Report from the President

Although the original Commission on Standardization of Biological Stains was first organized in 1921, it was not until 1944 that this was incorporated as an independent, nonprofit organization known as the Biological Stain Commission (see Clark 1974). The certification of dyes, as indicated by special labels purchased by manufacturers or vendors for attachment to the dye containers, originated with the parent organization and has continued to this day. The objectives of the Biological Stain Commission (BSC) are 1) to identify and standardize the content and performance of dyes and dye preparations used in staining biological tissues and products, 2) to issue labels of certification to companies that buy these to inform consumers that their certified dyes meet the specifications of the BSC, 3) to carry out and to support investigations on dyes and their performance, 4) to publish scientific data concerning biological stains and their use, and 5) to maintain, through scientific meetings and correspondence, an active “dialogue” among scientific and industrial personnel concerned with biological stains. The present report summarizes Commission activity and some of the changes that have occurred during the past five years.     

General Considerations: Methods for the Standardization of Biological Stains: Part I

This is the introduction to a series of papers giving the assay methods employed in the testing of dyes submitted to the Commission on Standardization of Biological Stains. These methods are used in determining whether or not to allow the sale of any particular batch of dye as a certified stain. The present paper takes up general considerations, discussing the relative merits of various analytical methods designed both for qualitative and quantitative analysis. The advantages of determining light “absorption ratios” for qualitative purposes, and of titanous chloride reduction for quantitative purposes are pointed out. It is further indicated that in spite of all the refinements that have yet been made in chemical and optical methods of analysis, great weight must be placed on biological testing in determining the quality of any given sample.     

The Biological Stain Commission's Quality Control Laboratory operations and improved traceability of certified stains

Abstract

The Biological Stain Commission (BSC) is a quality control laboratory that certifies biological dyes for staining cells and tissues. Originally, a single lot of a certified dye was sold to histologists. Today, companies frequently change their lot numbers as part of regulatory efforts. When a certified dye undergoes a lot number change, the BSC must re-certify this dye to verify that it is identical to the one certified earlier. The BSC has improved how these lot changes are monitored using a redesigned BSC certification label. Certification labels always have been issued by the BSC and are attached to every bottle of “BSC certified dye” that is sold. The new BSC certification label has added security features and currently bears both the BSC certification number and the manufacturer batch lot number. The result is improved security and traceability of certified dyes.     

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.     

Report from the President the Biological Stain Commission: Its Goals, Its Past and Its Present Status

This is a brief overview of the goals, evolution, and present status of the Biological Stain Commission. The main function of the Commission is the testing and certification of dye batches intended for biological applications. The testing is supported by charges made for batch testing and by the sale of certification labels affixed to individual dye containers. Submission of dyes for testing is voluntary, depending on the cooperation of the companies who sell them and the consumers who buy them. The supportive role of the University of Rochester School of Medicine and Dentistry—both past and present—is not well known and should be. Increasingly federal regulations affect the production, availability, and cost of dyes. Commission income from the sale of labels has decreased in recent years. Continuation of its work requires changes that will produce more income. Much dye is now sold in solutions instead of dry powders. The value of using Stain Commission certified dyes whenever possible is illustrated by the case of basic fuchsin. Years ago this dye was a mixture. Most basic fuchsin now marketed consists mainly of either pararosanilin (Colour Index No. 42500) or rosanilin (C.I. No. 42510). The Biological Stain Commission discovered that some certified batches of both pararosanilin and rosanilin sold as “basic fuchsin” had incorrect C.I. numbers on the labels. Sometimes that caused failure of the aldehyde fuchsin stain. Unless made with pararosanilin, aldehyde fuchsin does not stain pancreatic islet B-cells, elastic fibers, and hepatitis B surface antigen in unoxidized sections. Mislabelling by packagers may interfere with other applications of pararosanilin and rosanilin. The Commission acted to publicize and correct this problem. Biological Stain Commission publications help educate microscopists and histotechnologists about dyes and their best use. Stain Commission representatives from member scientific societies provide valuable input about changes in the availability and quality of such dyes as hematoxylin and others; they also provide useful feedback to their societies about dye problems. Each new generation of biologists and histotechnologists should be taught the importance of using only Stain Commission certified stains when available. They should be taught also to notify the Stain Commission whenever they experience problems with any certified dye.     

Revised procedures for the certification of carmine (C.I. 75470, Natural red 4) as a biological stain

Carmine is one of the original dyes certified by the Biological Stain Commission (BSC). Until now it has lacked both an assay procedure for dye content and a means to positively identify the dye. The methods for testing carmine in the laboratory of the BSC have been revised to include spectrophotometric examination at pH 12.5-12.6 to determine that the dye is carmine (λ_max=530-335 nm). The maximum absorbance of a solution containing 100 mg of dye per liter of water, adjusted to pH 12.5-12.6, which provides a relative measure of dye content, should lie in the range 1.2 to 1.8. If the dye is not carmine, spectrophotometry at pH 1.9-2.1 shows whether it is carminic acid (λ_max=490-500 nm) or 4-aminocarminic acid (λ_max=525-530 nm). The latter two dyes, which are also called carmine when sold as food colorants, have physical properties different from those of true carmine. The functional tests for carmine as a biological stain are Orth's lithium-carmine method for nuclei, Southgate's mucicarmine method for mucus, and Best's carmine method for glycogen.     

