Which granules can be stained with azure B and eosin?

The standardized stain composed of pure azure B and eosin, as published by Wittekind and colleagues in 1986, demonstrated granules in neutrophilic leucocytes that were much coarser than those seen after staining with conventional Romanowsky-Giemsa methods. These granules belong to at least two classes. Their identification cannot be achieved by means of the morphologic characteristics of single granules; a multivariate analysis of the granulation as a whole, and a comparison with specifically stained primary granules is required. In particular, this study on unbiased cell samples showed that with Wittekind's method, the primary granules in peripheral neutrophils are stained. Further study of clinical smears revealed an enhanced dye uptake by the secondary granules. The staining behavior of the granules is related to the leukocyte count.     

Nuclear Staining of Colletotrichum Gloeosporioides F. SP. Malvae Conidia with Fluorescent and Nonfluorescent Stains

Six different staining techniques were evaluated for their suitability to stain nuclei of Colletotrichum gloeosporioides f. sp. malvae (C.g.m.) spores. Of the three fluorescent stains, DAPI (4',6-diamidino-2-phenylindole) and bisbenzimide (Hoechst 33258) stained spore nuclei well; mithramycin did not. To achieve consistent results with the bisbenzimide staining protocol, the spores had to be fixed prior to staining and the stain had to be supplemented with Triton X-100. Both safranin O and Giemsa were suitable nonfluorescent staining techniques; lomofungin was not. Safranin O staining was simple and rapid. However, reproducibility was better if the spore suspension and KOH droplets were rapidly mixed prior to adding the stain. There was no significant difference in the percentages of uninucleate and binucleate spores observed in spore preparations stained with DAPI, bisbenzimide, safranin O or Giemsa. Bisbenzimide and safranin O were found to be simple, rapid and reliable fluorescent and nonfluorescent techniques, respectively, for staining nuclei of C.g.m. spores.     

A Rapid Method for In Situ Staining of Prostatic and other Tissue Culture Cells

A rapid method for staining prostatic epithelium grown in vitro and other tissue culture cells is described. Giemsa stain and a phosphate buffer with a pH of 6.8 were used. Excellent nuclearcytoplasmic contrast is obtained with this procedure. It is recommended for studies on the general morphology of normal and abnormal cells in tissue culture.     

The Oxidation Products of Methylene Blue

The mechanism of the oxidation of methylene blue varies with the conditions. The formation of trimethyl thionin (azure B) and of asymmetrical dimethyl thionolin (azure A) is followed under alkaline conditions by that of dimethyl thionin (methylene violet) and under acid conditions by that of monomethyl thionin (named by authors azure C).

Simple and practical methods are given for the preparation of azure A and azure C. The latter product, which has not been obtained from methylene blue hitherto, has valuable staining properties as a nuclear and bacterial stain in tissue and may also be employed satisfactorily as a substitute for azure A in the MacNeal tetrachrome formula as a blood stain or substitute for the Giemsa stain.

Azure B has no particular merit in staining.

Azure C proves to be a very valuable stain. A procedure is given for its use with eosin Y and orange II as counterstains, by which it is possible to demonstrate bacteria in tissue and at the same time the cytological elements of the tissue.     

The role of chromosomal proteins in the C-banding of Allium cepa chromosomes.

When chromosomes of Allium cepa are subjected to a C-banding procedure (incubation in saturated barium hydroxide followed by phosphate buffer at 60 degrees C for 1 h) and then treated with Giemsa stain, bands appear at the telomeres of all chromosomes. Microspectrophotometric measurements of Feulgen-DNA content, demonstrated that the C-banding procedure extracted DNA from the nuclei. Staining of banded chromosomes with several DNA-specific stains showed that this loss was differential, with the band DNA exhibiting more resistance to extraction than that of the rest of the chromosome. The C-banding procedure did not extract chromosomal proteins, however, and no difference in mass per unit length could be detected by Nomarski optics between band and interband regions. Several experiments demonstrated that chromosomal proteins play a significant role in C-banding. First, treatment of chromosomes with pronase before C-banding resulted in the elimination of differential staining with Giemsa. Furthermore, in preparations where the DNA was completely hydrolysed with hot TCA, the remaining chromosomal proteins were found to exhibit a differential affinity for Giemsa stain. Amido black staining demonstrated that total chromosomal protein was uniformly distributed after the hot TCA digestion, but the proteins localized in the telomeres had a greater affinity for the Giemsa stain than the bulk of the chromosomal proteins. When the TCA-digested chromosomes were subjected to the C-banding procedure before staining, the differential affinity of the telomeres for the Giemsa stain was lost. Thus, C-banding appears to be the result of a complex interaction between protein and DNA in which the greater resistance to extraction of the band DNA is necessary to stabilize and preserve chromatin protein which exhibits a differential affinity for Giemsa stain.     

