The Feulgen reaction: from pink-magenta to rainbow fluorescent at the Maffo Vialli's School of Histochemistry.

For over a century, Palazzo Botta (Palace Botta) has housed the University of Pavia's Biomedical Institutes. Illustrious scientists have conducted research and taught at this Palace, making significant contributions to the advancement of natural, biological, and medical science. Among them, Camillo Golgi received the Nobel Prize for discovering the so-called "black reaction." Following Golgi, the Palace continued to be a hub for the development of methodologies and reactions aimed at detecting and quantifying biological components. Maffo Vialli (in the Golgi stream) was the first to establish a Histochemistry Research Group, which began in the naturalistic field and later expanded to the biomedical area. Among the many histochemical studies initiated in the Palace, the Feulgen reaction undoubtedly played a significant role. This reaction, developed R. Feulgen and H. Rossenbeck in 1924, had significant international implications: numerous researchers then contributed to define its fine chemical details, which remained the subject of study for years, resulting in a massive international scientific literature. The Pavia School of Histochemistry also contributed to the evolution and application of this method, which has become a true benchmark in quantitative histochemistry. Giovanni Prenna and the CNR Centre for Histochemistry made significant contributions, as they were already focused on fluorescence cytochemistry. The Pavia researchers made significant contributions to the development of methodology and, in particular, instrumentation; the evolution of the latter resulted in the emergence of flow cytometry and an ever-increasing family of fluorescent probes, which somewhat overshadowed the Feulgen reaction for DNA quantification. The advent of monoclonal antibodies then contributed to the final explosion of flow cytometry in clinical application, almost making young neophytes forget that its roots date back to Feulgen.

Full-field hemocytometry. Forty years of progress seen through Clinical and Laboratory Hematology and the International Journal of Laboratory Hematology.

The extraordinary advances in clinical hematology, biology, and oncology in the last decades would not have been possible without discovering how to identify and count the cells circulating in the blood. For centuries, scientists have used slides, counting chambers (hemocytometers), and diluting and staining solutions for this task. Then, automated hemocytometry began. This science, now linked to the daily routine of laboratory hematology, has completed an overwhelming path over a few decades. Our laboratories today operate with versatile multiparameter systems, ranging from complex single-channel instruments to bulky continuous flow machines. In terms of clinical information obtained from a simple routine blood test, the full exploitation of their potential depends on the operators' imagination and courage. A comprehensive review of the scientific publications that have accompanied the development of hemocytometry from the 1950s to today would require entire volumes. More than seven hundred contributions that authors worldwide have published in Clinical and Laboratory Haematology until 2007 and then the International Journal of Laboratory Hematology are summarized. Such journals have represented and hopefully will continue to represent the privileged place of welcome for future scientific research in hemocytometry. Improved technologies, attention to quality, new reagents and electronics, information technology, and scientist talent ensure a more profound and deeper knowledge of cell properties: current laboratory devices measure and count even minor immature or pathological cell subpopulations. Full-field hemocytometry includes the analysis of nonhematic fluids, digital adds to the microscope, and the development of effective point-of-care devices.

Twenty years of histochemistry in the third millennium, browsing the scientific literature.

Over the last twenty years, about 240,000 articles where histochemical techniques were used have been published in indexed journals, and their yearly number has progressively increased. The histochemical approach was selected by researchers with very different scientific interests, as the journals in which these articles were published fall within 140 subject categories. The relative proportion of articles in some of these journal categories did change over the years, and browsing the table of contents of the European Journal of Histochemistry, as an example of a strictly histochemical journal, it appeared that in recent years histochemical techniques were preferentially used to mechanistically investigate natural or experimentally induced dynamic processes, with reduced attention to purely descriptive works. It may be foreseen that, in the future, histochemistry will be increasingly focused on studying the molecular pathways responsible for cell differentiation, the maintenance or loss of the differentiated state, and tissue regeneration.

Diagnostic histochemistry: A historical perspective.

Histochemistry has a history which, in some ways, goes back to ancient times. The desire for humans to understand the workings of their bodies, and the roles that various chemicals have in them, is long-standing. This review considers the evolution of histochemistry and cytochemistry as scientific disciplines, culminating in the pairing of those techniques with basic biochemistry. They have served as the bases for a synthesis of microscopy, chemistry, immunology, and molecular biology, particularly in the practice of anatomic pathology.

Alfred Pischinger (1899-1983): An Austrian career in anatomy continuing through National Socialism to postwar leadership.

Despite intensified research efforts on the history of anatomy during National Socialism (NS), many aspects of this story still need further investigation. This study explores the life, work and politics of Alfred Pischinger, Chairman of the Institute for Embryology and Histology in Graz from 1936 to 1945, and in Vienna from 1958 to 1970, and is an addition to previous reports on careers in anatomy continuing through the Third Reich to the postwar period. Pischinger was an illegal NSDAP member in Austria, joined the SA in 1938, served as expert in racial hygiene, and as judge on the Genetic Health High Court of Graz. His research focus was histochemistry, but he became part of a scientific network at the University of Graz, which from 1939 on experimented on the bodies of pregnant women and their fetuses under the leadership of gynecologist Karl Ehrhardt. The researchers were among the many who took actively part in the complete exploitation and physical destruction of those considered to be "the enemy" by the NS regime. After the war, Pischinger received publicity for his work on the "scientific basis" of alternative and holistic approaches of medicine. His NS past and fetal experiments seem to have vanished from public knowledge. As systematic studies of the influence of the NS period on postwar medical education and the science of anatomy itself are still missing, this critical investigation of Alfred Pischinger's life within the relevant historic background aims to contribute to this body of knowledge.

