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Pulmonary circulation

November 13, 2023

The pulmonary circulation is a division of the circulatory system in all vertebrates. The circuit begins with deoxygenated blood returned from the body to the right atrium of the heart where it is pumped out from the right ventricle to the lungs. In the lungs the blood is oxygenated and returned to the left atrium to complete the circuit.[1]

Pulmonary circulation
Pulmonary circulation in the heart
Details
SystemCirculatory system
Identifiers
MeSHD011652
Anatomical terminology
[edit on Wikidata]

The other division of the circulatory system is the systemic circulation that begins with receiving the oxygenated blood from the pulmonary circulation into the left atrium. From the atrium the oxygenated blood enters the left ventricle where it is pumped out to the rest of the body, returning as deoxygenated blood back to the pulmonary circulation.

The blood vessels of the pulmonary circulation are the pulmonary arteries and the pulmonary veins.

A separate circulatory circuit known as the bronchial circulation supplies oxygenated blood to the tissue of the larger airways of the lung.

Structure edit

 
3D rendering of a high resolution computed tomography of the thorax. The anterior thoracic wall, the airways and the pulmonary vessels anterior to the root of the lung have been digitally removed in order to visualize the different levels of the pulmonary circulation.
 
Image showing main pulmonary artery coursing ventrally to the aortic root and trachea. The right pulmonary artery passes dorsally to the ascending aorta, while the left pulmonary artery passes ventrally to the descending aorta.

De-oxygenated blood leaves the heart, goes to the lungs, and then enters back into the heart.[2] De-oxygenated blood leaves through the right ventricle through the pulmonary artery.[2] From the right atrium, the blood is pumped through the tricuspid valve (or right atrioventricular valve) into the right ventricle. Blood is then pumped from the right ventricle through the pulmonary valve and into the pulmonary artery.[2]

Lungs edit

The pulmonary arteries carry deoxygenated blood to the lungs, where carbon dioxide is released and oxygen is picked up during respiration.[3] Arteries are further divided into very fine capillaries which are extremely thin-walled.[4] The pulmonary veins return oxygenated blood to the left atrium of the heart.[3]

Veins edit

Main article: Pulmonary vein

Oxygenated blood leaves the lungs through pulmonary veins, which return it to the left part of the heart, completing the pulmonary cycle.[3][5] This blood then enters the left atrium, which pumps it through the mitral valve into the left ventricle.[3][5] From the left ventricle, the blood passes through the aortic valve to the aorta.[3][5] The blood is then distributed to the body through the systemic circulation before returning again to the pulmonary circulation.[3][5]

Arteries edit

Main article: Pulmonary artery

From the right ventricle, blood is pumped through the semilunar pulmonary valve into the left and right main pulmonary artery (one for each lung), which branch into smaller pulmonary arteries that spread throughout the lungs.[3][5]

Development edit

The pulmonary circulation loop is virtually bypassed in fetal circulation.[6] The fetal lungs are collapsed, and blood passes from the right atrium directly into the left atrium through the foramen ovale (an open conduit between the paired atria) or through the ductus arteriosus (a shunt between the pulmonary artery and the aorta).[6]

When the lungs expand at birth, the pulmonary pressure drops and blood is drawn from the right atrium into the right ventricle and through the pulmonary circuit. Over the course of several months, the foramen ovale closes, leaving a shallow depression known as the fossa ovalis.[6][7]

Clinical significance edit

A number of medical conditions may affect the pulmonary circulation:

History edit

 
The opening page of one of Ibn al-Nafis's medical works

The pulmonary circulation is archaically known as the "lesser circulation" which is still used in non-English literature.[13][14]

The discovery of the pulmonary circulation has been attributed to many scientists with credit distributed in varying ratios by varying sources. In much of modern medical literature, the discovery is credited to English physician William Harvey (1578 – 1657 CE) based on the comprehensive completeness and correctness of his model, despite its relative recency.[15][16] Other sources credit Greek philosopher Hippocrates (460 – 370 BCE), Spanish physician Michael Servetus (c. 1509 – 1553 CE), Arab physician Ibn al-Nafis (1213 – 1288 CE), and Syrian physician Qusta ibn Luqa.[17][18][19][20] Several figures such as Hippocrates and al-Nafis receive credit for accurately predicting or developing specific elements of the modern model of pulmonary circulation: Hippocrates[19] for being the first to describe pulmonary circulation as a discrete system separable from systemic circulation as a whole and al-Nafis[21] for making great strides over the understanding of those before him and towards a rigorous model. There is a great deal of subjectivity involved in deciding at which point a complex system is "discovered", as it is typically elucidated in piecemeal form so that the very first description, most complete or accurate description, and the most significant forward leaps in understanding are all considered acts of discovery of varying significance.[19]

