On the nature of Romanowsky--Giemsa staining and its significance for cytochemistry and histochemistry: an overall view

Quirks of dye nomenclature. 8. Methylene blue, azure and violet

Methylene blue was synthesized in 1877 and soon found application in medicine, staining for microscopy and as an industrial dye and pigment. An enormous literature has accumulated since its introduction. Early on, it was known that methylene blue could be degraded easily by demethylation; consequently, the purity of commercial samples often was low. Therefore, demethylation products, such as azures and methylene violet, also are considered here. The names and identity of the components, their varying modes of manufacture, analytical methods and their contribution to biological staining are discussed.

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.

Apoptotic death in erythrocytes of lamprey Lampetra fluviatilis induced by ionomycin and tert-butyl hydroperoxide

The work examined the effects of Ca²⁺ overload and oxidative damage on erythrocytes of river lamprey Lampetra fluvialtilis. The cells were incubated for 3h with 0.1-5μM Ca²⁺ ionophore ionomycin in combination with 2.5mM Ca²⁺ and 10-100μM pro-oxidant agent tert-butyl hydroperoxide (tBHP). The sensitivity of lamprey RBCs to studied compounds was evaluated by the kinetics of their death. Both toxicants induced dose- and time dependent phosphatidylserine (PS) externalization (annexin V-FITC labeling) and loss of membrane integrity (propidium iodide uptake). Highest doses of ionomycin (1-2μM) increased the number of PS-exposed erythrocytes to 7-9% within 3h, while 100μM tBHP produced up to 50% of annexin V-FITC-positive cells. Caspase inhibitor Boc-D-FMK (50μM), calpain inhibitor PD150606 (10μM) and broad protease inhibitor leupeptin (200μM) did not prevent ionomycin-induced PS externalization, whereas tBHP-triggered apoptosis was blunted by Boc-D-FMK. tBHP-dependent death of lamprey erythrocytes was accompanied by the decrease in relative cell size, loss of cell viability, activation of caspases 9 and 3/7, and loss of mitochondrial membrane potential, but all these processes were partially attenuated by Boc-D-FMK. None of examined death-associated events were observed in ionomycin-treated erythrocytes except activation of caspase-9. Incubation with ionomycin did not alter intracellular K⁺ and Na⁺ content, while exposure to tBHP resulted in 80% loss of K⁺ and 2.8-fold accumulation of Na⁺. Thus, lamprey erythrocytes appear to be more susceptible to oxidative damage. Ca²⁺ overload does not activate the cytosolic death pathways in these cells.

Romanowsky staining, the Romanowsky effect and thoughts on the question of scientific priority

I give an historical account and analysis of the scientific priority of the discovery of the polychrome staining of microscopic biological preparations provided by mixtures of eosin plus methylene blue and its derivatives, especially azure B. I maintain that both the formal priority for the discovery of the polychrome staining phenomenon and credit for initiating the development of a technique of polychrome staining properly belong to D. L. Romanowsky. His scientific work demonstrated the possibility of using a simple technique to stain hematological preparations selectively to give good contrast, high resolution and the ability to identify malaria parasites. Romanowsky's approach constituted the starting point for the development of a family of polychrome stains for microscopic investigation of hematological preparations by a number of his contemporaries.

Guidelines for May-Grünwald-Giemsa staining in haematology and non-gynaecological cytopathology: recommendations of the French Society of Clinical Cytology (SFCC) and of the French Association for Quality Assurance in Anatomic and Cytologic Pathology (AFAQAP)

OBJECTIVE

Since the guidelines of the International Committee for Standardisation in Haematology (ICSH) in 1984 and those of the European Committee for External Quality Assessment Programmes in Laboratory Medicine (EQALM) in 2004, no leading organisation has published technical recommendations for the preparation of air-dried cytological specimens using May-Grünwald-Giemsa (MGG) staining.

DATA SOURCES

Literature data were retrieved using reference books, baseline-published studies, articles extracted from PubMed/Medline and Google Scholar, and online-available industry datasheets.