Fluorochromes for DNA Staining and Quantitation.

In these last few decades the great explosion of the molecular approaches has casted a little shadow on the DNA quantitative analysis. Nevertheless DNA cytochemistry represented a long piece of history in cell biology since the advent of the Feulgen reaction. This discovery was really the milestone of the emerging quantitative cytochemistry, and scientists from all over the world produced a very large literature on this subject. This first era of quantitation (histochemistry followed by cytochemistry) started by means of absorption measurements (histophotometry and cytophotometry). The successive introduction of fluorescence microscopy gave a great boost to quantitation, making easier and faster the determination of cell components by means of cytofluorometry. The development of flow cytometry further contributed to the importance of quantitative cytochemistry. At its beginning, the mission of flow cytometry was still DNA quantitation. For a decade the Feulgen reaction had been the reference methodology for both conventional and flow cytofluorometry; the advent of Shiff-type reagents contributed to expand the variety of possible fluorochromes excitable in the entire visible spectrum as well as in the ultraviolet region. The fluorescence scenario was progressively enriched by new probes among which are the intercalating dyes which made DNA quantitation simple and fast, thus spreading it worldwide. The final explosion of cytofluorometry was made possible by the availability of a large variety of probes directly binding DNA structure. In addition, immunofluorescence allowed to correlate the cell cycle-related DNA content to other cell markers. In the clinical application of flow cytometry, this promoted the introduction of multiparametric analyses aimed at describing the cytokinetic characteristics of a given cell subpopulation defined by a specific immunophenotype setting.

Methylene Blue: The Long and Winding Road from Stain to Brain: Part 1.

Methylene blue, first discovered and used as a dye in the textile industry, has long been used for biological staining in histology, bacteriology, and hematology. Because of its unique physiochemical properties, it was the first synthetic drug used in medicine, having been used to treat malaria more than one century ago. Methylene blue was also one of the first drugs used for the treatment of patients with psychosis at the end of the 19th century and was the lead drug in the serendipitous development of phenothiazine antipsychotic drugs in the mid-20th century. It was studied in bipolar disorder in the 1980s and has been investigated in neurodegenerative disorders in recent years. The history of methylene blue from its discovery as a dye to its use as a stain and then its therapeutic application in medicine is an example of how a drug's use can evolve over time through careful observation, clinical needs, serendipity, and the integration of concepts from different disciplines. [Journal of Psychosocial Nursing and Mental Health Services, 54(9), 21-24.].

The Histochemistry and Cell Biology omnium-gatherum: the year 2015 in review.

We provide here our annual review/synopsis of all of the articles published in Histochemistry and Cell Biology (HCB) for the preceding year. In 2015, HCB published 102 articles, representing a wide variety of topics and methodologies. For ease of access to these differing topics, we have created categories, as determined by the types of articles presented to provide a quick index representing the general areas covered. This year, these categories include: (1) advances in methodologies; (2) molecules in health and disease; (3) organelles, subcellular structures, and compartments; (4) the nucleus; (5) stem cells and tissue engineering; (6) cell cultures: properties and capabilities; (7) connective tissues and extracellular matrix; (8) developmental biology; (9) nervous system; (10) musculoskeletal system; (11) respiratory and cardiovascular system; (12) liver and gastrointestinal tract; and (13) male and female reproductive systems. Of note, the categories proceed from methods development, to molecules, intracellular compartments, stem cells and cell culture, extracellular matrix, developmental biology, and finishing with various organ systems, hopefully presenting a logical journey from methods to organismal molecules, cells, and whole tissue systems.

Early attempts to visualize cortical monoamine nerve terminals.

The Falck-Hillarp, formaldehyde fluorescence method for the demonstration of monoamine neurons in a microscope was established in Lund, Sweden and published in 1962. In the same year Hillarp moved to Karolinska Institutet in Stockholm. Two years later Dahlström and Fuxe published the famous supplement in Acta Physiologica Scandinavica, describing the distribution of the dopamine, noradrenaline and serotonin cell groups in the rat brain. This landmark paper also represented an important contribution to an emerging discipline in neuroscience - chemical neuroanatomy. During the following years several modifications of the original method were developed, attempting to solve some shortcomings, one being the reproducible demonstration of noradrenaline nerve terminals in cortical regions. One result was the paper focused on in the present article, which also describes other efforts in the same direction going on in parallel, primarily, in Lund and Stockholm. As a result there was, in the mid 1970s, a fairly complete knowledge of the catecholamine systems in the rat brain. This article is part of a Special Issue entitled SI:50th Anniversary Issue.