Primitive descriptions of the cardiovascular system are found throughout several ancient cultures. The earliest known description of the role of air in circulation was produced in Egypt in 3500 BCE. At the time, the Egyptians believed that the heart was the origin of many channels that connected different parts of the body to each other and transported air – as well as urine, blood, and the soul – between them.[22] The Edwin Smith Papyrus (1700 BCE), named for American Egyptologist Edwin Smith (1822 – 1906 CE) who purchased the scroll in 1862, provided evidence that Egyptians believed that the heartbeat created a pulse that transported the above substances throughout the body.[23] A second scroll, the Ebers Papyrus (c. 1550 BCE), also emphasized the importance of the heart and its connection to vessels throughout the body and described methods to detect cardiac disease through pulse abnormalities. Although they had knowledge of the heartbeat, vessels, and pulse, the Egyptians attributed the movement of substances through the vessels to air that resided in these channels, rather than to the heart's exertion of pressure.[24] The Egyptians knew that air played an important role in circulation but did not yet have a conception of the role of the lungs.

The next addition to the historical understanding of pulmonary circulation arrived with the Ancient Greeks. Physician Alcmaeon (520 – 450 BCE) proposed that the brain, not the heart, was the connection point for all of the vessels in the body. He believed that the function of these vessels was to bring the "spirit" ("pneuma") and air to the brain.[22][25] Empedocles (492 – 432 BCE), a philosopher, proposed a series of pipes, impermeable to blood but continuous with blood vessels, that carried the pneuma throughout the body. He proposed that this spirit was internalized by pulmonary respiration.[22]

Hippocrates was the first to describe pulmonary circulation as a discrete system, separable from systemic circulation, in his Corpus Hippocraticum, which is often regarded as the foundational text of modern medicine.[19] Hippocrates developed the view that the liver and spleen produced blood, and that this traveled to the heart to be cooled by the lungs that surrounded it.[18] He described the heart as having two ventricles connected by an interventricular septum, and depicted the heart as the nexus point of all of the vessels of the body. He proposed that some vessels carried only blood and that others carried only air. He hypothesized that these air-carrying vessels were divisible into the pulmonary veins, which carried in air to the left ventricle, and the pulmonary artery, which carried in air to the right ventricle and blood to the lungs. He also proposed the existence of two atria of the heart functioning to capture air. He was one of the first to begin to accurately describe the anatomy of the heart and to describe the involvement of the lungs in circulation. His descriptions built substantially on previous and contemporaneous efforts but, by modern standards, his conceptions of pulmonary circulation and of the functions of the parts of the heart were still largely inaccurate.[22]

Greek philosopher and scientist Aristotle (384 – 322 BCE) followed Hippocrates and proposed that the heart had three ventricles, rather than two, that all connected to the lungs.[22] Greek physician Erasistratus (315 – 240 BCE) agreed with Hippocrates and Aristotle that the heart was the origin of all of the vessels in the body but proposed a system in which air was drawn into the lungs and traveled to the left ventricle via pulmonary veins. It was transformed there into the pneuma and distributed throughout the body by arteries, which contained only air.[23] In this system, veins distributed blood throughout the body, and thus blood did not circulate, but rather was consumed by the organs.[22]

The Greek physician Galen (129 – c. 210 CE) provided the next insights into pulmonary circulation. Though many of his theories, like those of his predecessors, were marginally or completely incorrect, his theory of pulmonary circulation dominated the medical community's understanding for hundreds of years after his death.[23] Galen contradicted Erasistratus before him by proposing that arteries carried both air and blood, rather than air alone (which was essentially correct, leaving aside that blood vessels carry constituents of air and not air itself).[18] He proposed that the liver was the originating point of all blood vessels. He also theorized that the heart was not a pumping muscle but rather an organ through which blood passed.[23] Galen's theory included a new description of pulmonary circulation: air was inhaled into the lungs where it became the pneuma. Pulmonary veins transmitted this pneuma to the left ventricle of the heart to cool the blood simultaneously arriving there. This mixture of pneuma, blood, and cooling produced the vital spirits that could then be transported throughout the body via arteries. Galen further proposed that the heat of the blood arriving in the heart produced noxious vapors that were expelled through the same pulmonary veins that first brought the pneuma.[26] He wrote that the right ventricle played a different role to the left: it transported blood to the lungs where the impurities were vented out so that clean blood could be distributed throughout the body. Though Galen's description of the anatomy of the heart was more complete than those of his predecessors, it included several mistakes. Most notably, Galen believed that blood flowed between the two ventricles of the heart through small, invisible pores in the interventricular septum.[22]

