The long history of hematoxylin

Hematoxylin is a naturally occurring chemical used as the basis of a dye in laboratories throughout the world to stain nuclei in microscope slide preparations. This chemical is extracted from the logwood tree Hematoxylon campechianum and was discovered by Spanish explorers to the Yucatan in 1502. A vigorous trade soon developed related to growing and preparing hematoxylin for use in dyeing fabrics in Europe. In the mid 1800s, amateur microscopists first used hematoxylin to stain cellular components. Later scientists developed a wide range of techniques to demonstrate different cellular components. Hematoxylin remains the most popular nuclear stain in histology. This paper briefly describes the history of hematoxylin production and use in histology.

The Staining of Mast Cells: A Historical Overview

The specificity of several staining methods for mast cells provides the pathologist with a useful means for the differential diagnosis of mast cell tumors. Mast cells stain metachromatically with toluidine blue with greater intensity in cells containing smaller granules. Most stains for mast cells rely on the cell's content of heparin, other glycosaminoglycans, and esterase. As an alternative to histochemical stains, different antibodies have been used to identify mast cells in humans.

The discovery of dendritic spines by Cajal in 1888 and its relevance in the present neuroscience

The year 2006 marks the centenary of the Nobel Prize for Physiology or Medicine awarded to Santiago Ramón y Cajal and Camilo Golgi, "in recognition of their work on the structure of the nervous system". Their discoveries are keys to understanding the present neuroscience, for instance, the discovery of dendritic spines. Cajal discovered dendritic spines in 1888 with the Golgi method, although other contemporary scientists thought that they were silver precipitates. Dendritic spines were demonstrated definitively as real structures by Cajal with the Methylene Blue in 1896. Many of the observations of Cajal and other contemporary scientists about dendritic spines are active fields of research of present neuroscience, for instance, their morphology, distribution, density, development and function. This article will deal with the main contributions of Cajal and other contemporary scientists about dendritic spines. We will analyse their contributions from the historical and present point of view. In addition, we will show high quality images of Cajal's original preparations and drawings related with this discovery.

Acid-Fast Positive and Acid-Fast Negative Mycobacterium tuberculosis: The Koch Paradox

Acid-fast (AF) staining, also known as Ziehl-Neelsen stain microscopic detection, developed over a century ago, is even today the most widely used diagnostic method for tuberculosis. Herein we present a short historical review of the evolution of AF staining methods and discuss Koch's paradox, in which non-AF tubercle bacilli can be detected in tuberculosis patients or in experimentally infected animals. The conversion of Mycobacterium tuberculosis from an actively growing, AF-positive form to a nonreplicating, AF-negative form during the course of infection is now well documented. The mechanisms of loss of acid-fastness are not fully understood but involve important metabolic processes, such as the accumulation of triacylglycerol-containing intracellular inclusions and changes in the composition and spatial architecture of the cell wall. Although the precise component(s) responsible for the AF staining method remains largely unknown, analysis of a series of genetically defined M. tuberculosis mutants, which are attenuated in mice, pointed to the primary role of mycolic acids and other cell wall-associated (glyco)lipids as molecular markers responsible for the AF property of mycobacteria. Further studies are now required to better describe the cell wall reorganization that occurs during dormancy and to develop new staining procedures that are not affected by such cell wall alterations and that are capable of detecting AF-negative cells.

Origins of ... tinctorial methods in histology

Images

Innervation of the human epidermis. A historical review

Skin biopsy represents an attractive technique to evaluate the extensive innervation of human epidermis, as demonstrated by the immunoreactivity of the intra-epidermal nerve fibers to the marker protein gene product 9.5. Intra-epidermal nerve fibers can be reliably quantified, and their density correlates with both the presence and the severity of sensory neuropathy. The first description of nerve fibers within human epidermis was published by Paul Langerhans. However, the limitations imposed by the relatively insensitive staining methods led several investigators working during the following century to deny or minimize their existence. The author reviews the assumptions and the striking discrepancies emerging from the wide literature on cutaneous sensory terminations since the late nineteenth century and highlights the new developments emerging from the most recent works.

