Understanding Romanowsky staining. I: The Romanowsky-Giemsa effect in blood smears

Normal blood smears were stained by the standardised azure B-eosin Y Romanowsky procedure recently introduced by the ICSH, and the classical picture resulted. The effects of varying the times and temperature of staining, the composition of the solvent (buffer concentration, methanol content, & pH), the concentration of the dyes, and the mode of fixation were studied. The results are best understood in terms of the following staining mechanism. Initial colouration involves simple acid and basic dyeing. Eosin yields red erythrocytes and eosinophil granules. Azure B very rapidly gives rise to blue stained chromatin, neutrophil specific granules, platelets and ribosome-rich cytoplasms; also to violet basophil granules. Subsequently the azure B in certain structures combines with eosin to give purple azure B-eosin complexes, leaving other structures with their initial colours. The selectivity of complex formation is controlled by rate of entry of eosin into azure B stained structures. Only faster staining structures (i.e. chromatin, neutrophil specific granules, and platelets) permit formation of the purple complex in the standard method. This staining mechanism illuminates scientific problems (e.g. the nature of 'toxic' granules) and assists technical trouble-shooting (e.g. why nuclei sometimes stain blue, not purple).     

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.     

Understanding Romanowsky staining

Summary Normal blood smears were stained by the standardised azure B-eosin Y Romanowsky procedure recently introduced by the ICSH, and the classical picture resulted. The effects of varying the times and temperature of staining, the composition of the solvent (buffer concentration, methanol content, & pH), the concentration of the dyes, and the mode of fixation were studied. The results are best understood in terms of the following staining mechanism. Initial colouration involves simple acid and basic dyeing. Eosin yields red erythrocytes and eosinophil granules. Azure B very rapidly gives rise to blue stained chromatin, neutrophil specific granules, platelets and ribosome-rich cytoplasms; also to violet basophil granules. Subsequently the azure B in certain structures combines with eosin to give purple azure B-eosin complexes, leaving other structures with their initial colours. The selectivity of complex formation is controlled by rate of entry of eosin into azure B stained structures. Only faster staining structures (i.e. chromatin, neutrophil specific granules, and platelets) permit formation of the purple complex in the standard method. This staining mechanism illuminates scientific problems (e.g. the nature of toxic granules) and assists technical trouble-shooting (e.g. why nuclei sometimes stain blue, not purple).To whom offprint should be sent     

Buffered Romanowsky-Giemsa method for formalin fixed,paraffin embedded sections: taming a traditional stain

Romanowsky-Giemsa (RG) stains were devised during the 19th century for identifying plasmodia parasites in blood smears. Later, RG stains became standard procedures for hematology and cytology. Numerous attempts have been made to apply RG staining to formalin-fixed paraffin-embedded tissue sections, with varied success. Most published work on this topic described RG staining methods in which sections were overstained, then subjected to acid differentiation; unfortunately, the differentiation step often caused inconsistent staining outcomes. If staining is performed under optimal conditions with control of dye concentration, pH, solution temperature and staining time, no differentiation is required. We used RG and 0.002 M buffer, pH 42, for staining and washing sections. All steps were performed at room temperature. After staining and air drying, sections were washed in 96?100% ethanol to remove extraneous stain. Finally, sections were washed in xylene and mounted using DPX. Staining results were similar to routine hemalum and eosin (H &; E) staining. Nuclei were blue; intensity depended largely on chromatin density. RNA-rich sites were purple. Collagen fibers, keratin, muscle cells, erythrocytes and white matter of the central nervous system were stained pinkish and reddish hues. Cartilage matrix, mast cell granules and areas of myxomatous degeneration were purple. Sulfate-rich mucins were stained pale blue, while those lacking sulfate groups were unstained. Deposits of hemosiderin, lipofuscin and melanin were greenish, and calcium deposits were blue. Helicobacter pylori bacteria were violet to purple. The advantages of the method are its close similarity to H &; E staining and technical simplicity. Hemosiderin, H. pylori, mast cell granules, melanin and specific granules of different hematopoietic cells, which are invisible or barely distinguishable by H &; E staining, are visualized. Other advantages over previous RG stains include shorter staining time and avoidance of acetone.     