The next significant developments in the understanding of pulmonary circulation did not arrive until centuries later. Persian polymath Avicenna (c. 980 – 1037 CE) wrote a medical encyclopedia entitled The Canon of Medicine. In it, he translated and compiled contemporary medical knowledge and added some new information of his own.[21] However, Avicenna's description of pulmonary circulation reflected the incorrect views of Galen.[18]

The Arab physician, Ibn al-Nafis, wrote the Commentary on Anatomy in Avicenna's Canon in 1242 in which he provided possibly the first known description of the system that remains substantially congruent with modern understandings, in spite of its flaws. Ibn al-Nafis made two key improvements on Galen's ideas. First, he disproved the existence of the pores in the interventricular septum that Galen had believed allowed blood to flow between the left and right ventricles. Second, he surmised that the only way for blood to get from the right to the left ventricle in the absence of interventricular pores was a system like pulmonary circulation. He also described the anatomy of the lungs in clear and basically correct detail, which his predecessors had not.[21] However, like Aristotle and Galen, al-Nafis still believed in the quasi-mythical concept of vital spirit and that it was formed in the left ventricle from a mixture of blood and air. Despite the enormity of Ibn al-Nafis's improvements on the theories that preceded him, his commentary on The Canon was not widely known to Western scholars until the manuscript was discovered in Berlin, Germany, in 1924. As a result, the ongoing debate among Western scholars as to how credit for the discovery should be apportioned failed to include Ibn al-Nafis until, at earliest, the mid-20th century (shortly after which he came to enjoy a share of this credit).[18][21] In 2021, several researchers described a text predating the work of al-Nafis, fargh- beyn-roh va nafs, in which there is a comparable report on pulmonary circulation. The researchers argue that its author, Qusta ibn Luqa, is the best candidate for the discoverer of pulmonary circulation on a similar basis to arguments in favour of al-Nafis generally.[20]

It took centuries for other scientists and physicians to reach conclusions that were similar to and then more accurate than those of al-Nafis and ibn Luqa. This later progress, constituting the gap between medieval and modern understanding, occurred throughout Europe. Italian polymath Leonardo da Vinci (1452 – 1519 CE) was one of the first to propose that the heart was just a muscle, rather than a vessel of spirits and air, but he still subscribed to Galen's ideas of circulation and defended the existence of interventricular pores.[22] The Flemish physician Andreas Vesalius (1514 – 1564 CE) published corrections to Galen's view of circulatory anatomy, questioning the existence of interventricular pores, in his book De humani corporis fabrica libri septem in 1543.[26] Spanish Michael Servetus, after him, was the first European physician to accurately describe pulmonary circulation.[17] His assertions largely matched those of al-Nafis. In subsequent centuries, he has frequently been credited with the discovery, but some historians have propounded the idea that he potentially had access to Ibn al-Nafis's work while writing his own texts.[18] Servetus published his findings in Christianismi Restituto (1553): a theological work that was considered heretical by Catholics and Calvinists alike. As a result, both book and author were burned at the stake and only a few copies of his work survived.[18] Italian physician Realdo Colombo (c. 1515 – 1559 CE) published a book, De re anatomica libri XV, in 1559 that accurately described pulmonary circulation. It is still a matter of debate among historians as to whether Colombo reached his conclusions alone or based them to an unknown degree on the works of al-Nafis and Servetus.[18][22] Finally, in 1628, the influential British physician William Harvey (1578 – 1657 AD) provided at the time the most complete and accurate description of pulmonary circulation of any scholar worldwide in his treatise Exercitatio Anatomica de Motu Cordis et Sanguinis in Animalibus. At the macroscopic level, his model is still recognizable in and reconcilable with modern understandings of pulmonary circulation.[15]

