Staining Reactions of some Anionic Disazo Dyes and Histochemical Properties of the Red Impurity in Trypan Blue

Some staining properties of 10 anionic disazo dyes are clarified by comparison with previous chromatographic analysis. Trypan blue contains both blue and red components and the purified blue fraction displays no color shifts in tissue sections. Evans blue, Niagara blue 2B, Niagara sky blue, Niagara sky blue 4B and Niagara sky blue 6B generally resemble trypan blue. Congo red is a metachromatic dye and the only known example among anionic dyes of established purity whose color shows shifts in tissue sections and also in solutions with certain basic compounds. Other red dyes (Congo corinth, trypan red and vital red) are not metachromatic. The red dye impurity of trypan blue selectively stains nuclei which are pycnotic, degenerating or undergoing no further division. This reaction is apparently related to basic protein content. Other reactions of the red fraction of trypan blue (mammalian erythrocytes, blood plasma) are not fully explained on this basis.     

The Identification of Some Acid Disazo Dyes by Paper Electrophoresis of their Reduction Products

Trypan blue, Niagara blue 2B, Niagara blue 4B, Afridol blue, Evans blue, Niagara sky blue 6B, Niagara blue 5B and Chlorazol blue G cannot be distinguished by their colour or their behaviour on paper chromatography. They may, however, be identified by paper electrophoresis at pH 4 of the products obtained by reduction of the azo linkages with sodium dithionite (Na₂S₂O₄).     

A histochemical comparison of methylene-blue/acid fuchsin with hematoxylin and eosin for differentiating calcification of stromal tissue

Benign and malignant connective tissue tumors consist of a fibrous component that contains varying amounts of one or more types of bone or other calcified tissue. Diagnosis of these connective tissue tumors often poses challenges for pathologists, because it is difficult to differentiate the organic matrix of osteoid from hyalinized stroma. To establish a definitive diagnosis, it sometimes is advantageous to demonstrate histologically by special staining either the type of calcification or the presence or absence of calcification. We compared the efficacy of methylene blue-acid fuchsin (MB-AF) to hematoxylin and eosin (H-E) for connective tissue tumors suspected to contain calcifications and to devise an optimal staining technique for calcification that would be specific, simple, and cost- and time-effective. We examined 50 benign and 45 malignant connective tissue tumors that were suspected to contain calcifications. Sections were stained with H-E and MB-AF and evaluated. MB-AF stained bone pink, which contrasted with blue soft tissue. After MB-AF staining, osteoid was faint pink in a blue stromal background. Osteoid was not visualized in H-E stained sections; it was stained the same shade of pink as stromal tissue. Dystrophic calcification and cementum could be identified equally well using either staining technique, but contrast was better after H-E staining. MB-AF staining of bone was comparable to H-E staining and could be used effectively to stain bone and osteoid. MB-AF is a simple, single step procedure. It also stains cementum blue with faint blue rimming and dystrophic calcification bluish-pink, but it cannot be used as a specific stain for types of calcification other than bone and osteoid.     

A Rhodocyan Technic for Staining the Anterior Pituitary

A reproducible, one-step, differential staining technic which uses routine formalin-fixed tissue and gives brilliantly contrasting results is produced by incubating sections for 1 hr in a 60° C oven in the following dye mixture: 1% eosin B (CI#771), 8 ml; 1% anilin blue (CI#707), 2 ml; and buffer solution (0.1M citric acid, 1.1 ml; 0.2M Na₂HPO₄, 0.9 ml; distilled water, 28.0 ml) at pH 4.5. No differentiation is necessary. The method can be modified for duodenal enterochromaffin cells and alpha cells of pancreatic islets by adjusting the buffer to pH 3.6 and staining for only 3 min at 60° C.     