RATIONALE

The present review addresses all pre-analytical issues concerning the use of Romanowsky's stains (including MGG) in haematology and non-gynaecological cytopathology. It aims at serving as actualised, best practice recommendations for the proper handling of air-dried cytological specimens. It, therefore, appears complementary to the staining criteria of the non-gynaecological diagnostic cytology handbook edited by the United Kingdom National External Quality Assessment Service (UK-NEQAS) in February 2015.

[Technical recommendations and best practice guidelines for May-Grünwald-Giemsa staining: literature review and insights from the quality assurance]

May-Grünwald-Giemsa (MGG) stain is a Romanowsky-type, polychromatic stain as those of Giemsa, Leishman and Wright. Apart being the reference method of haematology, it has become a routine stain of diagnostic cytopathology for the study of air-dried preparations (lymph node imprints, centrifuged body fluids and fine needle aspirations). In the context of their actions of promoting the principles of quality assurance in cytopathology, the French Association for Quality Assurance in Anatomic and Cytologic Pathology (AFAQAP) and the French Society of Clinical Cytology (SFCC) conducted a proficiency test on MGG stain in 2013. Results from the test, together with the review of literature data allow pre-analytical and analytical steps of MGG stain to be updated. Recommendations include rapid air-drying of cell preparations/imprints, fixation using either methanol or May-Grünwald alone for 3-10minutes, two-step staining: 50% May-Grünwald in buffer pH 6.8 v/v for 3-5minutes, followed by 10% buffered Giemsa solution for 10-30minutes, and running water for 1-3minutes. Quality evaluation must be performed on red blood cells (RBCs) and leukocytes, not on tumour cells. Under correct pH conditions, RBCs must appear pink-orange (acidophilic) or buff-coloured, neither green nor blue. Leukocyte cytoplasm must be almost transparent, with clearly delineated granules. However, staining may vary somewhat and testing is recommended for automated methods (slide stainers) which remain the standard for reproducibility. Though MGG stain remains the reference stain, Diff-Quik(®) stain can be used for the rapid evaluation of cell samples.

Identifying different types of chromatin using Giemsa staining

Mixtures of polychrome methylene blue-eosin Y (i.e., Giemsa stain) are widely used in biological staining. They induce a striking purple coloration of chromatin DNA (the Romanowsky-Giemsa effect), which contrasts with the blue-stained RNA-containing cytoplasm and nucleoli. After specific prestaining treatments that induce chromatin disorganization (giving banded or harlequin chromosomes), Giemsa staining produces a differential coloration, with C- and G-bands appearing in purple whereas remaining chromosome regions are blue. Unsubstituted (TT) and bromo-substituted (BT) DNAs also appear purple and blue, respectively. The same occurs in the case of BT and BB chromatids.In addition to discussing the use of Giemsa stain as a suitable method to reveal specific features of chromosome structure, some molecular processes and models are also described to explain Giemsa staining mechanisms of chromatin.

The Use of texture analysis in the morpho-functional characterization of mast cell degranulation in rainbow trout (Onchorhynchus mykiss)

Degranulation of intestinal mast cells in rainbow trout was studied ex vivo by means of texture analysis and related to the maximal intestinal contraction elicited by degranulation itself. Two strips from the same intestinal segment from ten trout were sampled, processed for light microscopy and stained with Giemsa solution. One of the two strips was exposed to an incremental dose of compound 48/80 in an isolated organ bath before processing. Gray-level RGB channel equivalent and 8-bit gray-level images of five granular cytoplasm areas of mast cells for each section were analyzed for texture features and to evaluate discrimination possibility between treatment groups by means of linear discriminant analysis according to feature selection methods and RGB stacks. Differential mean values (after-before compound 48/80) of the green (r 2 = 0.84, p < 0.01) and blue (r 2 = 0.83, p < 0.01) RGB channels and 8-bit grayscale (r 2 = 0.76, p < 0.05) image correlated significantly with the respective value of maximal intestinal contraction. A possible acidic (anionic) nature for the putative pro-contractile basophil agonist can be inferred.