References edit

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  8. ^ Anderson, Robert H.; Krishna, Kumar; Mussato, Kathleen A.; Redington, Andrew; Tweddell, James S.; Tretter, Justin (2020). Anderson's Pediatric Cardiology E-Book. Elsevier Health Sciences. p. PA1381. ISBN 978-0-7020-7924-5.
  9. ^ L. McCance, Kathryn; Huether, Sue E. (2018). Pathophysiology - E-Book: The Biologic Basis for Disease in Adults and Children. Elsevier Health Sciences. p. 1190. ISBN 978-0-323-41320-6.
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  11. ^ Joffe, Denise C.; Shi, Mark R.; Welker, Carson C. (April 2018). "Understanding cardiac shunts". Pediatric Anesthesia. 28 (4): 316–325. doi:10.1111/pan.13347. PMID 29508477. S2CID 4323077.
  12. ^ Widrich, J; Shetty, M (March 2021). "Physiology, Pulmonary Vascular Resistance". StatPearls Publishing. PMID 32119267.
  13. ^ "lesser circulation". TheFreeDictionary.com. Retrieved 2021-07-09.
  14. ^ de Man, Frances S.; La Gerche, Andre (2017-10-01). "A focus on the greatness of the lesser circulation: spotlight issue on the right ventricle". Cardiovascular Research. 113 (12): 1421–1422. doi:10.1093/cvr/cvx168. ISSN 0008-6363. PMID 28957539.
  15. ^ a b Ribatti D (September 2009). "William Harvey and the discovery of the circulation of the blood". Journal of Angiogenesis Research. 1: 3. doi:10.1186/2040-2384-1-3. PMC 2776239. PMID 19946411.
  16. ^ Azizi MH, Nayernouri T, Azizi F (May 2008). "A brief history of the discovery of the circulation of blood in the human body" (PDF). Archives of Iranian Medicine. 11 (3): 345–50. PMID 18426332.
  17. ^ a b Bosmia A, Watanabe K, Shoja MM, Loukas M, Tubbs RS (July 2013). "Michael Servetus (1511-1553): physician and heretic who described the pulmonary circulation". International Journal of Cardiology. 167 (2): 318–21. doi:10.1016/j.ijcard.2012.06.046. PMID 22748500.
  18. ^ a b c d e f g h Akmal M, Zulkifle M, Ansari A (March 2010). "Ibn nafis - a forgotten genius in the discovery of pulmonary blood circulation". Heart Views. 11 (1): 26–30. PMC 2964710. PMID 21042463.
  19. ^ a b c d Gregory Tsoucalas; Markos Sgantzos (21 March 2017). "The pulmonary circulation, it all started in the Hippocratic era". European Heart Journal. 38 (12): 851. doi:10.1093/eurheartj/ehx072. PMID 28931233.
  20. ^ a b Mahlooji, Kamran; Abdoli, Mahsima; Tekiner, Halil; Zargaran, Arman (2021-03-23). "A new evidence on pulmonary circulation discovery: A text of Ibn Luqa (860 - 912 CE)". European Heart Journal. 42 (26): 2522–2523. doi:10.1093/eurheartj/ehab039. ISSN 1522-9645. PMID 33755117.
  21. ^ a b c d West JB (December 2008). "Ibn al-Nafis, the pulmonary circulation, and the Islamic Golden Age". Journal of Applied Physiology. 105 (6): 1877–80. doi:10.1152/japplphysiol.91171.2008. PMC 2612469. PMID 18845773.
  22. ^ a b c d e f g h i Bestetti RB, Restini CB, Couto LB (December 2014). "Development of anatomophysiologic knowledge regarding the cardiovascular system: from Egyptians to Harvey". Arquivos Brasileiros de Cardiologia. 103 (6): 538–45. doi:10.5935/abc.20140148. PMC 4290745. PMID 25590934.
  23. ^ a b c d ElMaghawry M, Zanatta A, Zampieri F (2014). "The discovery of pulmonary circulation: From Imhotep to William Harvey". Global Cardiology Science & Practice. 2014 (2): 103–16. doi:10.5339/gcsp.2014.31. PMC 4220440. PMID 25405183.
  24. ^ Nunn JF (1996). Ancient Egyptian Medicine. pp. 57–68. ISBN 978-0-7141-0981-7. PMID 10326089. {{cite book}}: |journal= ignored (help)
  25. ^ Loukas M, Tubbs RS, Louis RG, Pinyard J, Vaid S, Curry B (August 2007). "The cardiovascular system in the pre-Hippocratic era". International Journal of Cardiology. 120 (2): 145–9. doi:10.1016/j.ijcard.2006.11.122. PMID 17316844.
  26. ^ a b Aird WC (July 2011). "Discovery of the cardiovascular system: from Galen to William Harvey". Journal of Thrombosis and Haemostasis. 9 Suppl 1 (Suppl. 1): 118–29. doi:10.1111/j.1538-7836.2011.04312.x. PMID 21781247. S2CID 12092592.