Accomplishments of the Trustees and laboratory staff of the Biological Stain Commission, 2002–2013

During the 12 years from 2002 to 2013, the Trustees and laboratory personnel of the Biological Stain Commission (BSC) can claim many accomplishments. These accomplishments are itemized under 11 categories: continuous publication of the official journal, Biotechnic & Histochemistry; production of four special issues of Biotechnic & Histochemistry devoted to specific dyes or stains; standardization of staining and dye purity; mechanisms of staining and prediction of dye behavior; publication of books or book chapters; effects of fixation and processing on staining; cancer research; immunohistochemistry; BSC Laboratory activities; miscellaneous publications; and administrative accomplishments.     

Traditional staining for routine diagnostic pathology including the role of tannic acid. 1. Value and limitations of the hematoxylin-eosin stain

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 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.     

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     

The Application of Dyes in the Cancer Problem

Three fundamental requirements for the problem of developing a differential stain for cancer are discussed: I. the choice of a technic for the microscopic preparation of tissues; II. an analysis of the biological properties peculiar to cancer; and III. various groups of dyes adaptable to such peculiar properties of cancer tissue. Under I the disadvantages of intravitam staining are pointed out and the use of cell suspensions, frozen sections, and fixed material favored. Under II three characteristics of cancer tissue offering possibilities for differential staining are discussed, the cytological structure known as the “plastin reaction”, the histogenic cycle of cancer tissue, and the viability of cancer tissue under anaerobic conditions. Under III modifications of the Giemsa stain are suggested for application to the plastin reaction, specific tissue stains advocated for the use of indicating end points in histogenic cycles, and the vital dyes, congo red and trypan blue, suggested as indicators for the survival of malignant tissues because of the failure of these dyes to permeate living cancer cells.

The angle of approach thruout has been an attempt to avoid unconscious pitfalls inherent in certain microscopic technics, and to substitute analytical methods for the blind trial and error method of routinely applying dye after dye in endless succession.     

The Selective Staining of Mitochondria

A critical analysis of extant selective mitochondrial stains has elucidated certain empirical criteria for the adoption of dyes for trial. These criteria include a specific triphenylmethane structure for the dye, with sulfonation and the use of aniline and heat as adjuvants. By the application of these characteristics the dyes fast green FGF and light green SF yellowish were chosen for study and proved to be highly selective mitochondrial stains. They are applicable to both tissue slices and homogenate studies and permit examination of the internal structure of mitochondria.     

The Determination of Apparent Isoelectric Points of Cell Structures by Staining at Controlled Reactions

The staining reactions at controlled pH-values of various dyes with the nucleus and cytoplasm of Trichonympha collaris under different conditions were investigated. When staining intensity was plotted against pH, it was found that with each dye a different curve was obtained. “Isoelectric points” obtained by superposition of acid and basic dye curves varied for the same material with the dyes employed. It was found that, with the same dye, the curves of staining intensity plotted against pH varied with the buffer system utilized. Moreover, the intensity of staining at any pH was found to vary directly with the concentration of dye and inversely with the concentration of buffer. Various factors modifying staining intensity were studied. In the staining of a protein in buffered solution, it was shown that staining intensity (the index of the concentration of the dye-protein compound) at a given pH-value is dependent upon the interaction of the dye-protein, buffer-protein and dye-buffer systems, and that as the dye or buffer or their concentrations were varied, the resultant “isoelectric points” which were obtained also varied. In view of these facts and of the present lack of knowledge of dyes and dye-protein combinations it would be impossible to determine a true isoelectric point by staining at controlled pH-values without further extensive work on the subject. It follows that no true isoelectric points have hitherto been obtained for nucleus, cytoplasm or other tissue elements by staining at controlled pH.     

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.     

The history, chemistry and modes of action of carmine and related dyes

Carmine has been used in biological staining to demonstrate selectively nuclei, chromosomes or mucins, depending on the formulation. Throughout its history in science, complaints and frustrations have been expressed about dye quality. Inconsistencies in dye quality or identity have prevented thorough understanding of staining mechanisms and have caused many stain solutions to behave unsatisfactorily. The aim of this review is to (1) detail causes of these problems, which are rooted in history, geography and production, (2) offer ways to minimize problems and (3) provide modern explanations for stain behavior. Carmine is a “semi-synthetic” dye, i.e., a complex of aluminum and the natural dye cochineal (carminic acid). Carmine shows considerable batch-to-batch variability. Geography, politics, history, agricultural practices and iconography all contribute to the variability of cochineal. In addition, widely divergent manufacturing methods are used to produce carmine. Also, confusion in terminology has led to mislabeling. Pressure from the food industry for a more satisfactory colorant for acidic foods led to the introduction of a new dye, aminocarminic acid, which could enter the biological market inadvertantly. Improved methods of analysis should help the certification process by the Biological Stain Commission. Further standardization could be achieved by replacing most of the methods of solubilizing carmine. The majority of these methods use heat, which is likely to damage the dye molecule. Fortunately, carmine is readily dissolved by raising the pH of the aqueous solvent above 12, and a new form of the dye, now available commercially, is soluble in water without the need for heat or pH adjustment. Chemical structures and physical properties of carminic acid, carmine, aminocarminic acid and kermesic acid are reviewed. A new configuration for carmine is proposed, as well as possible changes to carminic acid and carmine molecules as a result of decomposition caused by heating. Each of the major classes of carmine-based stains is described as are possible mechanisms of attachment to specific substrates. Glycogen binds carmine through hydrogen bonding, and it is here that carmine decomposed by heat could have the greatest detrimental impact. Nuclei and chromosomes are stained via coordination bonds, perhaps supplemented by hydrogen bonds. Finally, acidic mucins react ionically with carmine. Specificity in the latter case may be due to unique polymeric carmine molecules that form in the presence of aluminum chloride.     

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.