Staining the Nucleus in Yeasts

Yeast cells kept young by repeated subculturing were centrifuged, washed twice in distilled water and smeared on slides coated with a little egg albumen. The cells were treated with 0.002 M 8-hydroxyquinoline for 1 hr, fixed first in OsO, vapour for 30 sec and then in chloroform for 30 sec. The slides were passed through descending grades of alcohol, washed in distilled water, then immersed in 0.17 M NaCl solution for 2 hr. at 57°C. They were again washed in distilled water and later hydrolysed in 1 N HCl at 60°C for 5-7 min. This was followed by washing in distilled water and in buffer. The slides were then kept for 3 hr in Giemsa stain comprising 96 ml of phosphate buffer of pH 7.0 and 4 ml of the stain. After dehydration, mounting was done in balsam. Nuclei were brightly stained and well differentiated; centrosomes were clear, and the process of nuclear division and movement to daughter cells could be studied. Pretreatment with 8-hydroxyquinoline increased the viscosity of the cytoplasm, while NaCl treatment and acid hydrolysis led to the complete removal of ribonucleic acid and basophilic material. A selective staining of chromatin was thus achieved. Structures resembling chromosomes could be seen when fixed and stained cells were squashed, soon after the removal of the slides from the stain, under a cover glass by applying uniform pressure with a rubber stopper. Fixation in osmic acid vapor and chloroform followed by acid hydrolysis and staining in leucobasic fuchsin also helps to obtain bright staining of the nucleus; however, the preparations are inferior to those obtained after 8-hydroxyquinoline, NaCl treatment and Giemsa staining.     

Staining procedure to detect viability and the true acrosome reaction in spermatozoa of various species

A simple dual stain procedure (DS) for simultaneously determining sperm viability and acrosomal status is described. The DS includes the use of the vital stain trypan blue to detect live and dead spermatozoa and Giemsa to detect the presence or absence of an acrosome. For staining, spermatozoa are washed, incubated with trypan blue, washed, dried onto slides, and subjected to Giemsa. Dead spermatozoa stain blue in the postacrosomal region while live spermatozoa remain unstained. The acrosome stains light purple–dark pink while acrosome-free sperm remain unstained. This staining pattern enables differentiation of spermatozoa which have undergone a true acrosome reaction (TAR) from those which have undergone a false acrosome reaction (FAR). Incubation of bull, boar, ram, and stallion spermatozoa for 60 minutes at 37°C in the presence of calcium ionophore A23187 increased the proportion of spermatozoa undergoing a TAR in all species except the stallion. Incubation of bull spermatozoa for up to 24 hours at 37°C resulted in a decrease over time in the percentage of live acrosome-intact spermatozoa and a simultaneous increase in the percentage of spermatozoa categorized as having undergone a TAR and FAR. The DS could be a useful technique in evaluating sperm viability and acrosomal status in fertilization and clinical studies.     

Plastic Sectioning for Light Microscopy of Pyrenomycetes

In preparation for light microscopy, ascocarps of Sordaria fimicola Ces. & DeNot. were embedded in Spurr's medium and sectioned at 1-1.5 μm on an ultramicrotome. Sections were floated on Giemsa staining solution at 60 C for 10-30 min, washed in distilled water, affixed to slides by drying, and mounted in immersion oil. Best preservation of the delicate sterile tissues of the centrum was obtained by fixation in 1% KMnO₄ for 2.5-3 hr, followed by the Giemsa stain. This method is suggested for future studies on the morphology of perithecial ascomycetes.     

Giemsa G-Banding in Allium

Using divergent Giemsa staining protocols designed for other plant species, G-banding was visualized in the chromosomes of Allium cepa L., A. fistulosum L., and their interspecific (A. fistulosum × A. cepa) hybrid. This is the first demonstration of G-banding of Allium chromosomes. Differences and similarities with other Giemsa banding patterns in Allium are discussed.     

