Standardization of biological dyes and stains: pitfalls and possibilities

Summary 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.This paper is dedicated to my academic teacher, Prof. Dr. D.H. Wittekind, on the occasion of his 70th birthday     

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

Summary 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.     

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 a brief review of why standardized dyes and stains 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.     

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.     

Standardization of the Romanowsky staining procedure: an overview

Commerically available Romanowsky blood stains are variable mixtures of thiazein dyes and brominated fluorescein derivatives with varying degrees of metallic salt contamination in a number of different solvent systems. There is a need for standardized Romanowsky stains of constant composition, which, when used in conjunction with a carefully controlled specimen preparation technique, should give consistent performance. Such a preparation system would be of great value to hematologists in general and would be essential to the validity of data obtained by the digital processing of blood cell images. It is possible to prepare standardized Romanowsky stains as mixtures of two or three dye components, namely, eosin Y, azure B and methylene blue, although azure B has only recently become commercially available at an acceptable degree of purity. The logistic problems of stain standardization are discussed.     

Spectrophotometric Characteristics and Assay of Biological Stains III. The Xanthenes

In this continuation paper of the work on the chemical and spectrophotometic characteristics of commercial stains, data on the xanthene dyes are presented. In the xanthene group of dyes, it has been found possible to assay pyronin B, eosins B and Y and ethyl eosin by spectrophotometric means. Phloxine B, rose Bengal, and erythrosin B are assayed by die color acid precipitation method. Typical absorption curves are given for these dyes as well as representative spectral and assay data.     

The Fluorane Derivatives: Methods for the Standardization of Biological Stains: Part II

In this paper the methods are given which are used in determining whether to approve the sale of certain dyes of the fluorane group as certified biological stains. The methods have been worked out by the Commission on Standardization of Biological Stains in cooperation with the Color and Farm Waste Division, Bureau of Chemistry and Soils, U. S. Dept. of Agriculture. The dyes for which the methods are given in the present paper are: Fluorescein, eosin yellowish, ethyl eosin, eosin bluish, erythrosin, phloxine B, and rose bengal. For each of these dyes methods are given under the following headings: (1) identification or qualitative examination; (2) quantitative analysis; and (3) biological tests.     

Standardization in Biological Staining. The Influence of Dye Manufacturing

The purpose of biological staining is to obtain specimens of biological material that can be assessed in the microscope. These specimens are influenced by all processes from removal from the intact organism to mounting on the microscopic slide. To achieve comparable results with various techniques for biological staining, standardization of all procedures and reagents is mandatory. In this paper, I focus particularly on dyes and consider the possibilities for obtaining standardized dyes. In general practice, most biological staining takes place with available commercial dyes. These dyes may or may not have been subjected to quality assessment either internally by the producer or vendor or externally by independent investigators or organizations such as the Biological Stain Commission. Concerted attempts at standardization in Europe are discussed. The latest results of this work, the European standard EN 12376, is presented. This standard is concerned with information supplied by the manufacturer with in vitro diagnostic reagents for biological staining. The standard has been prepared by a Working Group on Staining in Biology under Technical Committee 140, In Vitro Medical Devices, of the European committee for standardization, CEN.     

Standardization in biological staining. The influence of dye manufacturing.

The purpose of biological staining is to obtain specimens of biological material that can be assessed in the microscope. These specimens are influenced by all processes from removal from the intact organism to mounting on the microscopic slide. To achieve comparable results with various techniques for biological staining, standardization of all procedures and reagents is mandatory. In this paper, I focus particularly on dyes and consider the possibilities for obtaining standardized dyes. In general practice, most biological staining takes place with available commercial dyes. These dyes may or may not have been subjected to quality assessment either internally by the producer or vendor or externally by independent investigators or organizations such as the Biological Stain Commission. Concerted attempts at standardization in Europe are discussed. The latest results of this work, the European standard EN 12376, is presented. This standard is concerned with information supplied by the manufacturer with in vitro diagnostic reagents for biological staining. The standard has been prepared by a Working Group on Staining in Biology under Technical Committee 140, In Vitro Medical Devices, of the European committee for standardization, CEN.     

