Physiological Reports 10th anniversary year: Looking to the future.

Physiological Reports 10th anniversary year banner image.

Tribute to Roger Guillemin, a pioneer in neuroendocrinology (1924-2024), Nobel Prize in Physiology or Medicine.

Roger Guillemin discovered and characterized the hypothalamic factors that control anterior pituitary functions. He consequently demonstrated that these brain peptides regulate a large number of major body activities through neuroendocrine mechanisms. This especially include growth, fertility and reproduction, endocrine gland functions and stress. These seminal works paved the way to major applications in many fields of physiology and medicine for diagnosis, pharmacology and therapy, far beyond the initial discovery and properties of these molecules, including in cancerology, immunology, inflammation, drug addiction and behavior.

Roger Guillemin a mis en évidence et caractérisé les facteurs hypothalamiques qui contrôlent les fonctions de l'adénohypophyse. Cette découverte majeure a permis de démontrer que ces peptides du cerveau régulent par voie neuroendocrine un grand nombre de fonctions importantes de l'organisme. C'est le cas de la croissance, de la fertilité et de la reproduction, des fonctions des glandes endocriniennes et du stress. Ces travaux pionniers ont ouvert la voie à des applications innovantes dans de nombreux domaines de la physiologie et de la médecine pour le diagnostic, la pharmacologie et la thérapie, bien au-delà de la découverte initiale et des propriétés de ces molécules. Ces domaines comprennent en particulier la cancérologie, l'immunologie, les problèmes inflammatoires, les addictions et le comportement.

A lesson for us all: the Hodgkin-Keynes long pore model of ion flux.

In this article we analyze the classic Hodgkin and Keynes 1955 paper describing investigations of the independence principle, with the expectation that there is much students and educators can learn from such exercises, most notably how the authors applied their diverse skill set to tackling the numerous obstacles that the study presented. The paper encompasses three of the physiology core concepts, cell membranes, flow down gradients, and scientific reasoning, which were recently assigned to the classes The Biological World, The Physical World, and Ways of Looking at the World, respectively. Thus, analysis of such a paper illuminates the relationships that exist between distinct concepts and encourages a holistic approach to understanding physiology. In-depth analysis of the paper allows us to follow the authors' thought processes from their realization that previous methods lacked the resolution to answer a fundamental question relating to ion movement across membranes to the application of a more sensitive technique and ultimately the development of a novel model describing ion flux. This paper was the culmination of work started in the mid-1930s, strongly supported the ionic theory of nervous conduction proposed by Hodgkin and Huxley, and predicted the presence of ion channels as narrow pores through which ions move sequentially four decades before these features were convincingly demonstrated.NEW & NOTEWORTHY We describe in detail Hodgkin and Keynes' investigation of the independence principle. It is our expectation that students and educators can benefit from following the thought processes applied by the authors as they navigated the complexities of experimental design and data analysis, culminating in development of a model whose elegant simplicity was convincing evidence of narrow membrane-bound pores, ion channels, that were the conduit for transmembrane ion movement.

A life dedicated to research and ideal: Johannes Müller between empirical universality and idealistic vitalism mirrored in lecture notes from 1851.

Until the mid-nineteenth century, "physiology" was a comprehensive theory of life, expounded and shaped by Johannes P. Müller (1801-1858). Biologists and medical doctors still refer to him today. In the summer term of 1851, Müller gave a lecture on the Comparative Anatomy of animals. This lecture was attended and recorded by Ernst Zeller (1830-1902), a future physician and zoologist, and has recently been published together with a German transcript. In this paper, we situate Johannes Müller within the intellectual history of his time. Through his "empirical idealism," we show how he opposed the speculative tendencies of the romantic understanding of nature, the emerging evolutionism, and the growing splits in the natural sciences. Müller focused on recognizing living nature as a whole and realizing ideal "phenomena" through his empirical research. He considered the notion of the soul of the world. Müller's lecture transcript serves as a poignant testament to German scientific culture in the mid-nineteenth century, a few years before the publication of Darwin's Origin of Species. It also provides valuable insights into the self-contained epistemological foundations of morphology.

The Elementary Organisms.

In 1861 the physiologist Ernst Brücke (1819-1892) published "The Elementary Organisms," calling for a major reform of the definition of the animal cell. An English translation of Brücke's essay is presented here for the first time. In this translation the numbered footnotes 1-9 are Brücke's own; alphabetical endnotes A-HH are my own annotations, with additional references to works cited by Brücke. Figures referenced by Brücke but not included in his original essay are also provided. I have also presented an introductory essay to my translation that provides background on Brücke and his arguments: "The Schema and Organization of the Cell," https://doi.org/10.1007/s10739-024-09774-8 , in this same issue of the Journal of the History of Biology.

Contributions of Griffith Pugh to Success on Mt. Everest and His Impact on the Advancement of Altitude and Environmental Physiology.