Giemsa as a fluorescent dye for mineralizing bone-like nodules in vitro

Giemsa was first used as a fluorescent dye for mineralized bone and cartilage in tissue sections. The aim of this study was to establish the use of Giemsa as a fluorescent dye for mineralizing bone-like nodules produced in cell cultures. Osteoblasts were grown under mineralizing conditions for 14 days, producing typical bone-like nodules. Upon staining with Giemsa stock solution for 1 min, the mineralizing nodules could be selectively visualized emitting intense green and red fluorescence when observed under blue and green illumination, respectively. The textural details of the nodules were clearly observed under fluorescence microscopy, allowing to identify regions with different degrees of mineralization. The mineralized nature of the nodules was confirmed using von Kossa's method, Alizarin Red S staining and x-ray mapping for Ca and P in a scanning electron microscope, showing a strong correlation between the mineralizing and the fluorescent nodules. The selective fluorescence was related to the mineral phase, being absent in decalcified samples. The use of Giemsa as a fluorescent dye for mineralizing bone-like nodules presents a simple alternative method to quickly analyze biomineralization assays in vitro under fluorescence microscopy, particularly in the biological evaluation of biomaterials.

The ultimate Wright-Giemsa stain: 60 years in the making

Abstract Wright-Giemsa staining is a common procedure that is performed routinely in hematology laboratories. Consistency in intra-laboratory staining quality is essential for accurate morphological interpretation of blood smears. Although the Wright-Giemsa stain can be challenging to perform, the methods illustrated here have provided consistent, high quality stains in the Special Hematology Laboratory at the University of Minnesota for over half a century. We outline methods for collecting blood specimens, preparing the slides and performing a Wright-Giemsa stain using our combination of reagents. Various techniques that have been passed down in our laboratory for troubleshooting suboptimally stained specimens are shared as well.

Rapid staining techniques in cytopathology: a review and comparison of modified protocols for hematoxylin and eosin, Papanicolaou and Romanowsky stains

The objective of this study was to review and compare rapid protocols for fixation and staining of cytologic smears. We used fresh surgical specimens from dogs and horses to evaluate and modify, if necessary, previously described rapid staining protocols. Slides were wet-fixed, rehydrated or air-dried. Rapid Papanicolaou, hematoxylin and eosin (H&E), and Romanowsky stains were applied, including modification of Diff-Quick stain. The modified rapid staining protocols were simple to use and gave results within 5 minutes that were comparable to those obtained with traditional methods. Advantages of rehydrated vs wet-fixed smears included consistent preparations, a clean background, and equally good or superior nuclear detail.

Coming full circle: a brief history of the domestic synthetic dye and biological stain industries

The synthetic dye industry is traced from its inception in England in 1856 to the European Continent and finally to the United States. The primitive state of this industry in America prior to World War I is described as is the desperate effort to develop the neglected technology once imports were difficult to obtain. Topics include biological stains, formation of the Biological Stain Commission (BSC), pioneers in the industry, dye shortages after World War II, formation of the Environmental Protection Agency (EPA), the decline of the domestic dye industry after the EPA was instituted, and the present state of the domestic dye industry.

Palmitate induces structural alterations in nuclei of cardiomyocytes

The objective of this study was to examine the hypothesis that the alterations of cardiac nuclei, that has been noted in some cardiomyopathies, can be produced by palmitate, a saturated fatty acid present in high circulating concentrations in patients with conditions associated with a high probability of developing cardiomyopathy. Cardiomyocytes isolated from embryonic chick ventricle were maintained in culture for 72 h and then treated with palmitate, 100 microM for 24 h. Cells were stained with acridine orange or Giemsa and examined microscopically. Cell size and nuclear size were examined by forward light scatter during flow cytometry. Cells were permeabilized and their nuclei were stained with propidium iodide and examined by flow cytometry on populations of 10,000 cells. Cardiomyocytes treated with palmitate displayed changes in nuclear appearance as nuclei were larger, relative to cell size, with more intense acridine orange staining in a peripheral location. Nucleoli were often disrupted. Palmitate produced a significant (P < 0.001) and 17% increase in nuclear size compared to untreated cells using flow cytometry analysing forward light scatter to estimate nuclear and whole cells size. There were no significant changes in the size of the whole cell and ratio of nucleus to whole cell was significantly (P < 0.01) increased compared to control cells. Fluorescent activating cell sorting analysis of propidium iodide stained nuclei demonstrated that the nuclear enlargement was not due to cell mitosis as the proportion of nuclei in Go/G1, S or M was not changed by palmitate. In summary, these studies identify that palmitate can induce structural abnormalities of cardiomyocytes nuclei by producing increased nuclear size and nucleolar destruction.