Romanowsky dyes and the Romanowsky-Giemsa effect. 3. Microspectrophotometric studies of Romanowsky-Giemsa staining. Spectroscopic evidence of a DNA-azure B-eosin Y complex producing the Romanowsky-Giemsa effect

The Romanowsky-Giemsa staining (RG staining) has been studied by means of microspectrophotometry using various staining conditions. As cell material we employed in our model experiments mouse fibroblasts, LM cells. They show a distinct Romanowsky-Giemsa staining pattern. The RG staining was performed with the chemical pure dye stuffs azure B and eosin Y. In addition we stained the cells separately with azure B or eosin Y. Staining parameters were pH value, dye concentration, staining time etc. Besides normal LM cells we also studied cells after RNA or DNA digestion. The spectra of the various cell species were measured with a self constructed microspectrophotometer by photon counting technique. The optical ray pass and the diagramm of electronics are briefly discussed. The nucleus of RG stained LM cells, pH congruent to 7, is purple, the cytoplasm blue. After DNA or RNA digestion the purple respectively blue coloration in the nucleus or the cytoplasm completely disappeares. Therefore DNA and RNA are the preferentially stained biological substrates. In the spectrum of RG stained nuclei, pH congruent to 7, three absorption bands are distinguishable: They are A1 (15400 cm-1, 649 nm), A2 (16800 cm-1, 595 nm) the absorption bands of DNA-bound monomers and dimers of azure B and RB (18100 cm-1, 552 nm) the distinct intense Romanowsky band. Our extensive experimental material shows clearly that RB is produced by a complex of DNA, higher polymers of azure B (degree of association p greater than 2) and eosin Y. The complex is primarily held together by electrostatic interaction: inding of polymer azure B cations to the polyanion DNA generates positively charged binding sites in the DNA-azure B complex which are subsequently occupied by eosin Y anions. It can be spectroscopically shown that the electronic states of the azure B polymers and the attached eosin Y interact. By this interaction the absorption of eosin Y is red shifted and of the azure B polymers blue shifted. The absorption bands of both molecular species overlap and generate the Romanowsky band. Its strong maximum at 18100 cm-1 is due to the eosin Y part of the DNA-azure B-eosin Y complex. The discussed red shift of the eosin Y absorption is the main reason for the purple coloration of RG stained nuclei. Using a special technique it was possible to prepare an artificial DNA-azure B-eosin Y complex with calf thymus DNA as a model nucleic acid and the two dye stuffs azure B and eosin Y.(ABSTRACT TRUNCATED AT 400 WORDS)     

Spectrophotometric and cytochemical studies on azures A, B and C.

The cytochemical use of azures A, B and C, propared with either N HCL and potassium metabisulphite or with sodium hydrosulphite in tissue sections were investigated. Both in situ absorption curves of nuclei stained with each of these dye-SO2 reagents as well as in vitro absorption data of acqueous solutions of the dyes are also presented. It has been pointed out that the mechanism of staining with azure A-SO2 and azure C Eosinate-SO2 is the same as that of the conventional Feulgen reaction with Schiff reagent but that of staining with azure B-SO2 is by the modified Feulgen reaction because this dye does not contain any primary amino group.     

How Romanowsky stains work and why they remain valuable — including a proposed universal Romanowsky staining mechanism and a rational troubleshooting scheme

Abstract

An introduction to the nomenclature and concept of “Romanowsky stains” is followed by a brief account of the dyes involved and especially the crucial role of azure B and of the impurity of most commercial dye lots. Technical features of standardized and traditional Romanowsky stains are outlined, e.g., number and ratio of the acidic and basic dyes used, solvent effects, staining times, and fixation effects. The peculiar advantages of Romanowsky staining are noted, namely, the polychromasia achieved in a technically simple manner with the potential for stain intensification of “the color purple.” Accounts are provided of a variety of physicochemically relevant topics, namely, acidic and basic dyeing, peculiarities of acidic and basic dye mixtures, consequences of differential staining rates of different cell and tissue components and of different dyes, the chemical significance of “the color purple,” the substrate selectivity for purple color formation and its intensification in situ due to a template effect, effects of resin embedding and prior fixation. Based on these physicochemical phenomena, mechanisms for the various Romanowsky staining applications are outlined including for blood, marrow and cytological smears; G-bands of chromosomes; microorganisms and other single-cell entities; and paraffin and resin tissue sections. The common factors involved in these specific mechanisms are pulled together to generate a “universal” generic mechanism for these stains. Certain generic problems of Romanowsky stains are discussed including the instability of solutions of acidic dye–basic dye mixtures, the inherent heterogeneity of polychrome methylene blue, and the resulting problems of standardization. Finally, a rational trouble-shooting scheme is appended.     