Griffith Pugh, MD (1909-1994), was a pioneer in altitude physiology. During World War II, he developed training protocols in Lebanon to improve soldier performance at altitude and in the cold. In 1951 he was chosen to join the British Everest team as a scientist. In preparation, he developed strategies for success on a training expedition on Cho Oyu in 1952. Results from Cho Oyu led to the use of supplemental oxygen at higher flow rates during ascent than used previously (4 L/min vs 2 L/min) and continued use (at a reduced rate of 2 L/min) during descent, enabling increased performance and improved mental acuity. Oxygen was also used during sleep, leading to improved sleep and warmth. Adequate hydration (∼3 L/day) was also stressed, and a more appealing diet led to improved nutrition and condition of the climbers. Improved hygiene practices and acclimatization protocols were also developed. These strategies contributed to the first successful summiting of Mount Everest in 1953. Pugh was then appointed as the lead scientist for a ground-breaking eight-and-a-half-month research expedition where the team was the first to overwinter at high altitude (5800 m) in the Himalayas. This current work summarizes Pugh's scientific contributions as they relate to success on Mount Everest and in inspiring future altitude research by generations of successful researchers.

[Dr. Valentin Grandis and Dr. Virgilio Ducceschi, two italian masters who initiated Experimental Physiology at the Faculty of Medical Sciences - Universidad Nacional De Cordoba (Argentina)] / Dr. Valentin Grandis y Dr. Virgilio Ducceschi, Dos maestros italianos iniciadores de la Fisiología experimental en la Facultad de Ciencias Médicas - UNC.

This paper examines the significant contribution of Dr. Valentín Grandis and Dr. Virgilio Ducceschi to the founding and development of experimental physiology at the Faculty of Medical Sciences of the National University of Córdoba (UNC), Argentina. Although the most notable contribution to the field of experimental physiology in Argentina is attributed to Bernardo Alberto Houssay, this study highlights the importance of the previous and fundamental efforts of Grandis and Ducceschi, two Italian professors whose work in Buenos Aires and Córdoba laid the foundations for research and teaching in this discipline. The paper details how, in 1904, the arrival of Valentin Grandis at the UNC marked the formal beginning of the teaching and practice of experimental physiology at the institution, followed by the incorporation of Virgilio Ducceschi, who continued and expanded Grandis' legacy. The work of these two Italian masters involved not only the installation of a state-of-the-art laboratory but also the establishment of a solid academic and scientific foundation that would influence future generations of Argentine physicians and researchers. Through a detailed analysis of their biographies, scientific contributions, and the impact of their work, this paper illustrates how Grandis and Ducceschi were key figures in the development of medical science in Argentina, particularly in the field of experimental physiology. Furthermore, the study highlights the importance of their educational approach and their ability to train disciples who would continue their research, thus ensuring the permanence of their legacy at the National University of Córdoba and in Argentine science in general. In conclusion, this paper vindicates and celebrates the contributions of Valentín Grandis and Virgilio Ducceschi to the initiation of research and experimentation in physiology and biological chemistry at the UNC, highlighting their importance in the advancement of medicine and science in Argentina.

Este trabajo examina el significativo aporte de los doctores Valentín Grandis y Virgilio Ducceschi a la fundación y desarrollo de la fisiología experimental en la Facultad de Ciencias Médicas de la Universidad Nacional de Córdoba (UNC), Argentina. A pesar de que la contribución más notable en el campo de la fisiología experimental en Argentina se atribuye a Bernardo Alberto Houssay, este estudio destaca la importancia de los esfuerzos previos y fundamentales de Grandis y Ducceschi, dos profesores italianos cuyo trabajo en Buenos Aires y Córdoba sentó las bases para la investigación y la enseñanza de esta disciplina.   El trabajo detalla cómo, en 1904, la llegada de Valentín Grandis a la UNC marcó el inicio formal de la enseñanza y práctica de la fisiología experimental en la institución, seguida por la incorporación de Virgilio Ducceschi, quien continuó y expandió el legado de Grandis. La labor de estos dos maestros italianos no solo involucró la instalación de un laboratorio de vanguardia sino también el establecimiento de una sólida base académica y científica que influiría en generaciones futuras de médicos e investigadores argentinos.   A través de un análisis detallado de sus biografías, contribuciones científicas, y el impacto de su trabajo, este documento ilustra cómo Grandis y Ducceschi fueron figuras clave en el desarrollo de la ciencia médica en Argentina, particularmente en el ámbito de la fisiología experimental. Además, el estudio resalta la importancia de su enfoque educativo y su capacidad para formar discípulos que continuarían sus investigaciones, asegurando así la permanencia de su legado en la Universidad Nacional de Córdoba y en la ciencia argentina en general.   En conclusión, el presente trabajo reivindica y celebra las contribuciones de Valentín Grandis y Virgilio Ducceschi al inicio de la investigación y experimentación en fisiología y química biológica en la UNC, subrayando su importancia en el avance de la medicina y la ciencia en Argentina.