External links edit

  Media related to Pulmonary circulation at Wikimedia Commons

  • Official Journal of the Pulmonary Vascular Research Institute

November 13, 2023
pulmonary, circulation, pulmonary, circulation, division, circulatory, system, vertebrates, circuit, begins, with, deoxygenated, blood, returned, from, body, right, atrium, heart, where, pumped, from, right, ventricle, lungs, lungs, blood, oxygenated, returned. The pulmonary circulation is a division of the circulatory system in all vertebrates The circuit begins with deoxygenated blood returned from the body to the right atrium of the heart where it is pumped out from the right ventricle to the lungs In the lungs the blood is oxygenated and returned to the left atrium to complete the circuit 1 Pulmonary circulationPulmonary circulation in the heartDetailsSystemCirculatory systemIdentifiersMeSHD011652Anatomical terminology edit on Wikidata The other division of the circulatory system is the systemic circulation that begins with receiving the oxygenated blood from the pulmonary circulation into the left atrium From the atrium the oxygenated blood enters the left ventricle where it is pumped out to the rest of the body returning as deoxygenated blood back to the pulmonary circulation The blood vessels of the pulmonary circulation are the pulmonary arteries and the pulmonary veins A separate circulatory circuit known as the bronchial circulation supplies oxygenated blood to the tissue of the larger airways of the lung Contents 1 Structure 1 1 Lungs 1 2 Veins 1 3 Arteries 2 Development 3 Clinical significance 4 History 5 References 6 External linksStructure edit nbsp 3D rendering of a high resolution computed tomography of the thorax The anterior thoracic wall the airways and the pulmonary vessels anterior to the root of the lung have been digitally removed in order to visualize the different levels of the pulmonary circulation nbsp Image showing main pulmonary artery coursing ventrally to the aortic root and trachea The right pulmonary artery passes dorsally to the ascending aorta while the left pulmonary artery passes ventrally to the descending aorta De oxygenated blood leaves the heart goes to the lungs and then enters back into the heart 2 De oxygenated blood leaves through the right ventricle through the pulmonary artery 2 From the right atrium the blood is pumped through the tricuspid valve or right atrioventricular valve into the right ventricle Blood is then pumped from the right ventricle through the pulmonary valve and into the pulmonary artery 2 Lungs edit The pulmonary arteries carry deoxygenated blood to the lungs where carbon dioxide is released and oxygen is picked up during respiration 3 Arteries are further divided into very fine capillaries which are extremely thin walled 4 The pulmonary veins return oxygenated blood to the left atrium of the heart 3 Veins edit Main article Pulmonary vein Oxygenated blood leaves the lungs through pulmonary veins which return it to the left part of the heart completing the pulmonary cycle 3 5 This blood then enters the left atrium which pumps it through the mitral valve into the left ventricle 3 5 From the left ventricle the blood passes through the aortic valve to the aorta 3 5 The blood is then distributed to the body through the systemic circulation before returning again to the pulmonary circulation 3 5 Arteries edit Main article Pulmonary artery From the right ventricle blood is pumped through the semilunar pulmonary valve into the left and right main pulmonary artery one for each lung which branch into smaller pulmonary arteries that spread throughout the lungs 3 5 Development editThe pulmonary circulation loop is virtually bypassed in fetal circulation 6 The fetal lungs are collapsed and blood passes from the right atrium directly into the left atrium through the foramen ovale an open conduit between the paired atria or through the ductus arteriosus a shunt between the pulmonary artery and the aorta 6 When the lungs expand at birth the pulmonary pressure drops and blood is drawn from the right atrium into the right ventricle and through the pulmonary circuit Over the course of several months the foramen ovale closes leaving a shallow depression known as the fossa ovalis 6 7 Clinical significance editA number of medical conditions may affect the pulmonary circulation Pulmonary hypertension describes an increase in resistance in the pulmonary arteries 8 Pulmonary embolism is occlusion or partial occlusion of the pulmonary artery or its branches by an embolus usually from the embolization of a blood clot from deep vein thrombosis 9 It can cause difficulty breathing or chest pain is usually diagnosed through a CT pulmonary angiography or V Q scan and is often treated with anticoagulants such as heparin and warfarin 10 Cardiac shunt is an unnatural connection between parts of the heart that leads to blood flow that bypasses the lungs 11 Vascular