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.

Improving biological dyes and stains: quality testing versus standardization

This paper discusses the impact of both standardization and quality testing of dyes and stains in biology and medicine. After the brief review of why standardized dyes and strains are not presently available commercially, two types of testing and ways of improving dye quality are described. National or international organizations could be established to define standardization of dyes and stains. Standardization would be specifically defined as a list of physico-chemical parameters such as elaborated in this paper. Commercial batches of comparable quality may be labeled by the supplier as "standard dye," a procedure currently performed by the European Council for Clinical and Laboratory Standardization (ECCLS). Also recommended to improve dye quality is commercial dye testing by independent laboratories with subsequent certification for use. This sort of quality control is currently carried out in the United States by the Biological Stain Commission (BSC). The advantages and disadvantages of both techniques and the use of image analysis for the definition of standards are discussed. A combination of both the BSC testing protocols and the ECCLS standards should be established for extended quality control of biological dyes and stains.

Ductal adenocarcinoma of the pancreas. Histopathological features and prognosis

Between 1972 and 1987, curative surgical resection (RO) was performed in 81 patients with ductal adenocarcinoma of the pancreas. In this study, slides from surgical specimens were reviewed, and histopathological features of the carcinomas were retrospectively reevaluated. Tumor stage was the most important prognostic factor: In UICC stages I, II, and III, the median survival times were 13, 16, and 8 mo, respectively. Lymph node involvement and direct extension of the tumor into adjacent peripancreatic tissue, as well as invasion into peripancreatic organs were found to significantly influence survival. Tumor infiltration of the lymphatic vessels was present in 74% of the resected carcinomas and significantly correlated with survival time. There was no relationship between survival and tumor size; furthermore, histological grade of differentiation, age, and sex had no influence on prognosis.

Standardization of biological dyes and stains: pitfalls and possibilities

The present paper gives a review of the actual state of standardization of biological dyes and stains. In a first part general information is given on practical problems encountered by the routine user of dyes with special emphasis on dye contamination. Some theoretical aspects of standardization are discussed. The second part of the paper gives more detailed information on commercial batches of hematoxylin-eosin-, Giemsa- and Papanicolaou-stains and on their standardization. Special problems arising with the application of image analysis techniques are briefly mentioned. User-oriented specifications for the standardization of dyes, stains and staining procedures are given. Fluorescent dyes and dyes used in chromogenic reagents such as the Feulgen-Schiff reaction are not included in this review.

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 HEPES-buffer, pH 6. Staining time is 30-90 min after formol-calcium 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.

Microwave-assisted staining procedures in routine histopathology

The use and practicability of microwave-assisted staining procedures in routine histopathology over more than three years has been evaluated. A domestic microwave oven was used to speed up the following staining procedures: Haematoxylin-Eosin (for frozen sections), Romanowsky-Giemsa, Periodic acid-Schiff (PAS), Ziehl-Neelson, Papanicolaou, Feulgen and Grocott--stain on buffered formalin fixed sections or cytologic smears. These staining procedures can be made highly reproducible providing; (1) Staining vessels are placed in the same position inside the oven; (2) Accurate timing in seconds is observed. Microwave-assisted staining procedures are equal to or even superior to those of the standard methods. Staining times can be reduced to 2%-10% of the conventional staining procedures. The basic staining protocols are presented.

