Asunto(s)
Aniversarios y Eventos Especiales , Sociedades Médicas , Humanos , Sociedades Médicas/historia , Historia del Siglo XXI , Historia del Siglo XX , Cardiología/historia , Difusión de Innovaciones , Publicaciones Periódicas como Asunto/historia , Valor Predictivo de las Pruebas , Enfermedades Cardiovasculares/historiaAsunto(s)
Cardiología , Historia del Siglo XX , Historia del Siglo XXI , Humanos , Cardiología/historiaRESUMEN
Whereas medical practice stems from Hippocrates, cardiovascular science originates with Aristotle. The Hippocratic philosophy was championed by Galen (129-216 CE), whose advocacy of a tripartite soul found favor in the early Christian Church. In contrast, Aristotle's works were banned as heresy by ecclesiastical authority, only to survive and prosper in the Islamic Golden Age (775-1258 CE). Galen theorized that the circulation consisted of separate venous and arterial systems. Blood was produced in the liver and traveled centrifugally through veins. When arriving in the right ventricle, venous blood passed through tiny pores in the ventricular septum into the left ventricle, where it became aerated by air passing from the lungs through the pulmonary veins to the left side of the heart. Following arrival at distal sites, arterial blood disappeared, being consumed by the tissues, requiring that the liver needed to continually synthesize new blood. The heart was viewed as a sucking organ, and the peripheral pulse was deemed to result from changes in arterial tone, rather than cardiac systole. Galen's framework remained undisputed and dominated medical thought for 1,300 years, but the reintroduction of Aristotelian principles from the Islamic world into Europe (through the efforts of the Toledo School of Translators) were nurtured by the academic freedom and iconoclastic environment uniquely cultivated at the University of Padua, made possible by Venetian rebellion against papal authority. At Padua, the work of Andreas Vesalius, Realdo Colombo, Hieronymus Fabricius ab Acquapendente, and William Harvey (1543-1628) methodically destroyed Galen's model, leading to the modern concept of a closed-ended circulation. Yet, due to political forces, Harvey was ridiculed, as was James Lind, who performed the first prospective controlled trial, involving citrus fruits for scurvy (1747); it took nearly 50 years for his work to be accepted. Even the work of William Withering (1785), the father of cardiovascular pharmacology, was tarnished by professional jealously and the marketing campaign of a pharmaceutical company. Today's cardiovascular investigators should understand that major advances are routinely derided by the medical establishment for political or personal reasons; and it may take decades or centuries for important work to be accepted.
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Cardiología , Humanos , Cardiología/historia , Historia Antigua , Historia Medieval , Médicos/historia , Historia del Siglo XVII , Investigación Biomédica/historia , Historia del Siglo XVIAsunto(s)
Cardiología , Humanos , Cardiología/historia , Cardiología/tendencias , Medicina Nuclear/historia , Medicina Nuclear/tendencias , Historia del Siglo XXI , Predicción , Historia del Siglo XX , Enfermedades Cardiovasculares/diagnóstico por imagen , Enfermedades Cardiovasculares/terapia , Valor Predictivo de las Pruebas , Imagen de Perfusión Miocárdica/métodosRESUMEN
Following new concepts by Bichat in the early 19th century, of organic and animal life centered around the ganglionic nervous system, over 100 years of anatomic studies and physiologic experimentation eventually resulted in Gaskell's 1916 book entitled "The Involuntary Nervous System" and Langley's 1921 book entitled "The Autonomic Nervous System." Neurology and cardiology emerged as specialties of medicine in the early 20th century. Although neurology made several prominent discoveries in neurophysiology during the first half of the 20th century, cardiology developed coronary care units and cardiac catheterization in the 1960s. Programmed electrical stimulation of the heart and noninvasive ambulatory monitoring provided new methodologies to study clinical cardiac arrhythmias. Experimentally, direct cardiac nerve stimulation of sympathetic nerve endings, as well as parasympathetic control of the atrioventricular node, provided the background to new detailed autonomic studies of the heart. Neurocardiology, perhaps initially more directed towards our understanding of sudden cardiac death, ultimately embraced an even significantly more complex scheme of local circuit neurons and near-endless loops of interconnecting neurons in the heart. Intrathoracic extracardiac and intracardiac ganglia have been recharacterized, both anatomically and physiologically, laying the groundwork for potential new therapies of cardiac neuromodulation.
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Sistema Nervioso Autónomo , Cardiología , Sistema Nervioso Autónomo/fisiopatología , Humanos , Historia del Siglo XX , Cardiología/historia , Historia del Siglo XIX , Animales , Neurología/historia , Historia del Siglo XXI , Corazón/inervaciónAsunto(s)
Cardiología , Humanos , Historia del Siglo XX , Historia del Siglo XXI , Cardiología/historiaRESUMEN
Gated radionuclide angiography and myocardial perfusion imaging were developed in the United States and Europe in the 1970's and soon adopted in Canadian centers. Much of the early development of nuclear cardiology in Canada was in Toronto, Ontario and was quickly followed by new programs across the country. Clinical research in Canada contributed to the further development of nuclear cardiology and cardiac PET. The Canadian Nuclear Cardiology Society (CNCS) was formed in 1995 and became the Canadian Society of Cardiovascular Nuclear and CT Imaging (CNCT) in 2014. The CNCS had a major role in education and advocacy for cardiovascular nuclear medicine testing. The CNCS established the Dr Robert Burns Lecture and CNCT named the Canadian Society of Cardiovascular Nuclear and CT Imaging Annual Achievement Award for Dr Michael Freeman in memoriam of these two outstanding Canadian leaders in nuclear cardiology. The future of nuclear cardiology in Canada is exciting with the expanding use of SPECT imaging to include Tc-99m-pyrophosphate for diagnosis of transthyretin cardiac amyloidosis and the ongoing introduction of cardiac PET imaging.
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Cardiología , Medicina Nuclear , Tomografía de Emisión de Positrones , Humanos , Canadá , Medicina Nuclear/historia , Historia del Siglo XX , Cardiología/historia , Historia del Siglo XXI , Sociedades Médicas , Imagen de Perfusión MiocárdicaRESUMEN
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.