in modelfilms when stained with this dye in ethylene glycol obeys the law of Lambert-Beer. Proteins were however, also coloured by the dye.The chromatographic experiments showed that the dye is built up from two main and a number of secondary products. The secondary products which increase by aging of the dye-solution, change the spectrophotometric properties of the total dye and show aspecific binding.The conclusion was reached that on the basis of a positive reaction with Sudan Black B no definite conclusions can be drawn about the presence of lipids in the interior of the cell nucleus.     

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.     

Some aspects of the value of Sudan Black B in lipid histochemistry.

The lipid dye Sudan Black B, as generally used to demonstrate lipids in the interior of the cell nucleus, was studied with regard to its staining properties for isolated nuclei in relation with its chromatographic characteristics in solution, as well as with a model system consisting of lipid containing polyacrylamide films. Isolated nuclei are stained with Sudan Black B dissolved in ethylalcohol, only when the dye-solution is at least one month old. Extraction with chloroform-methanol (2:1) before staining resulted in a decrease of 35% in intensity. Treatment with proteolytic enzymes and DNA-se caused a complete disappearance of the staining capacity. The binding of Sudan Black B with phospholipids enclosed in the form of liposomes in modelfilms when stained with this dye in ethylene glycol obeys the law of Lamber-Beer, Proteins were however, also coloured by the dye. The chromatographic experiments showed that the dye is built up from two main and a number of secondary products. The secondary products which increase by aging of the dye-solution, change the spectrophotometric properties of the total dye and show a specific binding. The conclusion was reached that on the basis of a positive reaction with Sudan Black B no definite conclusions can be drawn about the presence of lipids in the interior of the cell nucleus.     

Detection of lipids in the plant meristematic cell with the aid of Sudan black staining

As lipids can be a source of artefacts during intracellular localization of enzymes by cytochemical methodsin situ it was the aim of the present work to obtain orientation data on the distribution of lipids in the meristematic plant cells. The different fixation and object embedding methods examined revealed that it is best to fix the material by some formol fixative and without chroming, to embed it in polyethyleneglycol media. An alcoholic solution of Sudan black was found to be most reliable. In the meristematio cells the cytoplasm is usually stained more intensely than the nucleus. The ground cytoplasm is stained weakly while cytoplasmic particles are stained intensely. In some cases an intense black staining of nuclei, particularly in the prolongation zone, can be achieved. The staining intensity of cell components does not decrease on extracting lipids with pyridine. After extracting the dye from stained cell components a browninsh residual coloration remains. Chromatography of Sudan black revealed in all the samples tested slowly moving spots (blue and violet) and rapidly moving ones (red II, yellow, red I, colourless).     

A Sudan Black B Myelin Stain for Peripheral Nerves

Blocks of fresh issue were fixed 2 or more days in: cobalt sulfate (or nitrate), 1 gm; distilled water, 80 ml; 10% calcium chloride, 10 ml; and formalin, 10 ml. The fixed tissue was washed thoroughly in tap water, embedded in gelatin, frozen sections cut, and mounted on slides with gelatin adhesive. The sections were stained 15-30 min in a saturated, filtered solution of Sudan black B in 70% alcohol, differentiated in 50% alcohol under microscopic observation, and a cover glass applied with glycerol-gelatin. In thick (50-100 μ) sections, myelin stained green to gray-green and this allowed easy differentiation between nerves and other tissue elements.     

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.     

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.     

Taenia taeniaeformis: early inflammatory response around developing metacestodes in the liver of resistant and susceptible mice II. Histochemistry and cytochemistry