Romanowsky dyes and Romanowsky-Giemsa effect. 5. Structural investigations of the purple DNA-AB-EY dye complexes of Romanowsky-Giemsa staining

A reproducible Romanowsky-Giemsa staining (RGS) can be carried out with standardized staining solutions containing the two dyes azure B (AB) and eosin Y (EY). After staining, cell nuclei have a purple coloration generated by DNA-AB-EY complexes. The microspectra of cell nuclei have a sharp and intense absorption band at 18,100 cm-1 (552 nm), the so called Romanowsky band (RB), which is due to the EY chromophore of the dye complexes. Other absorption bands can be assigned to the DNA-bound AB cations. Artificial DNA-AB-EY complexes can be prepared outside the cell by subsequent staining of DNA with AB and EY. In the first step of our staining experiments we prepared thin films of blue DNA-AB complexes on microslides with 1:1 composition: each anionic phosphodiester residue of the nucleic acid was occupied by one AB cation. Microspectrophotometric investigations of the dye preparations demonstrated that, besides monomers and dimers, mainly higher AB aggregates are bound to DNA by electrostatic and hydrophobic interactions. These DNA-AB complexes are insoluble in water. Therefore it was possible to stain the DNA-AB films with aqueous EY solutions and also to prepare insoluble DNA-AB-EY films in the second step of the staining experiments. After the reaction with EY, thin sites within the dye preparations were purple. The microspectra of the purple spots show a strong Romanowsky band at 18,100 cm-1. Using a special technique it was possible to estimate the composition of the purple dye complexes. The ratio of the two dyes was approximately EY:AB approximately 1:3. The EY anions are mainly bound by hydrophobic interaction to the AB framework of the electrical neutral DNA-AB complexes. The EY absorption is red shifted by the interaction of EY with the AB framework of DNA-AB-EY. We suppose that this red shift is caused by a dielectric polarization of the bound EY dianions. The DNA chains in the DNA-AB complexes can mechanically be aligned in a preferred direction k. Highly oriented dye complexes prepared on microslides were birefringent and dichroic. The orientation is maintained during subsequent staining with aqueous EY solutions. In this way we also prepared highly orientated purple DNA-AB-EY complexes on microslides. The light absorption of both types of dye complexes was studied by means of a microspectrophotometer equipped with a polarizer and an analyser. The sites of best orientation within the dye preparations were selected under crossed nicols according to the quality of birefringence.(ABSTRACT TRUNCATED AT 400 WORDS)

[Model investigations on the structure of the purple dye complex of Giemsa staining]

Nuclei of Giemsa stained cells show a purple coloration, which is generated by a complex of DNA, azure B (AB) and eosin Y (EY). The structure of this complex is unknown. Its absorption spectrum shows a sharp and strong band at 18,100 cm-1 (552 nm), the so called Romanowsky band (RB). It is possible to produce the complex outside of the cell, but it is cubersome to handle. Easier to handle is a purple complex composed of chondroitin sulfate (CHS), AB and EY, which also shows a sharp and strong RB at 18,100 cm-1 in the absorption spectrum. This CHS-AB-EY complex is a model for the DNA-AB-EY complex of Giemsa stained cell nuclei. We tried to investigate its structure. In the first step of the staining procedure CHS binds AB cations forming a stable CHS-AB complex. In the case of saturation each anionic SO4- and COO- -binding site of CHS is occupied by one dye cation and the complex has 1:1 composition. It has a strong and broad absorption band with its maximum at ca. 18,000 cm-1 (556 nm). In the second step the CHS-AB complex additionally binds EY dianions forming the purple CHS-AB-EY complex with its RB at 18,100 cm-1. This band can be clearly distinguished from the broad absorption of the bound AB cations. RB is generated by the EY chromophore, whose absorption is shifted to longer wavelength by the interaction with the CHS-AB framework.

Understanding Romanowsky staining. 2. The staining mechanism of suspension-fixed cells, including influences of specimen morphology on the Romanowsky-Giemsa effect

Romanowsky staining of suspension-fixed lymphocytes and fibroblasts, deposited as monolayers on slides, involves an initial basic dyeing process followed by formation of a hydrophobic Azur B/Eosin Y complex at the more permeable and so faster staining cellular sites. This mechanism is shared with blood and marrow smears. However certain morphological features peculiar to suspension-fixed, cell culture-derived preparations also influence the staining pattern via rate control: namely the irregular and bulky profiles of fibroblasts, compared to the smoother and thinner lymphocytes; and the occasional superficial occlusion of cells by culture medium.