Peroxidase Staining Combined with Autoradiography for Study of Eosinophilic Granules

Giemsa staining and a peroxidase reaction were applied to blood films in conjunction with autoradiography to establish the types of granulocytes that stain differentially with the benzidine-peroxidase reaction. Differential counts made on Ciemsa-stained and peroxidase-stained autoradiograms were compared. In T. spiralis-infected rats with an elevated eosinophil count, as judged by Giemsa staining, the percentage of granulocytes that stained more intensely with peroxidase was increased. The results suggested that the eosinophils were the intensely peroxidase-positive cells. Blood smears were stained for peroxidase before being coated with NTB₂ liquid emulsion. Although the blue color of the peroxidase reaction faded during photographic development, the color redeveloped when peroxidase-stained autoradiograms were stained once again after photographic development. It was found necessary to stain for peroxidase both before and after autoradiography. The correlation of Giemsa-stained and peroxidase-stained autoradiograms indicated that the peroxidase stain can be combined with autoradiography to obtain authentic results.     

A Simple Method for Histochemical Demonstration of Viral Inclusion Bodies in Cell Monolayers in Microtitration Plates

The present paper describes a Bouin's-formalin fixation and Giemsa staining procedure for demonstrating viral cytoplasmic inclusion bodies in cellular monolayers in microtitration plates. Monolayers are fixed in Bouin's fixative for 15 min followed by 10% neutral buffered formalin fixation overnight. After fixation, the monolayers are stained with 4% (v/v) Giemsa stain. The method is superior to the separate use of formalin, methanol or Bouin's fixation-staining methods and compares favorably to immunocytochemical techniques for sensitivity.     

A simple method for histochemical demonstration of viral inclusion bodies in cell monolayers in microtitration plates

The present paper describes a Bouin's-formalin fixation and Giemsa staining procedure for demonstrating viral cytoplasmic inclusion bodies in cellular monolayers in microtitration plates. Monolayers are fixed in Bouin's fixative for 15 min followed by 10% neutral buffered formalin fixation overnight. After fixation, the monolayers are stained with 4% (v/v) Giemsa stain. The method is superior to the separate use of formalin, methanol or Bouin's fixation-staining methods and compares favorably to immunocytochemical techniques for sensitivity.     

Understanding microwave-stimulated Romanowsky-Giemsa staining of plastic embedded bone marrow

Summary Bone marrow smears were made and fixed in methanol or formaldehyde. Marrow sections of various thicknesses were also prepared from formaldehyde fixed marrows embedded in paraffin or plastic (glycol methacrylate). The different smears and sections were then stained by a Romanowsky-Giemsa procedure. Some specimens were stained using a standard microwave-stimulated method previously used diagnostically. The effects of technical variations were studied, including degree of microwave irradiation and the staining time. Comparisons of the resulting staining outcomes showed that microwave stimulated Romanowsky-Giemsa staining of plastic sections is a rate controlled process. Unusual aspects of the staining pattern of plastic sections (namely the purple basophilic cytoplasms and nucleoli, and blue chromatin) are due to microwave stimulation and formaldehyde fixation respectively.     

Reciprocal Giemsa staining of late DNA replicating regions produced by low and high pH sodium phosphate

A procedure is described whereby late replicating, BUdR-substituted chromosome regions stain intensely with Giemsa, thus producing the reciprocal staining patterns compared to those obtained by all other BUdR-Giemsa procedures where BUdR-substituted regions appear pale staining. This method may be more convenient than pre-existing techniques for demonstrating late replicating chromosome regions, and may provide a higher degree of resolution of the late replicating regions. The finding that BUdR-substituted regions can be made to stain either intensely or palely with Giemsa, depending on the pH of the pretreatment NaH₂PO₄ solution, may have important implications concerning the mechanism of BUdR-induced chromosome differentiation.     

Azure B-Eosin APAAP Staining: a Method for Simultaneous Hematological and Immunological Cell Analysis

Azure B-eosin APAAP staining allows simultaneous analysis of peripheral blood and bone marrow cells for hematological characteristics and immunological cell marker profiles. A defined sequence of staining procedures maintains characteristic components of the Romanowsky-Giemsa stain whereas cell antigens can be detected immunologically using the alkaline phosphatase-anti-alkaline phosphatase (APAAP) detection system. Antigens are visualized by the staining product of the substrate-naphthol AS GR phosphate and variamine blue salt. The usefulness of the azure B-eosin APAAP method was demonstrated on blood and bone marrow smears of patients with various hematological disorders.     