Investigation of Thiazin Dyes as Biological Stains I. The Staining Properties of Thionin and its Derivatives as Compared with Their Chemical Formulae

An investigation has been made of the staining properties of eight dyes of the thionin group. The dyes studied are as follows: tetra-ethyl thionin, asymmetrical di-ethyl thionin, tetra-methyl thionin (methylene blue), tri-methyl thionin (azure B), asymmetrical di-methyl thionin (azure A), symmetrical di-methyl thionin, mono-methyl thionin (azure C), and unsubstituted thionin. The staining properties were tested on sections of paraffin embedded material following five different methods of fixation. No counterstain was employed. It was shown that there was a general correlation between the extent of ethylation or methylation of the dyes and their staining properties. As one passes from tetra-ethyl thionin down the series to thionin itself, there is a progressive decrease in the amount of green showing in the preparations, and an increase in the amount of red present, also an increase in the metachromatic effects, and in the intensity of nuclear staining. There seems, also, to be a similar relation between staining qualities on the one hand and the color and solubility of the dye base on the other.     

Investigation of Thiazin Dyes as Biological Stains I. The Staining Properties of Thionin and its Derivatives as Compared with Their Chemical Formulae

An investigation has been made of the staining properties of eight dyes of the thionin group. The dyes studied are as follows: tetra-ethyl thionin, asymmetrical di-ethyl thionin, tetra-methyl thionin (methylene blue), tri-methyl thionin (azure B), asymmetrical di-methyl thionin (azure A), symmetrical di-methyl thionin, mono-methyl thionin (azure C), and unsubstituted thionin. The staining properties were tested on sections of paraffin embedded material following five different methods of fixation. No counterstain was employed. It was shown that there was a general correlation between the extent of ethylation or methylation of the dyes and their staining properties. As one passes from tetra-ethyl thionin down the series to thionin itself, there is a progressive decrease in the amount of green showing in the preparations, and an increase in the amount of red present, also an increase in the metachromatic effects, and in the intensity of nuclear staining. There seems, also, to be a similar relation between staining qualities on the one hand and the color and solubility of the dye base on the other.     

Thermodynamics of Orcein staining of elastic fibres

Synopsis Elastic fibres in histological sections have only a slightly higher affinity (than chromatin or cartilage matrix) for unpurified Orcein in acidified 70% ethanol, but the staining of elastic fibres is more exothermic (the heat of staining being in good agreement with publishedin vitro measurements), has a considerably higher activation energy, and is probably accompanied by a greater decrease in entropy. Experiments with purified dye fractions, and unpurified dye in 10% ethanol, were inconclusive, as it was not possible to prove unequivocally that equilibrium between dyebath and substrate had been achieved under these conditions.The results are consistent with the selectivity of orcein for elastic fibres under practical conditions being due to (a) the presence in elastic fibres of a relatively large number of dye-binding sites per unit volume, which probably bind by some non-ionic mechanism, (b) the relatively non-polar nature of elastic fibres, which repel cationic dye particles less than do tissue components that at low pH carry a positive charge, and (c) the low permeability of elastic fibres, so that dyeing, once achieved, is relatively resistant to alcoholic extraction. An alcoholic solvent for the dye enables strong solutions, and hence short staining times, to be used.     