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

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.

Harmine as a substitute for 33258 Hoechst in the FPG technique

We studied the effectiveness of harmine as a substitute for 33258 Hoechst in the fluorescence-plus-Giemsa technique, using Allium cepa chromosomes after 5-bromo-2'-deoxyuridine (BrdU) incorporation. Harmine showed a photosensitizing capacity which was somewhat higher than 33258 Hoechst and used half of the time established for the usual treatment.

Microwave-stimulated staining of plastic embedded bone marrow sections with the Romanowsky-Giemsa stain: improved staining patterns

Staining plastic sections with the Romanowsky-Giemsa method is both time-consuming and difficult. This paper reports how the staining time can be reduced to 25 min using microwave irradiation of the staining solution. It is shown that staining results depend on the fixative used, staining temperature, dye concentration and pH of the staining solution as well as on several parameters of the microwave irradiation technique. The staining patterns are improved when compared with those obtained by conventional staining of plastic sections. The colors are more brilliant and greater contrasts are observed. Basophilia, polychromasia, and orthochromasia accompanying red cell maturation are more pronounced. For white cell maturation the initial appearance of specific granules (neutrophil, basophil, and eosinophil) is more evident. Thus, cell classification is easily accomplished using the described technique. It is suggested that microwave-stimulated staining be considered for routine use.

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).

Quality control of azure B preparations by liquid chromatography and standardization with azure B tetrafluoroborate

A liquid chromatographic procedure for the quantitative determination of the thiazine dye azure B, the principal constituent of Romanowsky stains, is presented. Unlike previous methods relying on peak area normalization, the present approach involves real quantitation through calibration with the reference standard azure B tetrafluoroborate. The method has been used for the quality control of commercial azure B preparations and to study their stability in stock and staining solutions, either or not in the presence of eosin Y. Results suggest that highly pure azure B perchlorate meets the requirements of a reference material, useful for standardization of Romanowsky-Giemsa staining in haematology.

Air drying as a preparatory factor in cytology: investigation of its influence on dye uptake and dye binding

The effect of air-drying on cytological material is investigated in this article. Smears of rat liver were fixed completely wet and, after air drying, postfixed in ethanol, methanol/formaldehyde/acetic acid (MFA), and formaldehyde. Staining was performed with the thionin-Feulgen procedure, a standard Romanowsky-Giemsa stain with azure B-eosin Y and a Papanicolaou staining variant. The image analysis system IBAS 2000 was applied to evaluate objective criteria of the changes caused by air drying the chromatin texture. Nuclear absorption was measured with a Vickers M 85a Microdensitometer. Air-drying had striking effects on size and shape of cell nuclei (spreading), on the structure of the nuclear chromatin (chromatin condensation), and on the chromaticity coordinates (hue, saturation, and intensity of nuclear staining). The variations of the chromatin texture and dye-substrate affinity are attributed to alterations of the tertiary structure of the nuclear proteins.

Increased acidophilia of eosinophil granules after EDTA treatment

The acidophilic reaction of eosinophil leucocyte granules from human, pig and horse blood smears was investigated by using May-Grünwald-Giemsa staining after previous treatment with EDTA and sodium citrate solutions. The same peak at 530 nm, but absorption values considerably higher than those of controls, were found in eosinophil granules after application of chelating agents, indicating that removal of metal cations could unmask basic groups in these structures.