[About the first publication of I.M. Sechenov. (To the 195th anniversary of his birth)]. / O pervoi publikatsii I.M. Sechenova. (K 195-letiyu so dnya rozhdeniya).

Ivan Mikhailovich Sechenov is a Russian physiologist, a natural scientist, and the creator of the Russian physiological school. The classic work «Reflexes of the Brain¼, published in 1863, became revolutionary in its own way for medicine and society, since the reflex nature of conscious and unconscious activity was proved. Along with numerous well-known scientific works, there is an early student publication in the Moscow Medical Journal published by A. I. Polunin. It describes the medical history of a patient with a tumor who was unsuccessfully treated for a long time in accordance with the humoral theory of pathology. This publication makes it possible to understand why I. M. Sechenov became disillusioned with practical medicine, but found his vocation in the study of physiology. The article is devoted to the 195th anniversary of the birth of I. M. Sechenov.

[The experimental physiologist Carl Ludwig (1816-1895): Scientific genius - modest, selfless, unswerving!] / Der Experimentalphysiologe Carl Ludwig (1816­1895): Wissenschaftlicher Genius ­ uneitel, selbstlos, unbeirrbar!

Carl Ludwig was, besides Johannes Müller, one of the most prolific natural scientists of the 19th century. Carl Ludwig believed that the function of organs can be ascribed to the laws of physics and chemistry and that only through repeatable physiological experiments can hypotheses be verified. Ludwig has laid the technological foundations for experimental physiology. The "kymographion", (waves-recorder), the "stromuhr" and the blood gas pump are some of his developments that underline this fact. Together with his students he performed fundamental experiments to gain better understanding of renal physiology and pulmonary physiology, cardiovascular circulatory and innervation, as well as glandular secretion and the lymphatic system. For decades, Ludwig's two-volume textbook on the human physiology was standard work in scientific and experimental physiology. Many young scientists from all over the world ventured to Leipzig to be taught experimental physiology by Ludwig.

Sixty Years of Heart Research in the Institute of Physiology of the Czech Academy of Sciences.

In 2023, six decades have elapsed since the first experimental work on the heart muscle was published, in which a member of the Institute of Physiology of the Czech Academy of Sciences participated as an author; Professor Otakar Poupa was the founder and protagonist of this research domain. Sixty years - more than half of the century - is certainly significant enough anniversary that is worth looking back and reflecting on what was achieved during sometimes very complicated periods of life. It represents the history of an entire generation of experimental cardiologists; it is possible to learn from its successes and mistakes. The objective of this review is to succinctly illuminate the scientific trajectory of an experimental cardiological department over a 60-year span, from its inaugural publication to the present. The old truth - historia magistra vitae - is still valid. Keywords: Heart, Adaptation, Development, Hypoxia, Protection.

Aspectos de la vida y obra del Dr. Bernardo Alberto Houssay / Aspects of the life and work of Dr. Bernardo Alberto Houssay

Con motivo del Día Mundial de la Ciencia y la Tecnología, se realizó en la Casa Museo Bernardo Houssay un conversatorio en el que expertos biógrafos resaltaron algunos aspectos de la trayectoria profesional del Premio Nobel de Medicina de 1947, destacando su actividad como investigador en fisiología y sus cualidades humanas. Estos importantes estudiosos del tema compartieron sus conocimientos en un selecto auditorio. (AU)

On the occasion of World Science and Technology Day, a discussion was held at the Bernardo Houssay House Museum in which expert biographers highlighted some aspects of the professional career of the 1947 Nobel Prize in Medicine, highlighting his activity as a researcher in physiology and his human qualities. These important scholars of the subject shared their knowledge in a select audience. (AU)

A century of exercise physiology: key concepts in neural control of the circulation.

Early in the twentieth century, Walter B. Cannon (1871-1945) introduced his overarching hypothesis of "homeostasis" (Cannon 1932)-the ability to sustain physiological values within a narrow range necessary for life during periods of stress. Physical exercise represents a stress in which motor, respiratory and cardiovascular systems must be integrated across a range of metabolic stress to match oxygen delivery to oxygen need at the cellular level, together with appropriate thermoregulatory control, blood pressure adjustments and energy provision. Of these, blood pressure regulation is a complex but controlled variable, being the function of cardiac output and vascular resistance (or conductance). Key in understanding blood pressure control during exercise is the coordinating role of the autonomic nervous system. A long history outlines the development of these concepts and how they are integrated within the exercise context. This review focuses on the renaissance observations and thinking generated in the first three decades of the twentieth century that opened the doorway to new concepts of inquiry in cardiovascular regulation during exercise. The concepts addressed here include the following: (1) exercise and blood pressure, (2) central command, (3) neurovascular transduction with emphasis on the sympathetic nerve activity and the vascular end organ response, and (4) tonic neurovascular integration.

Ferid Murad (1936-2023).

Physician-scientist who discovered NO signaling.