Santiago Ramón y Cajal and methods in neurohistology

Controversy, misunderstanding or uninformed opinion abound over the extent to which the great Spanish neurohistologist, Santiago Ramón y Cajal, specified his staining methods in his analytical papers, the methods by which he analysed and presented his data, and the microscopes available to him. In this paper, we have attempted to outline the information on these points that we have been able to obtain from a detailed examination of his writings and a study of the evidence remaining in the Cajal Museum in Madrid.

A Historical Perspective on the Identification of Cell Types in Pancreatic Islets of Langerhans by Staining and Histochemical Techniques

Before the middle of the previous century, cell types of the pancreatic islets of Langerhans were identified primarily on the basis of their color reactions with histological dyes. At that time, the chemical basis for the staining properties of islet cells in relation to the identity, chemistry and structure of their hormones was not fully understood. Nevertheless, the definitive islet cell types that secrete glucagon, insulin, and somatostatin (A, B, and D cells, respectively) could reliably be differentiated from each other with staining protocols that involved variations of one or more tinctorial techniques, such as the Mallory-Heidenhain azan trichrome, chromium hematoxylin and phloxine, aldehyde fuchsin, and silver impregnation methods, which were popularly used until supplanted by immunohistochemical techniques. Before antibody-based staining methods, the most bona fide histochemical techniques for the identification of islet B cells were based on the detection of sulfhydryl and disulfide groups of insulin. The application of the classical islet tinctorial staining methods for pathophysiological studies and physiological experiments was fundamental to our understanding of islet architecture and the physiological roles of A and B cells in glucose regulation and diabetes.

The Golgi Stain: invention, diffusion and impact on neurosciences

The black reaction, invented in 1873 by Camillo Golgi (1843-1926, was the first technique to reveal neurons in their entirety, i.e. with all their processes. This important development passed unnoticed at first and only received wide international attention after a long delay. The Golgi stain was widely employed for almost thirty years and was directly responsible for major advances in our knowledge of the microscopic anatomy of the nervous system, as well as in other fields of study. In the hands of other researchers, the black reaction provided vital evidence that helped to establish the neuron theory. The Golgi stain was almost forgotten in the period between the two World Wars, but the introduction of the electron microscope to neurocytological resarch revived its use around the middle of the twentieth century. Today, the black reaction is still used extensively not only in combination with electron microscopy, but also as an autonomous technique in studies on the evolution, ontogeny, and organization of the nervous system.

Robert Koch and the pressures of scientific research: tuberculosis and tuberculin

Images

James Homer Wright: a biography of the enigmatic creator of the Wright stain on the occasion of its centennial

James Homer Wright (1869-1928), the eldest son of a Pittsburgh glass merchant, was educated in Baltimore and practiced pathology in Boston from 1893 until his death in 1928. In 1896, when not quite 27 years old, he assumed directorship of the newly founded Pathology Laboratory at the Massachusetts General Hospital, a post he held for the next 30 years. He is remembered eponymously by the blood cell stain that bears his name and the Homer Wright pseudorosettes of neuroblastoma, but he made many additional contributions to pathology. These include the following: determination of the cellular lineage of multiple myeloma, identification of the megakaryocyte as the cell of origin of blood platelets, recognition of the cell of origin of the neuroblastoma, demonstration of spirochetes in syphilitic aneurysms of the aorta, and clarification of misconceptions about actinomycosis. Additionally, Wright coauthored, with Dr. Frank B. Mallory, the book Pathological Technique, which was a staple of laboratories for >40 years and exemplifies Wright's wide-ranging interests in, and contributions to, practical aspects of pathology including staining, culture and frozen section techniques, photography, and development of the rotary microtome. He received Honorary Doctor of Science Degrees from Harvard University, the University of Maryland (his alma mater), and the University of Missouri. He was the recipient of the Gross prize in 1905 for his publication on actinomycosis and the Boylston Medical Prize in 1908 for his discovery of the origin of platelets, and he was inducted into the American Academy of Arts and Sciences in 1915. Although shy and somewhat austere in the workplace, a different side was shown by his anonymously sending flowers to a young Norwegian opera singer whom he subsequently married. The pathology laboratories of the Massachusetts General Hospital were named the "James Homer Wright Pathology Laboratories" in 1956. Today James Homer Wright is remembered and honored 100 years after his description of the stain that, along with the pseudorosettes of neuroblastoma, carry his name into eternity and ensure his great contributions will never be forgotten.