resistance 12 Pulmonary shuntHistory edit nbsp The opening page of one of Ibn al Nafis s medical worksThe pulmonary circulation is archaically known as the lesser circulation which is still used in non English literature 13 14 The discovery of the pulmonary circulation has been attributed to many scientists with credit distributed in varying ratios by varying sources In much of modern medical literature the discovery is credited to English physician William Harvey 1578 1657 CE based on the comprehensive completeness and correctness of his model despite its relative recency 15 16 Other sources credit Greek philosopher Hippocrates 460 370 BCE Spanish physician Michael Servetus c 1509 1553 CE Arab physician Ibn al Nafis 1213 1288 CE and Syrian physician Qusta ibn Luqa 17 18 19 20 Several figures such as Hippocrates and al Nafis receive credit for accurately predicting or developing specific elements of the modern model of pulmonary circulation Hippocrates 19 for being the first to describe pulmonary circulation as a discrete system separable from systemic circulation as a whole and al Nafis 21 for making great strides over the understanding of those before him and towards a rigorous model There is a great deal of subjectivity involved in deciding at which point a complex system is discovered as it is typically elucidated in piecemeal form so that the very first description most complete or accurate description and the most significant forward leaps in understanding are all considered acts of discovery of varying significance 19 Primitive descriptions of the cardiovascular system are found throughout several ancient cultures The earliest known description of the role of air in circulation was produced in Egypt in 3500 BCE At the time the Egyptians believed that the heart was the origin of many channels that connected different parts of the body to each other and transported air as well as urine blood and the soul between them 22 The Edwin Smith Papyrus 1700 BCE named for American Egyptologist Edwin Smith 1822 1906 CE who purchased the scroll in 1862 provided evidence that Egyptians believed that the heartbeat created a pulse that transported the above substances throughout the body 23 A second scroll the Ebers Papyrus c 1550 BCE also emphasized the importance of the heart and its connection to vessels throughout the body and described methods to detect cardiac disease through pulse abnormalities Although they had knowledge of the heartbeat vessels and pulse the Egyptians attributed the movement of substances through the vessels to air that resided in these channels rather than to the heart s exertion of pressure 24 The Egyptians knew that air played an important role in circulation but did not yet have a conception of the role of the lungs The next addition to the historical understanding of pulmonary circulation arrived with the Ancient Greeks Physician Alcmaeon 520 450 BCE proposed that the brain not the heart was the connection point for all of the vessels in the body He believed that the function of these vessels was to bring the spirit pneuma and air to the brain 22 25 Empedocles 492 432 BCE a philosopher proposed a series of pipes impermeable to blood but continuous with blood vessels that carried the pneuma throughout the body He proposed that this spirit was internalized by pulmonary respiration 22 Hippocrates was the first to describe pulmonary circulation as a discrete system separable from systemic circulation in his Corpus Hippocraticum which is often regarded as the foundational text of modern medicine 19 Hippocrates developed the view that the liver and spleen produced blood and that this traveled to the heart to be cooled by the lungs that surrounded it 18 He described the heart as having two ventricles connected by an interventricular septum and depicted the heart as the nexus point of all of the vessels of the body He proposed that some vessels carried only blood and that others carried only air He hypothesized that these air carrying vessels were divisible into the pulmonary veins which carried in air to the left ventricle and the pulmonary artery which carried in air to the right ventricle and blood to the lungs He also proposed the existence of two atria of the heart functioning to capture air He was one of the first to begin to accurately describe the anatomy of the heart and to describe the involvement of the lungs in circulation His descriptions built substantially on previous and contemporaneous efforts but by modern standards his conceptions of pulmonary circulation and of the functions of the parts of the heart were still largely inaccurate 22 Greek philosopher and scientist Aristotle 384 322 BCE followed Hippocrates and proposed that the heart had three ventricles rather than two that all connected to the lungs 22 Greek physician Erasistratus 315 240 BCE agreed with Hippocrates and Aristotle that the heart was the origin of all of the vessels in