D Wittekind scite author profile

Biotechnic & Histochemistry

2003

The components of the hematoxylin and eosin (H & E) stain (i.e. hemalum and eosin Y), their contributions to the typical staining pattern, and the reasons why the H & E stains are the preferred oversight stains for routine diagnostic histopathology are discussed. The essential diagnostic significance of effective nuclear staining by hemalum, providing information on nuclear morphology and texture, is emphasized; as is the ironic advantage for routine diagnostic histopathology of the limited range of colors provided by H & E staining, that allows recognition of significant features under low microscopic magnifications. Standardization of hemalum is considered, along with probable reasons why users show resistance to such a concept. Counterstaining with anionic (acid) dyes is discussed, as is the important phenomenon of contrast. The particular advantages and disadvantages of eosin Y and phloxin B as counterstains to hemalum are outlined. The concept of an "ideal routine histological stain" is considered, and H & E is compared to such an ideal case. Finally, deficiencies of H & E staining are discussed, and a program to develop an improved oversight stain is introduced.

Standardization of reagents and methods used in cytological and histological practice with emphasis on dyes, stains and chromogenic reagents

et al. 1994

The need for the standardization of reagents and methods used in the histology laboratory is demonstrated. After definitions of dyes, stains, and chromogenic reagents, existing standards and standards organizations are discussed. This is followed by practical instructions on how to standardize dyes and stains through the preparation of reference materials and the development of chromatographic methods. An overview is presented of the problems concerned with standardization of the Romanowsky-Giemsa stain for cytological and histological application. Finally, the problem of how to convince routine dye and stain users of the need for standardization in their histology laboratories is discussed.

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

1983

Histochem J

The chances of Romanowsky---Giemsa (RG) staining becoming a reliable and useful histochemical procedure are reviewed, based on the now proven fact that RG staining requires two dyes only, namely, cationic Azure B and anionic Eosin Y. These two dyes differ from otherwise similar dye combinations in that they give, on distinct biological substrates, one additional colour, purple, which cannot be obtained by the use of either dye alone. The purple colour characterizes the Romanowsky--Giemsa effect (RGE), which is the essential feature of RG staining. Consideration is given to the physico-chemical and morphological implications of RGE. Of primary importance is the nature of the biological substrates where RGE occurs, and also of those where it has never been observed. The way substrates react to RG stains largely depends on the kind of pretreatment they have received; for instance, alcoholic fixation preserves RGE but formaldehyde may inhibit it. Physico-chemical factors are considered which, by altering either the biological substrates or the composition of the staining solutions, may modify the RG staining pattern. This review also serves as an introduction for a series of experimental papers that will follow and which are intended to consolidate the basis of RG staining, a method which holds much promise as a useful histochemical tool.

On the nature of Romanowsky dyes and the Romanowsky-Giemsa effect

2008

Summary This paper reviews the nature of Romanowsky staining and the relationship between Romanowsky dyes and the Romanowsky‐Giemsa effect (RGE). On blood and bone marrow smears the RGE is characterized by a purple colouration of nuclei and neutrophil granules. The nuclear purple contrasts strongly with the blue cytoplasmic staining of cells rich in RNA. Requirement for the occurrence of RGE are: 1 A cationic dye: The best dye is azure B and, though azure A gives the nuclear purple colour, the cytoplasmic blue is inferior. No other cationic dye such as methylene blue is suitable. 2 An anionic dye: Most commonly eosin Y is used, but it can be replaced by the erythrosins. Full halogenation of the fluorescein (four atoms of bromine or iodine) is not necessary. Phloxine and rose bengal are unsuitable. 3 An appropriate substrate: These are proteins with acidic side groups or proteins bound to a polyanion. For interaction with the dyes substrates must provide a suitable three‐dimensional network which is why the RGE is not obtained in solutions. A tentative theory of RGE is advanced and briefly discussed.

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

Gehring

1985

Histochem J

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.