Labeled antigens and antibodies: the evolution of magic markers and magic bullets

The ability to label antigens and antibodies with simple chemicals and even with whole proteins fostered new approaches to basic studies of the immune system as well as new methods of immunodiagnosis and immunotherapy. This was especially true following the introduction of monoclonal antibodies, which enhanced the specificity of many of these applications. The uses to which these labeled immunoreagents were put were legion, and those who employed them might come from any field of biology or medicine. Many of these technical elaborations were critical to progress in immunology and in many other biomedical sciences. They illustrate also the often complex interplay between technology and theory.

Tannic acid in histology: an historical perspective

The development of tannic acid as a reagent in histological methods is traced against a background of widespread use in science and technology from times of antiquity. Numerous light microscopic methods involving tannic acid, particularly in conjunction with iron and silver, have been described for a variety of tissue components. In most applications, tannic acid functions as a mordant. Current use is generally restricted to methods based on its affinity for collagen. The most significant histological use of tannic acid in contemporary times is as an adjunct to conventional glutaraldehyde-osmium-heavy metal fixation and staining for ultrastructural studies of tissue structures not normally clearly demonstrated. Tannic acid reacts with various components by mechanisms which are often not fully understood.

Imagining the brain cell: the neuron in visual culture

Images of the exquisitely formed apparatus of the nervous system have great potential to capture the imagination. However, the fascinating complexity and diversity of neuronal form has only rarely been celebrated in broader visual culture. We discuss how scientific and cultural practices at the time of the neuron's discovery generated a legacy of schematic and simplified popular neuronal imagery, which is only now being revised in the light of technological advances and a changing artistic climate.

Histological reassessment of three kidneys originally described by Richard Bright in 1827-36

Portions of kidney from three patients with renal disease that were originally described by Richard Bright between 1827 and 1836 have been preserved in the Gordon Museum at Guy's Hospital. Histological study has shown that two cases fall into the current diagnostic category of mesangiocapillary (membranoproliferative) glomerulonephritis. One of these patients had a five-year clinical history and died with chronic renal failure and uraemia. The other patient died after three to four months with a severe nephrotic syndrome. The third patient was a young woman with chronic "phthisis pulmonalis" and renal amyloidosis.

Making the brain plastic: early neuroanatomical staining techniques and the pursuit of structural plasticity, 1910-1970

The concept of neuronal plasticity is widely used, but seldom defined in the neurosciences. It can signify many different occurrences, such as structural alterations of axons and dendrites (Cotman & Nadler, 1978), behavioural adaptations (Rosenzweig & Bennett, 1996), or physiological changes in synapse formation (Martin et al., 2000) at different stages of health and disease. Although there is such a wealth of research from many disciplines, the neuroanatomical aspects of plasticity are the focus of this paper. It seeks to illuminate the evolution of different concepts of plasticity concerning the structure and circuitry of the central nervous system (CNS). Early modern morphological research on de- and regeneration phenomena in the 19th- and early 20th-century is well documented. These studies, however, almost exclusively concentrated on the peripheral nervous system (PNS). It was one of the major contributions of Santiago Ramón y Cajal (1852-1934), that he applied the concept of regenerative capacities to the CNS. But the term plasticity seemed to have disappeared for about two decades after his death. The ensuing comeback of the expression may be attributed, at least in part, to new neuroanatomical staining and tracing methods. The pursuit of these techniques will serve as a guidepost through varying approaches in different times: It was the 1950s which seemed to spawn the time for new departures in structural investigations of neuronal plasticity.