the body but proposed a system in which air was drawn into the lungs and traveled to the left ventricle via pulmonary veins It was transformed there into the pneuma and distributed throughout the body by arteries which contained only air 23 In this system veins distributed blood throughout the body and thus blood did not circulate but rather was consumed by the organs 22 The Greek physician Galen 129 c 210 CE provided the next insights into pulmonary circulation Though many of his theories like those of his predecessors were marginally or completely incorrect his theory of pulmonary circulation dominated the medical community s understanding for hundreds of years after his death 23 Galen contradicted Erasistratus before him by proposing that arteries carried both air and blood rather than air alone which was essentially correct leaving aside that blood vessels carry constituents of air and not air itself 18 He proposed that the liver was the originating point of all blood vessels He also theorized that the heart was not a pumping muscle but rather an organ through which blood passed 23 Galen s theory included a new description of pulmonary circulation air was inhaled into the lungs where it became the pneuma Pulmonary veins transmitted this pneuma to the left ventricle of the heart to cool the blood simultaneously arriving there This mixture of pneuma blood and cooling produced the vital spirits that could then be transported throughout the body via arteries Galen further proposed that the heat of the blood arriving in the heart produced noxious vapors that were expelled through the same pulmonary veins that first brought the pneuma 26 He wrote that the right ventricle played a different role to the left it transported blood to the lungs where the impurities were vented out so that clean blood could be distributed throughout the body Though Galen s description of the anatomy of the heart was more complete than those of his predecessors it included several mistakes Most notably Galen believed that blood flowed between the two ventricles of the heart through small invisible pores in the interventricular septum 22 The next significant developments in the understanding of pulmonary circulation did not arrive until centuries later Persian polymath Avicenna c 980 1037 CE wrote a medical encyclopedia entitled The Canon of Medicine In it he translated and compiled contemporary medical knowledge and added some new information of his own 21 However Avicenna s description of pulmonary circulation reflected the incorrect views of Galen 18 The Arab physician Ibn al Nafis wrote the Commentary on Anatomy in Avicenna s Canon in 1242 in which he provided possibly the first known description of the system that remains substantially congruent with modern understandings in spite of its flaws Ibn al Nafis made two key improvements on Galen s ideas First he disproved the existence of the pores in the interventricular septum that Galen had believed allowed blood to flow between the left and right ventricles Second he surmised that the only way for blood to get from the right to the left ventricle in the absence of interventricular pores was a system like pulmonary circulation He also described the anatomy of the lungs in clear and basically correct detail which his predecessors had not 21 However like Aristotle and Galen al Nafis still believed in the quasi mythical concept of vital spirit and that it was formed in the left ventricle from a mixture of blood and air Despite the enormity of Ibn al Nafis s improvements on the theories that preceded him his commentary on The Canon was not widely known to Western scholars until the manuscript was discovered in Berlin Germany in 1924 As a result the ongoing debate among Western scholars as to how credit for the discovery should be apportioned failed to include Ibn al Nafis until at earliest the mid 20th century shortly after which he came to enjoy a share of this credit 18 21 In 2021 several researchers described a text predating the work of al Nafis fargh beyn roh va nafs in which there is a comparable report on pulmonary circulation The researchers argue that its author Qusta ibn Luqa is the best candidate for the discoverer of pulmonary circulation on a similar basis to arguments in favour of al Nafis generally 20 It took centuries for other scientists and physicians to reach conclusions that were similar to and then more accurate than those of al Nafis and ibn Luqa This later progress constituting the gap between medieval and modern understanding occurred throughout Europe Italian polymath Leonardo da Vinci 1452 1519 CE was one of the first to propose that the heart was just a muscle rather than a vessel of spirits and air but he still subscribed to Galen s ideas of circulation and defended the existence of interventricular pores 22 The Flemish physician Andreas Vesalius 1514 1564 CE published corrections to Galen s view of circulatory