Vital Staining with Two Dis-Azo Textile Dyes

Subcutaneous injections of 0.25% saline solutions of two dis-azo textile dyes, calcodur pink 2BL, C. I. 353, also known as benzo fast pink 2BL and amidine fast rose 2BL, and a blue dye, dianil blue G, C. I. 508, were made on alternate days on albino rats for one week. The blue dye is closely similar to Niagara blue 4B, C. I. 520, and dianil blue R, C. I. 465. Staining reactions were much like those of other vital blue disazo dyes. Although the pink dye exhibited a similar staining pattern, there were notable differences. The tissues of most glands were stained pink or red. Nuclei of the tubular epithelial cells of the kidney contained red granules as did the cytoplasm of the Kupfer cells. Most unusual was the bright red staining of the elastica interna of medium and large sized arteries.     

A new type of two-color fluorescence staining for cytology specimens.

A new two-color fluorescence staining technique for cervical cytology specimens is described. To permit application of this staining in automated cytology, techniques for specimen collection and cell preparation giving a sufficient number of well-separated cells on slides were used. The staining consists of a combination of a modified Feulgen-acriflavine procedure for DNA and a primulin or stilbene isothiocyanate staining for protein. This results in a bright yellow nuclear fluorescence and a blue cytoplasmic fluorescence. The staining procedure can be completed in about 90 min and is therefore suitable for routine application. Sequential inspection of the yellow nuclear and blue cytoplasmic fluorescence can be done with the two-wavelength excitation method used in fluorescence microscopy. For the application of this method, special vertical illuminators are now available. These illuminators are provided with quickly interchangeable filter sets permitting consecutive visualization of, for example, only the nuclei in the first image and the whole cell in the second image. This procedure opens new possibilities for rapid image-analysis systems.     

Metachromatic Reaction of Pancreatic B Cells to Toluidine Blue; Influence of pH on Staining

The granules of islet B cells show an intense β metachromasia when paraffin sections of pancreas fixed in Bouin's fluid or formalin are dipped for 1 min in a 0.1% aqueous solution of toluidine blue O₂ buffered to pH 6.0 with acetate or phosphate. This reaction provides a quick method for surveying the condition of B cells in experimental work. A weak staining is observable at pH 4.5 and becomes distinct at pH 5.5-6.0. Oxidation of sections (0.25% KMnO₄ in 0.5% H₂SO₄, for 1 min, recommended) prior to staining intensifies the metachomatic reaction conspicuously. The metachromatic substance could not be demonstrated after fixation in either ethanol or acetone. It corresponds to the aldehyde fuchsin-positive and pseudoisocyanin-metachromatic substance in its occurrence and distribution in the B cells, as shown by different physiological states of various animals, including fasted and glucose-administered guinea pigs. It is thought to be topographically coincident but not necessarily identical to insulin.     

Oxazine Dyes. I. Celestine Blue B with Iron as a Nuclear Stain

It is suggested that celestine blue B can stain as a colloidal dispersion, the nuclear specificity of which is controlled by the pH. The staining solution is prepared by adding 0.5 ml of concentrated H₂SO₄ to 1 gm of celestine blue B and dissolving the resultant granular mass in 100 ml of 2.5% ferric alum containing 14 ml of glycerol. Sections of amphibian, avian, and mammalian tissue placed for 1 min in this solution and then rinsed in water show as sharp nuclear staining as that usually produced by hematoxylin. A wide variety of fixatives is permissible. Overstaining is not possible within reasonable limits of exposure and no differentiation nor bluing is required. Both the staining solution and stained slides are stable.     

Sequential Use of Wright's and Ziehl-Neelsen's Stains for Demonstrating Phagocytosis of Bacterial Spores

Nongerminating spores, germinating spores, and vegetative cells of Clostridium botulinum type A were observed during phagocytosis in the peritoneal fluid of white mice. Since phagocytes are easily ruptured by heat, the method described avoids heating, as this has been employed in conventional spore staining methods. A thin smear of the fluid is air dried on the slide for 2 hr, and stained by Wright's method: stain, 2 min; dilution water, 2 min; and rinsed; then in 0.005% methylene blue for 30 sec, and rinsed. This is followed by Ziehl-Neelsen's stain for 3-4 min and destained with 1: acetone-95% ethanol for 10 sec. The slide is rinsed, and Wright's staining repeated: stain 1 min, dilution 2-3 min; and thereafter washed about 5 ml of Wright's buffer. Blotting and air drying completes the staining. Non-germinating spores stain light red with a red spore wall, germinating spores are deep red throughout, vegetative cells are blue, and leucocytes show a dark purple nucleus and light blue cytoplasm.     