Electron microscopic demonstration of pulmonary surfactant proteins using procion brilliant blue H5GS

A new electron microscopy technique is described for detection of lung surfactant proteins with the copper-containing phthalocyanine dye, procion brilliant blue H5GS. The protein structures were stained concurrently with the fixation during perfusion through the pulmonary artery of a fixative-staining mixture containing glutaric aldehyde and a dye in the kakodilate buffer, pH 5.6-6, and in the course of a subsequent immersion of lung tissue pieces into the same mixture. Then the material was treated with thiosemicarbazide and post-fixed with OsO4. The dye did not penetrate intact cells. The electron-dense products of the histochemical reaction were located inside and on the surface of the surfactant membrane, in the hypophase of the surfactant complex, on the plasmalemma of air-blood barrier cells and in its micropinocytosis vesicles, as well as on the membranes of osmophilic plate-like bodies as their contents egressed into the alveolar lumen.     

Localization of methylene blue paramolybdate in vitally stained nerves

Methylene blue taken up by living neurons can be preserved for electron microscopy in a fixative containing osmium tetroxide and ammonium paramolybdate at pH 5.2. Paramolybdate is the buffer, precipitating agent and main osmotic ingredient; it does not function as an electron stain unless methylene blue is present. The low pH keeps the dye/paramolybdate complex from dissolving. Neither the low pH nor drastic dehydration from water to absolute ethanol harm the tissue. The staining mechanism involves cationic methylene blue associating with anionic structures such as microtubules and neurofilaments in the living cell; during fixation paramolybdate forms a precipitate with the dye at the staining sites. This fixative does not preserve microtubules unless they are first vitally stained.     

A simple metachromatic and fluorescent staining method for microorganisms using carbocyanine dye

The cationic carbocyanine dye, 1-ethyl-2-[3-(1-ethylnaphtho[1, 2d]-thiazolin-2-ylidene)-2-methylpropenyl]-naphtho[1, 2d]thiazolium bromide, interacts with several classes of anionic polymers, exhibiting metachromasia. We were able to stain various kinds of microorganisms with this dye. Gram-negative bacteria were stained reddish purple, while Gram-positive bacteria were stained violet or bluish purple. Stains of molds were of various colors. Yeast vegetative cells were stained reddish purple, but zygotic asci were bluish. Chlamydia trachomatis inclusions, which are surrounded by cytoplasmic membranes, were also stained red. Microorganism and cell stains have different features and can be identified also by use of fluorescent microscopy. The new staining method we report here is rapid and simple enough for routine microscopical examinations of smears of clinical specimens including microorganisms.     

Ethidium bromide: a nucleic acid stain for tissue section

The phenanthridinium dye, ethidium bromide (EB), selectively intercalates into double-stranded regions of nucleic acids with a large and specific increase in fluorescence. When used for the staining of fixed tissue sections, the dye stains cellular nuclei with excellent resolution of microscopic detail. In some fixed tissues, particularly pancreatic acini, cytoplasm stains intensely and this staining can be abolished by digestion with trypsin and ribonuclease. The orange fluorescence of EB can be easily distinguished from the green fluorescence of fluorescein and EB is thus an excellent counterstain for immunofluorescence. Ethidium bromide is a useful and practical stain for the fluorescence microscopy of tissue sections and, in combination with enzymatic digestion of RNA, provides a simple way to differentially localize DNA and RNA.     

Bacterial decolorization of acid orange 7 in the presence of ionic and non-ionic surfactants

The effects of the non-ionic surfactant Triton X-100, the cationic surfactant cetyltri-methylammonium bromide (CTAB) and the anionic surfactant sodium N-lauroyl sarcosinate (SLS) on the decolorization of the reaction medium containing the monoazo dye Acid Orange 7 (AO7) by Alcaligenes faecalis and Rhodococcus erythropolis were studied. It was found that the surfactants influenced in different ways the rate of decolorization. At all concentrations tested the non-ionic surfactant Triton X-100 decreased the decolorization rate of R. erythropolis. At concentrations above the critical micelle concentration (CMC) Triton X-100 upset the usually observed exponential decay of the dye with A. faecalis due probably to the existence of an outer membrane in this organism. In concentrations above the CMC the anionic surfactant SLS inhibited the decolorization and, at prolonged incubation, caused partial release of the bound dye. The cationic surfactant CTAB in concentrations above and below the CMC accelerated drastically the binding of AO7 to the cells causing a rapid staining of the biomass and complete decolorization of the reaction medium. An attempt was made for explanation of the observed differences by the negative electrostatic charge of the living bacterial cell.     