New Stains for Blood and Bone Marrow Cells

Traditionally, blood and bone marrow cells have been identified based on their characteristic shapes and colors when stained with one of several panoptic stains including Wright's or Giemsa's. As questions arose regarding the origin of normal and leukemic cells, cytochemical stains were developed. These stains help identify cells on the basis of a distinctive metabolite or enzyme. As part of an ongoing tradition in which textile dyes are used for biological staining, several new stains have been applied to hematologic staining. These include C.I. basic blue 41, basic blue 141, basic blue 93, and an assymetrical polymethine dye. As additional cell-selective stains are developed, we can anticipate further improvements in our ability to identify normal and malignant hematopoietic cells.     

New stains for blood and bone marrow cells.

Traditionally, blood and bone marrow cells have been identified based on their characteristic shapes and colors when stained with one of several panoptic stains including Wright's or Giemsa's. As questions arose regarding the origin of normal and leukemic cells, cytochemical stains were developed. These stains help identify cells on the basis of a distinctive metabolite or enzyme. As part of an ongoing tradition in which textile dyes are used for biological staining, several new stains have been applied to hematologic staining. These include C.I. basic blue 41, basic blue 141, basic blue 93, and an asymmetrical polymethine dye. As additional cell-selective stains are developed, we can anticipate further improvements in our ability to identify normal and malignant hematopoietic cells.     

Standardization of the Feulgen reaction for absorption DNA image cytometry: a review.

The present paper gives a review of the current potentials and problems of a standardized Feulgen reaction for absorption DNA image cytometry. The cytochemical basis of the Feulgen reaction is described in the first part of this review. Subsequently, several preparatory factors which influence the performance of the Feulgen reaction, such as fixation, acid hydrolysis, composition of the Feulgen reagent and, in histology, embedding, are discussed in more detail. Some user-oriented recommendations for a standard Feulgen technique are given.     

Absorption Ratios of Biological Stains

Absorption ratios are supplied for most of the dyes used as biological stains.

The use of these ratios will enable the analyst to identify the stains conveniently, and will also frequently afford information of considerable value respecting their purity.     

Studies on Textile Dyes for Biological Staining: I. Pontacyl Blue Black SX, Pontacyl Violet 6R and Luxol Fast Yellow TN

After a series of commercial grade textile dyes were screened, three -were found to be excellent biological stains. Two of these, pontacyl blue black SX and pontacyl violet 6R, were nuclear stains, the best results being obtained after mordanting with chrome salts. The third dye, luxol fast yellow TN, imparted a brilliant yellow stain to the cytoplasm and collagen fibers when used in alcoholic solution. A technical procedure for the use of either of the nuclear stains combined with the yellow cytoplasmic stain is given.     

Various Oil Soluble Dyes as Pat Stains in the Supersaturated Isopropanol Technic

Oil red O (xylene-azo-xylene-azo-β-naphthol), oil red 4B or EGN (xylene-azo-toluene-azo-β-naphthol) and Sudan red 4B give somewhat deeper orange red or red fat stains and more stable dilute isopropanol solutions than Sudan IV. Sudan II gives brighter orange-yellow fat stains and stronger stable dilute isopropanol solutions than Sudan HI. Satisfactory brownish red dyes as to intensity and stability of their dilute isopropanol solutions are Sudan brown, Sudan brown 5B, and oil brown D.     

Influence of staining on fast automated cell segmentation, feature extraction and cell image analysis

FAZYTAN, a system for fast automated cell segmentation, cell image analysis and extraction of nuclear features, was used to analyze cervical cell images variously stained by the conventional Papanicolaou stain, the new Papanicolaou stain and hematoxylin and thionin only; the last two dyes are used as the nuclear stains in the two versions of the Papanicolaou stain. Other dyes were also tried in cell classification experiments. All cell images in the variously stained samples could be described by the same nuclear features as had been adapted for the discrimination of conventional-Papanicolaou-stained cells. Variances were lower for thionin-stained cells as compared with hematoxylin-stained cells. By application of spectrophotometry, it was confirmed that the spectra of the cytoplasmic counterstains are superimposed on those of the nuclear stains. It appears that a variety of dyes are suitable as cytologic stains for cell classification by the FAZYTAN system, provided that they achieve sufficiently strong nuclear-cytoplasmic contrast by precisely delineating the chromatin texture.     

The History of Staining Logwood Dyes

Except for the cochineal derivatives, logwood extract was the first of the important modern stains to be employed in histology. Certain other natural dyes, such as madder and indigo, had been used earlier, but they are of little significance in discussing the history of staining, because none of them nor even alizarin, the derivative of madder, are of any appreciable significance in these days of synthetic dyes. Hematoxylin, on the other hand, still continues a very important stain, and it has played an interesting part in the history of staining.