Staining Mitochondria in Saccharomyces cerevisiae

After testing various procedures (amidoblack 10B, acid fuchsin-methyl blue, Luxol fast blue MBS-phloxine, toluidine blue O, Jams green B and pinacyanol), three stains can be recommended for staining both types of mitochondria (globose and threadlike) in the cells of Saccharomyces cerevisiae: (1) 0.1% solution of amidoblack 10B in citrate buffer (pH 3.0) for 10 min; (2) 0.01% solution of toluidine blue O in phosphate buffer (pH 6.0) for 30 min; (3) 0.01% solution of Janus green B in distilled water (pH 5.6) for 30 min. The latter stain is most specific because its staining reaction depends upon the action of the mitochondrial enzyme cytochrome c oxidase. Yet, low concentrations and short incubation periods must be applied to avoid poisoning of the cell metabolism.     

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.     

On the specificity of staining by Alcian blue in the study of human,foetal adenohypophysis

Summary The specificity of Alcian blue staining has been investigated on a material comprising the adenohypophysis from 26 human foetuses.Two distinct types of alcianophilic cells were observed. The first cell type appears about 28 mm CRL forming small groups at the epithelial-mesenchymal junction and beneath the anlage of the fibrous capsule. Besides its alcianophilic property the cell shows a pronounced maltase-resistant PAS-positivity. The alcianophilia is due to carboxylgroups — probably of proteins as no sialic acid could be detected. By the performic acid — Alcian blue method the cell seems to show a high content of SH and S-S groups.The second type of cell appears about 70 mm CRL and is mostly located singly. It shows a pronounced alcianophilia — probably due to sulphate groups and to some extent to carboxyl groups.The role of the alcianophilic properties of the cells in typing definite cells of the foetal adenohypophysis was discussed. — Finally the pitfalls caused by different fixatives and by the use of the general polychrome staining methods for the typing of pituitary parenchymal cells were discussed.This work was supported by grants from the Association for the Aid of Crippled Children, New York, and from the Danish State Research Foundation, Copenhagen.     

A Rapid Safranin-Metal Phthalocyanine Double Staining Technique for Plants

Pure metal 4.4',4',4'-tetxa-substituted, sulfo-, carboxy- and nitrophthalocyanines were synthesized. Mounted, deparaffinized and partially dehydrated sections of plant tissues were stained with 0.5% safranin in 50% alcohol for 5-10 min. Excess safranin was removed with a series of 70%, 95% and absolute alcohol washes. The sections were then stained for 2-3 min using metal 4,4',4',4'-phthalocyanine tetracarboxylic acid (MPTC, 0.5% (V/V) containing a few drops of dilute sodium hydroxide), metal 4,4',4',4'-tetra-sulfophthalocyanine (MPTS, 0.5% (V/V)) or metal tetranitrophthalocyanine (MPTN, 0.5% (V/V) in dimethyl sulfoxide). The sections were washed with 95%, then absolute alcohol; however, the metal tetranitrophthalocyanine section was washed only with absolute alcohol. Stained sections were treated briefly with xylene, then mounted on a coverslip. Bright peacock blue (MPTC and MPTS using Cu, Co or Ni), turquoise blue (MPTN using Cu or Ni) or parrot green (zinc phthalocyanine tetracarboxylic acid-ZnPTC, zinc phthalocyanine tetranitro derivative-ZnPTN) colors were obtained. Lignin-containing cells were stained red by safranin and the remaining cell structures were stained by the metal phthalocyanine complex with color brightness superior to that of fast green. Uniform staining, no color fading after a year, reliability, brief staining times, high color contrast (log ε = 4.0-4.9) and ease of use make this double staining combination ideal for routine use and photomicrography.     