The involvement of nucleosomes in Giemsa staining of chromosomes. A new hypothesis on the banding mechanism

A new hypothesis is proposed on the involvement of nucleosomes in Giemsa banding of chromosomes. Giemsa staining as well as the concomitant swelling can be explained as an insertion of the triple charged hydrophobic dye complex between the negatively-charged super-coiled helical DNA and the denatured histone cores of the nucleosomes still present in the fixed chromosomes. New cytochemical data and recent results from biochemical literature on nucleosomes are presented in support of this hypothesis. Chromosomes are stained by the Giemsa procedure in a purple (magenta) colour. Giemsa staining of DNA and histone (isolated or in a simple mixture) in model experiments results in different colours, indicating that a higher order configuration of these chromosomal components lies at the basis of the Giemsa method. Cytophotometry of Giemsa dye absorbance of chromosomes shows that the banding in the case of saline pretreatment is due to a relative absence of the complex in the faintly coloured bands (interbands). Pretreatment with trypsin results in an increase in Giemsa dye uptake in the stained bands. Cytophotometric measurements of free phosphate groups before and after pretreatment with saline, reveal a blocking of about half of the free phosphate groups indicating that a substantial number of free amino groups is still present in the fixed chromosomes. Glutaraldehyde treatment inhibited Giemsa-banding irreversibly while the formaldehyde-induced disappearance of the bands could be restored by a washing procedure. These results correlate with those of biochemical nucleosome studies using the same aldehydes. Based on these findings and on the known properties of nucleosomes, a mechanism is proposed that explains the collapse of the chromosome structure when fixed chromosomes are transferred to aqueous buffer solutions. During homogeneous Giemsa staining reswelling of the unpretreated chromosome is explained by insertion of the hydrophobic Giemsa complex between the hydrophobic nucleosome cores and the superhelix DNA. Selective Giemsa staining of the AT-enriched bands after saline pretreatment is thought to be due to the, biochemically well-documented, higher affinity of arginine-rich proteins present in the core histones for GC-enriched DNA, which prevents the insertion of the Giemsa complex in the interbands. Production of Giemsa bands by trypsin pretreatment can be related to the action of this enzyme on the H1 histones and subsequent charge rearrangements.(ABSTRACT TRUNCATED AT 400 WORDS)

On the nature of Romanowsky-Giemsa staining and the Romanowsky-Giemsa effect. I. Model experiments on the specificity of azure B-eosin Y stain as compared with other thiazine dye-eosin Y combinations

After incorporation into a polyacrylamide matrix, the biopolymers DNA, RNA, heparin, hyaluronic acid, collagen and the synthetic polymers poly(U) and poly(A, U) were stained with the pure thiazine dyes, Methylene Blue, the Azures and Thionin alone and combined with Eosin Y. Satisfactory spectrophotometric agreement was obtained between the staining reactions of the biopolymers in the artificial matrix and those in their natural surroundings. This was especially true with respect to the specificity of the Azure B-Eosin Y dye-pair, which is based on the generation, on suitable substrates, of a purple colour, the Romanowsky-Giemsa effect (RGE), with an absorbance maximum near 550 nm. In the model experiments, DNA, heparin, hyaluronic acid and collagen were found to be RGE-positive and poly(U), poly(A, U) and RNA RGE-negative. A theory of RGE is proposed which complies with the new and earlier observations: after saturation of available anionic binding sites and aggregate formation by Azure B, electron donor acceptor complexes are formed between Eosin Y and Azure B via hydrogen-bridge formation of the aminosubstituent proton of Azure B and between Eosin Y and the biopolymer surface. Charge-transfer complex formation may also account for the qualitative identity of Azure B-Eosin Y and Azure A-Eosin Y spectra of substrates, which are coloured purple. Quantitatively, Azure A-Eosin Y is less efficient in giving RGE. The generation of RGE is time-dependent. Equilibrium staining is attained after about 120 h. The implications of the results for the biological application of Romanowsky-Giemsa staining are discussed briefly.

Stability of azure B-eosin Y staining solutions

The stability of azure B-eosin Y staining solutions of varying composition and of a routine May Grunwald Giemsa (MGG) stain were studied by analysis of the density histogram of white blood cells obtained by an image analysis computer. The stability appeared to be variable and depended on the concentration of the dyes, the molarity of the buffer solutions and the presence of dimethylsulfoxide (DMSO) as a stabilizer. Although most staining solutions including the routine MGG stain showed marked loss of staining capacity soon after preparation, it was possible to obtain an azure B-eosin Y mixture with very satisfactory staining properties which did not decrease during 8 h after its preparation.

[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)