Affinity extraction of BSA with reversed micellar system composed of unbound Cibacron Blue

Affinity Cibacron Blue 3GA (CB) dye in aqueous phase was directly transferred to the reversed micelles due to electrostatic interaction between anionic CB and cationic cetyltrimethylammonium bromide (CTAB). The bovine serum albumin (BSA) transfer to the reverse micelles increases significantly in a wide range of pH by the addition of a small amount of CB ( approximately 1.0-7.0% of the total surfactant concentration) to the aqueous phase. For pH < pI, the selectivity can be significantly improved with the presence of affinity CB because no BSA was extracted in the absence of CB. For backward extraction of BSA from the micellar phase with stripping aqueous solution, the addition of 2-propanol to the aqueous phase can recover almost all BSA (98.5%) extracted into the reverse micelles.     

Cytochemical studies demonstrating the effect of monosodium glutamate on RNA concentration in neurons in mice

The effect of monosodium glutamate (MSG) on the concentration of ribonucleic acid (RNA) in the neurons of mice was studied, using the specific cytochemical stain, azure B bromide. The RNA-rich sites such as the nucleolus and the Nissl substances of large neurons showed a marked decrease in the concentration of RNA in the MSG-treated as compared to the control animals. Since RNA is believed to be the principal macromolecule involved in the learning and behavioral processes, previous reports have attributed learning and behavioral dysfunctions in MSG-treated animals to a significant decrease of the RNA concentration in these animals.     

Study of the Formation and Solution Properties of Worm-Like Micelles Formed Using Both N-Hexadecyl-N-Methylpiperidinium Bromide-Based Cationic Surfactant and Anionic Surfactant

The viscoelastic properties of worm-like micelles formed by mixing the cationic surfactant N-hexadecyl-N-methylpiperidinium bromide (C₁₆MDB) with the anionic surfactant sodium laurate (SL) in aqueous solutions were investigated using rheological measurements. The effects of sodium laurate and temperature on the worm-like micelles and the mechanism of the observed shear thinning phenomenon and pseudoplastic behavior were systematically investigated. Additionally, cryogenic transmission electron microscopy images further ascertained existence of entangled worm-like micelles.     

The Azure Dyes their Purification and Physicochemical properties. II. Purification of Azure B

A method is described for the purification of the dye azure B in quantities sufficient for biological staining experiments on a larger scale. The method is based on the use of column chromatography. Two columns are employed. In column A with silica gel as adsorbent the azure B fraction is isolated from a suitable substrate ('technical' azure B gained by a modification of Bernthsen's synthesis of methylene blue, or plychrome methylene blue) using an acetate-formate mixture as eluent. In column B, on an Amberlite polyineric adsorbent (XAD-2) the acetate-formate anions are exchanged for chloride. Regeneration of both columns is possible: KMnO₄, Na₂S₂O₄ and water are run through column A, 5% NaOH, methanol and water through column B. Purification of azure B on economic terms is thus attained. The opinion is expressed that this method is also applicable to the purification of other cationic dyes.     

The azure dyes: their purification and physicochemical properties. II. Purification of azure B.

A method is described for the purification of the dye azure B in quantities sufficient for biological staining experiments on a larger scale. The method is based on the use of column chromatography. Two columns are employed. In column A with silica gel as adsorbent the azure B fraction is isolated from a suitable substrate ('technical' azure B gained by a modification of Bernthsen's synthesis of methylene blue, or polychrome methylene blue) using an acetate-formate mixture as eluent. In column B, on an Amberlite polymeric adsorbent (XAD-2) the acetate-formate anions are exchanged in chloride. Regeneration of both columns is possible: KMnO4, Na2S2O4 and water are run through column A; 5% NaOH, methanol and water through column B. Purification of azure B on economic terms is thus attained. The opinion is expressed that this method is also applicable to the purification of other cationic dyes.