Practical staining method: T-OPA triple stain

The following procedure has proven to be successful as routine trichrome stain on paraffin embedded material: 1) Mayer's hemalum for 10 min, followed by running tap water wash; 2) staining in 1% Orange G in 1% acqueous PTA for 5 min and rinsing a few seconds in distilled water; 3) Aniline blue 1% acqueous for 5 min, followed by few seconds distilled water wash. Dehidratation in ethanol, or by blotting followed by t-buthanol or 1:3 terpineol-xylene, clearing and mounting, completed the procedure.     

Preparation of colloidal gold for staining proteins electrotransferred onto nitrocellulose membranes

This paper describes a simple method of preparing colloidal gold for staining protein blots. Colloidal gold was prepared from 0.005 or 0.01% HAuCl4 by the addition of formalin as a reductant and potassium hydroxide. Staining of small cell carcinoma tissue extract blotted onto nitrocellulose membranes with this colloidal gold solution resulted in the appearance of a large number of clear wine-red bands. The sensitivity of gold staining was 60 times higher than that of Coomassie brilliant blue staining and almost comparable to that of silver staining of proteins in polyacrylamide gel. The sensitivity of this method was also satisfactory in comparison with that of enzyme immunoblotting. The colloidal gold prepared by this method is usable for routine work.     

Viability and acrosome staining of stallion spermatozoa by Chicago sky blue and Giemsa

A simple trypan blue-neutral red-Giemsa staining procedure for simultaneous evaluation of acrosome, sperm head, and tail membrane integrity and morphology has been used to evaluate equine spermatozoa. Some special characteristics and problems have arisen in evaluating stallion semen. One problem was the differentiation of intact vs. damaged sperm tails primarily in frozen and thawed samples. After freezing and thawing, a high percentage of spermatozoa with an unstained head and stained tail were observed. These cells are considered immotile. Therefore, unambiguous differentiation of intact vs. damaged sperm tail membrane is very important for evaluating semen quality. The aim of our study was to develop a method especially for stallion sperm to distinguish more accurately the different cell types. We compared Chicago sky blue 6B (CSB) to trypan blue (TB) for viability staining. CSB/Giemsa staining showed good repeatability and agreement with TB/Giemsa measurements. For densitometry analysis, individual digital images were taken from smears stained by CSB/Giemsa and by TB/Giemsa. A red-green-blue (RGB) histogram for each area of spermatozoa was drawn. Differences of means of RGB values of live vs. dead tails and separate live vs. dead heads from each photo were used to compare the two staining procedures. CSB produced similar live/dead sperm head differentiation and better tail differentiation. TB can be replaced by CSB and this results in more reliable evaluation. After staining with 0.16% CSB and 4 min fixation, 2–4 h Giemsa staining at 25–40° C is recommended for stallion semen.     

Viability and acrosome staining of stallion spermatozoa by Chicago sky blue and Giemsa

A simple trypan blue-neutral red-Giemsa staining procedure for simultaneous evaluation of acrosome, sperm head, and tail membrane integrity and morphology has been used to evaluate equine spermatozoa. Some special characteristics and problems have arisen in evaluating stallion semen. One problem was the differentiation of intact vs. damaged sperm tails primarily in frozen and thawed samples. After freezing and thawing, a high percentage of spermatozoa with an unstained head and stained tail were observed. These cells are considered immotile. Therefore, unambiguous differentiation of intact vs. damaged sperm tail membrane is very important for evaluating semen quality. The aim of our study was to develop a method especially for stallion sperm to distinguish more accurately the different cell types. We compared Chicago sky blue 6B (CSB) to trypan blue (TB) for viability staining. CSB/Giemsa staining showed good repeatability and agreement with TB/Giemsa measurements. For densitometry analysis, individual digital images were taken from smears stained by CSB/Giemsa and by TB/Giemsa. A red-green-blue (RGB) histogram for each area of spermatozoa was drawn. Differences of means of RGB values of live vs. dead tails and separate live vs. dead heads from each photo were used to compare the two staining procedures. CSB produced similar live/dead sperm head differentiation and better tail differentiation. TB can be replaced by CSB and this results in more reliable evaluation. After staining with 0.16% CSB and 4 min fixation, 2-4 h Giemsa staining at 25-40° C is recommended for stallion semen.     