[Cytochemical localization and properties of selected nucleolytic enzymes]. / Cytochemiczna lokalizacja i wlasciwosci wybranych enzymów nukleolitycznych.

In the article there are shortly outlined studies on cytochemical localization of selected nucleolytic enzymes carried out between 1957-1986 by David Shugar and his coworkers. The histochemical localization of several nucleolytic enzymes in animal and plant tissues was determined by synthesis of specific substrates, alpha-naphthyl esters of 5'- and 3'-nucleotides and their derivatives. In rat tissues phosphodiesterase I was localized in the plasma membrane whereas phosphodiesterase II in the lizosomes, reflecting their physiological roles. The localization of pancreatic type ribonuclease in animal tissues was determined, indicating its role in extracellular digestion. Plant nucleotide pyrophosphatase was localized in several tissues, purified to near homogeneity from potato tubers and its properties and substrate specificity were determined. Application of this enzyme for removal of m7GMP from the "cap" of eukaryotic mRNA allowed to elucidate the role of "cap" in mRNA binding to ribosomes in the process of translation. Furthermore, cyclic nucleotide phosphodiesterase was isolated from potato tubers and its physicochemical properties, oligomeric structure and substrate specificity were elucidated.

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.

Twenty-five years of RENHIS: a history of histopathological studies within EUVAS.

In the early 1990s, an international working group of experienced renal pathologists, the Renal Histology group, set up a scoring system for biopsies with anti-neutrophil cytoplasmic autoantibody (ANCA)-associated glomerulonephritis. This scoring system subdivided glomerular, interstitial and vascular lesions and served as a tool for the evaluation of all renal biopsies from studies of the European Vasculitis Study Group (EUVAS). Histopathological studies gave new insights into the prediction of renal outcome in patients with ANCA-associated glomerulonephritis. Percentage of normal glomeruli and a selected number of interstitial parameters were reliable predictors of long-term follow-up glomerular filtration rate in all studies. Out of these results, a histopathological classification distinguishing focal, crescentic, mixed and sclerotic classes of ANCA-associated glomerulonephritis was developed. Until today, 13 studies have validated this classification system. Future studies will try to determine if and how renal histology could be helpful in guiding treatment of ANCA-associated glomerulonephritis.

The contribution of Paul Ehrlich to histochemistry: a tribute on the occasion of the centenary of his death.

Paul Ehrlich is the founder of a number of areas in biomedical research: in the first line, immunology and chemotherapy. Aim of this historical note to the centenary of Paul Ehrlich's death is to commemorate his tribute to the establishment and development of histochemistry.

Human population studies and the World Health Organization

This essay draws attention to the role of the WHO in shaping research agendas in the biomedical sciences in the postwar era. It considers in particular the genetic studies of human populations that were pursued under the aegis of the WHO from the late 1950s to 1970s. The study provides insights into how human and medical genetics entered the agenda of the WHO. At the same time, the population studies become a focus for tracking changing notions of international relations, cooperation, and development and their impact on research in biology and medicine in the post-World War II era. After a brief discussion of the early history of the WHO and its position in Cold War politics, the essay considers the WHO program in radiation protection and heredity and how the genetic study of «vanishing» human populations and a world-wide genetic study of newborns fitted this broader agenda. It then considers in more detail the kind of support offered by the WHO for these projects. The essay highlights the role of single individuals in taking advantage of WHO support for pushing their research agendas while establishing a trend towards cooperative international projects in biology (AU)

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C and APUD cells and endocrine tumours. Pearse's laboratory in the years 1965-1969: a personal recollection.

This paper is a personal recollection of the studies, conducted in Prof. Pearse's laboratory in London in the years 1965-1969, which led to the discovery of production of calcitonin by parafollicular C cells and medullary carcinomas of the thyroid. The author's intention is to underline the combination of technical excellence, brilliant intuition, dedication and serendipity which led to a series of major discoveries and, historically, established the pivotal role to be played by immunohistochemistry in endocrine research and diagnosis. The formulation of Pearse's APUD cell theory gave a formal credence to the existence of common endocrine mechanisms, molecular markers and structural features in dispersed cells, all belonging to a diffuse endocrine system. This represented a major breakthrough which primed, in the following years, the studies on polypeptide hormone-producing cells and tumours, thus paving the way to the endocrine histology and pathology as we know, and practice them today.

Histochemistry: historical development and current use in pathology.

We describe the history of the histochemical stains that contributed most to the development of modern pathology during the last two centuries. Histochemical stains are presented in a list, which provides the essential information about year, country and main use of each to enable the reader to follow the chronological and geographical history of histochemistry. In addition to the historical evaluation of histochemistry development, we investigate how many classical histochemical stains survive in a modern laboratory of pathology and how often they are used for diagnostic practice compared to immunohistochemical (IHC) techniques. A ratio of about one histochemical reaction to 13 IHC reactions was tabulated. Finally, our data make it possible to define different cultural approaches to the terminology of histochemical and IHC stains: the former were based on eponyms, which link the stain with the name of its inventor, while the latter use a more impersonal biological terminology.