Female BALB/cJ (resistant), C3H/HeJ (intermediate resistant), and C3H/HeDub (susceptible) inbred mice, 4-5 wk old, were infected with Taenia taeniaeformis. Liver sections were stained for the enzymes acid phosphatase, beta-glucuronidase, and peroxidase. Eosinophils present around the parasite were identified by the ethanolic Congo red method. Possible gross changes in lipid metabolism in the hepatocytes surrounding the parasite were investigated with the Sudan black B method. The results of observations made by light microscopy were: (1) beta-glucuronidase activity above background levels was observed only in the hepatocytes around the parasite in BALB/cJ mice at 4, 5, and 6 days postinfection (PI); no reaction was observed in the other 2 strains of mice studied; (2) acid phosphatase activity was very strong at 2, 3, and 4 in the 3 strains of mice while this reactivity was weak at 5 and 6 days PI; (3) the cytoplasm of the hepatocytes around the metacestode stained more heavily with Sudan black B than other hepatocytes; and (4) the presence of eosinophils appearing at 3 days PI around the parasite in all 3 strains of mice was demonstrated by staining with Sudan black B, the substrate of peroxidase, and Congo red. Infected C3H/HeJ and BALB/cJ mice had higher numbers of liver eosinophils than infected C3H/HeDub mice throughout the observation time. The present results suggest 2 conclusions: (1) a parasite-liver interaction occurs as is evident by hepatocyte changes in beta-glucuronidase activity and Sudan black B staining, and (2) resistance to the early stages of T. taeniaeformis is associated with the appearance of eosinophils.     

Pattern of lipofuscin pigmentation in nitrergic and non-nitrergic,neurofilament immunoreactive myenteric neuron types of human small intestine

Lipofuscin, an autofluorescent age pigment, occurs in enteric neurons. Due to its broad excitation and emission spectra, it overlaps with commonly used fluorophores in immunohistochemistry. We investigated the pattern of lipofuscin pigmentation in neurofilament (NF)-reactive nitrergic and non-nitrergic human myenteric neuron types. Subsequently, we tested two methods for reduction of lipofuscin-like autofluorescence. Myenteric plexus/longitudinal muscle wholemounts of small intestines of five patients undergoing surgery for carcinoma (aged between 18 and 69 years) were double stained for NF and neuronal nitric oxide synthase (nNOS). Lipofuscin pigmentation patterns were semiquantitatively evaluated by using confocal laser scanning microscopy with three different excitation wave lengths (one for undisturbed lipofuscin autofluorescence and two for specific labellings). Two pigmentation patterns could be detected in the five NF-reactive neuron types investigated. In nitrergic/spiny as well as in non-nitrergic/stubby neurons, coarse, intensely autofluorescent pigment granules were prominent. In non-nitrergic type II, III and V neurons, a fine granular, diffusely distributed and less intensely autofluorescent pigment was obvious. After incubation of wholemounts in either CuSO₄ or Sudan black B solutions, unspecific autofluorescence could be substantially reduced whereas specific NF and nNOS fluorescence remained largely unaffected. We conclude that NF immunohistochemistry is useful for morphological representation of subpopulations of human myenteric neurons. The lipofuscin pigmentation in human myenteric neurons reveals at least two different patterns which can be related to distinct neuron types. Incubations of multiply stained whole mounts in both CuSO₄ or Sudan black B are suitable methods for reducing autofluorescence thus facilitating discrimination between specific (immunohistochemical) and non-specific (lipofuscin) fluorescence.     

Sudan Black and Osmic Acid as Staining Agents for Testicular Interstitial Cells

Two standard cytological techniques have heen modified to stain specifically the interstitial cells of the testis. In Method 1, the tissue is fixed in Zenker-formol or Regaud's fluid for several hours or overnight and subsequently postchromed in 3% K₂Cr₂O₇ for 72 hr at 37°C. After paraffin embedding, sections are cut at 5μ, dewaxed, brought down to 70% alcohol and stained in an unfiltered saturated solution of Sudan black in 70% alcohol for 10-30 min. Sections are washed briefly in 70% alcohol to remove all excess dye, differentiated, if necessary, in 50% alcohol, downgraded to water and mounted in Farrants' medium or glycerol jelly. Interstitial cells: deep blue black; remainder of testicular tissue: light blue. Method 2 is essentially the Champy-Kull technique but specific staining for mitochondria is omitted and the sections are downgraded to water; then they are mounted in Farrants' medium or glycerol jelly without further treatment. In this way osmicated lipoids are preserved. Interstitial cells: conspicuous due to the variable number of black granules in their cytoplasm; the remainder of the tissue: yellow.     

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.