Viability and acrosome staining of stallion spermatozoa by Chicago sky blue and Giemsa.

A simple trypan blue-neutral red-Giemsa staining procedure for simultaneous evaluation of acrosome, sperm head, and tail membrane integrity and morphology has been used to evaluate equine spermatozoa. Some special characteristics and problems have arisen in evaluating stallion semen. One problem was the differentiation of intact vs. damaged sperm tails primarily in frozen and thawed samples. After freezing and thawing, a high percentage of spermatozoa with an unstained head and stained tail were observed. These cells are considered immotile. Therefore, unambiguous differentiation of intact vs. damaged sperm tail membrane is very important for evaluating semen quality. The aim of our study was to develop a method especially for stallion sperm to distinguish more accurately the different cell types. We compared Chicago sky blue 6B (CSB) to trypan blue (TB) for viability staining. CSB/Giemsa staining showed good repeatability and agreement with TB/Giemsa measurements. For densitometry analysis, individual digital images were taken from smears stained by CSB/Giemsa and by TB/Giemsa. A red-green-blue (RGB) histogram for each area of spermatozoa was drawn. Differences of means of RGB values of live vs. dead tails and separate live vs. dead heads from each photo were used to compare the two staining procedures. CSB produced similar live/dead sperm head differentiation and better tail differentiation. TB can be replaced by CSB and this results in more reliable evaluation. After staining with 0.16% CSB and 4 min fixation, 2-4 h Giemsa staining at 25-40 degrees C is recommended for stallion semen.     

Staining methods for Calcium—a Comparison Based on Reactions Shown by Cardiac Calcinosis in DBA Mice

Spontaneous calcification, which occurs frequently in hearts of mice of the DBA strain, has been used to compare effectiveness of calcium stains. Three fixatives (1) 80% ethanol, (2) 10% formalin and 3.5% acetic acid in 95% ethanol (modified Lavdowsky's) and (3) a 1:1 mixture of concentrated formalin and absolute ethanol were tested for their subsequent effects on staining. Stains for Ca included purpurin, von Kossa's, phthalocyanin, and glyoxal bis(2-hydroxyanil). These, with appropriate counterstaining, were compared among each other, with hematoxylin-eosin (H-E), and with the periodic acid-Schiff (PAS) reaction. Fixatives (1) and (3) did not affect results appreciably, but the von Kossa technic was unsatisfactory after (2). All stain demonstrated sites of Ca deposits, but purpurin and von Kossa's gave greatest sharpness of definition and were the simplest to perform. H-E and PAS with Alcian blue showed the same Ca sites in addition to details of the surrounding tissue.     

Protocol for the combination of neurohistological techniques on vibratome obtained sections

Introduction. The histological study of the nervous system requires the use of special techniques. Currently, no methods are available to visualize simultaneously all the cellular constituents of nervous tissue. Objectives. A protocol was adapted for staining nervous tissue by modification of a formerly difficult procedure. Materials and methods. Slices of brain and spinal cord, 4 mm thick, were taken from adult mice, previously fixed by intracardiac perfusion with 4% paraformaldehyde. Vibratome sections were obtained with thickness of 15-25 μm. These were mounted on glass slides prepared with gelatin as an adhesive. The preparations were subjected to staining protocol Luxol Fast Blue-PAS-hematoxylin (LPH) combined with silver staining method (LPH-Holmes). Results. LPH technique yielded an excellent differentiation of gray and white matter in all regions of the nervous system. A panoramic view of the gray matter was colored pink in contrast to the myelinated nerve fibers and tracts which were light blue. The combination LPH-Holmes retained the staining characteristics but significantly improved the demarcation of axons and tracts. Conclusions. A protocol was standardized for the LPH and LPH-Holmes nervous tissue stains applied in combination to tissue slices obtained with a vibratome. The method was shorter, less wasteful and less expensive than the original and also better preserved the integrity of nervous tissue.