The Demonstration of Beryllium Oxide in Paraffin Sections with Chromoxane Stains

Aqueous solutions of the arylmethane dyes Chromoxane pure blue BLD (C.I. No. 43825) and Chromoxane pure blue B (C.I. No. 43830) will stain beryllium oxide. In the presence of EDTA the staining of other metals is masked. As a specific stain for BeO, formol saline fixed paraffin sections are hydrated and stained for 1 hr with either 0.1 gm of pure blue BLD in 100 ml of pH 4.0 Na-acetate buffer or with 0.1 gm of pure blue B in 1 N NaOH adjusted to pH 9.0 with HCl. To mask interference from other metal ions, 9 gm of Na₂-EDTA is added to 100 ml of the stain solution. BeO is stained blue, organic tissue components are either unstained or pink. Results of tests against other materials show that a high degree of specificity may be expected from these dyes. A 1% aqueous solution of neutral red may be used as a counterstain.     

The Standard Romanowsky-Giemsa Stain in Histology

A new and technically simple Romanowsky-Giemsa (RG) stain is proposed as a standardized technique for use in histology. An RG stock solution (pure azure B 7.5 g/l, eosin Y as eosinic acid 1.2 g/l in dimethylsulfoxide) is diluted to form the working solution with HBPES-buffer, pH 6. Staining time is 30-90 min after formolcalcium solution (or 2-4 hr after formaldehyde-organic acid mixtures). The resulting overstained sections are to be differentiated. A tannic acid-acetic acid combination in an isopropanol-water mixture was found to give optimum results within 100 sec. Subsequent dehydration is in isopropanol only. The staining pattern obtained is polychrome. The distribution of colors in detail is influenced by the modes of pre- and posttreatment. Of practical interest is the development of green and greenish blue colors on collagen fibrils which contrast strongly against the pink of sarcoplasm. For this and other reasons, this RG stain version seems suitable to replace the trichrome Gomori-type trichrome stains under appropriate processing conditions.     

The Standard Romanowsky-Giemsa Stain in Histology

A new and technically simple Romanowsky-Giemsa (RG) stain is proposed as a standardized technique for use in histology. An RG stock solution (pure azure B 7.5 g/l, eosin Y as eosinic acid 1.2 g/l in dimethylsulfoxide) is diluted to form the working solution with HBPES-buffer, pH 6. Staining time is 30-90 min after formolcalcium solution (or 2-4 hr after formaldehyde-organic acid mixtures). The resulting overstained sections are to be differentiated. A tannic acid-acetic acid combination in an isopropanol-water mixture was found to give optimum results within 100 sec. Subsequent dehydration is in isopropanol only. The staining pattern obtained is polychrome. The distribution of colors in detail is influenced by the modes of pre- and posttreatment. Of practical interest is the development of green and greenish blue colors on collagen fibrils which contrast strongly against the pink of sarcoplasm. For this and other reasons, this RG stain version seems suitable to replace the trichrome Gomori-type trichrome stains under appropriate processing conditions.     

Staining Chromosomes in Sections of Germinal Vesicles of Sarcoptid Mites by a Schiff Reagent

Chromosomes of oocytes, especially early prophase I stages, of Acaridae and Anoetidae species are difficult to stain by procedures using hematoxylin, Feulgen and aceto-orcein. Hematoxylin stains are intensely polychromatic in oocytes; the standard Feulgen procedure is negative with chromosomes during diffuse prophase stages. Satisfactory staining can be obtained with a supersensitive Schiff reagent (Tobie, W. C., Ind. Eng. Chem., Anal. Ed., 14: 405—406, 1942) made by reducing basic fuchsin with gaseous SO₂. Routinely prepared paraffin sections of mites fixed in Carnoy's 6:3:1 mixture were hydrolysed 5-8 min in 1 N HCl, washed well, and stained in this reagent: 1-2 hr for prophase oocytes, 10-20 min for condensed chromosomes. A second staining in a 0.5% aqueous solution of toluidine blue 0, adjusted to pH 5.3-5.5 with a citrate buffer, served to darken the original Feulgen stain. Counterstaining with 0.1-0.2% fast green FCF in the last fluid of the dehydrating series enhanced contrast between chromosomes and cytoplasm. This staining technic is also suitable for preparing whole mounts of mites.