anatomy questioning the existence of interventricular pores in his book De humani corporis fabrica libri septem in 1543 26 Spanish Michael Servetus after him was the first European physician to accurately describe pulmonary circulation 17 His assertions largely matched those of al Nafis In subsequent centuries he has frequently been credited with the discovery but some historians have propounded the idea that he potentially had access to Ibn al Nafis s work while writing his own texts 18 Servetus published his findings in Christianismi Restituto 1553 a theological work that was considered heretical by Catholics and Calvinists alike As a result both book and author were burned at the stake and only a few copies of his work survived 18 Italian physician Realdo Colombo c 1515 1559 CE published a book De re anatomica libri XV in 1559 that accurately described pulmonary circulation It is still a matter of debate among historians as to whether Colombo reached his conclusions alone or based them to an unknown degree on the works of al Nafis and Servetus 18 22 Finally in 1628 the influential British physician William Harvey 1578 1657 AD provided at the time the most complete and accurate description of pulmonary circulation of any scholar worldwide in his treatise Exercitatio Anatomica de Motu Cordis et Sanguinis in Animalibus At the macroscopic level his model is still recognizable in and reconcilable with modern understandings of pulmonary circulation 15 References edit Hine R 2008 A dictionary of biology 6th ed Oxford Oxford University Press p 540 ISBN 978 0 19 920462 5 a b c Nash Michael 2014 UK Higher Education OUP Humanities amp Social Sciences Health amp Social Welfare McGraw Hill Education UK p 84 ISBN 978 0 335 26286 1 a b c d e f g Ehrlich Ann Schroeder Carol L Ehrlich Laura Schroeder Katrina A 2016 Medical Terminology for Health Professions Spiral bound Version Cengage Learning p 128 ISBN 978 1 305 88714 5 Marchese Rosemary Taylor Julie Fagan Kirsten 2019 The Essential Guide to Fitness Cengage AU p 49 ISBN 978 0 17 041370 1 a b c d e Cohen Barbara Janson Jones Shirley A 2020 Medical Terminology An Illustrated Guide Jones amp Bartlett Learning pp 317 318 ISBN 978 1 284 21880 0 a b c McConnell Thomas H Hull Kerry L 2020 Human Form Human Function Essentials of Anatomy amp Physiology Enhanced Edition Jones amp Bartlett Learning p 703 ISBN 978 1 284 21805 3 Davis FA 2016 Taber s Quick Reference for Cardiology and Pulmonology F A Davis p 106 ISBN 978 0 8036 4721 3 Anderson Robert H Krishna Kumar Mussato Kathleen A Redington Andrew Tweddell James S Tretter Justin 2020 Anderson s Pediatric Cardiology E Book Elsevier Health Sciences p PA1381 ISBN 978 0 7020 7924 5 L McCance Kathryn Huether Sue E 2018 Pathophysiology E Book The Biologic Basis for Disease in Adults and Children Elsevier Health Sciences p 1190 ISBN 978 0 323 41320 6 Moini Jahangir Piran Pirouz 2020 Functional and Clinical Neuroanatomy A Guide for Health Care Professionals Academic Press pp 146 147 ISBN 978 0 12 817425 8 Joffe Denise C Shi Mark R Welker Carson C April 2018 Understanding cardiac shunts Pediatric Anesthesia 28 4 316 325 doi 10 1111 pan 13347 PMID 29508477 S2CID 4323077 Widrich J Shetty M March 2021 Physiology Pulmonary Vascular Resistance StatPearls Publishing PMID 32119267 lesser circulation TheFreeDictionary com Retrieved 2021 07 09 de Man Frances S La Gerche Andre 2017 10 01 A focus on the greatness of the lesser circulation spotlight issue on the right ventricle Cardiovascular Research 113 12 1421 1422 doi 10 1093 cvr cvx168 ISSN 0008 6363 PMID 28957539 a b Ribatti D September 2009 William Harvey and the discovery of the circulation of the blood Journal of Angiogenesis Research 1 3 doi 10 1186 2040 2384 1 3 PMC 2776239 PMID 19946411 Azizi MH Nayernouri T Azizi F May 2008 A brief history of the discovery of the circulation of blood in the human body PDF Archives of Iranian Medicine 11 3 345 50 PMID 18426332 a b Bosmia A Watanabe K Shoja MM Loukas M Tubbs RS July 2013 Michael Servetus 1511 1553 physician and heretic who described the pulmonary circulation International Journal of Cardiology 167 2 318 21 doi 10 1016 j ijcard 2012 06 046 PMID 22748500 a b c d e f g h Akmal M Zulkifle M Ansari A March 2010 Ibn nafis a forgotten genius in the discovery of pulmonary blood circulation Heart Views 11 1 26 30 PMC 2964710 PMID 21042463 a b c d Gregory Tsoucalas Markos Sgantzos 21 March 2017 The pulmonary circulation it all started in the Hippocratic era European Heart Journal 38 12 851 doi 10 1093 eurheartj ehx072 PMID 28931233 a b Mahlooji Kamran Abdoli Mahsima Tekiner Halil Zargaran Arman 2021 03 23 A new evidence on pulmonary circulation discovery A text of Ibn Luqa 860 912 CE European Heart Journal 42 26 2522 2523 doi 10 1093 eurheartj ehab039 ISSN 1522 9645 PMID 33755117 a b c d West JB December 2008 Ibn al Nafis the pulmonary circulation and the Islamic Golden Age Journal of Applied Physiology 105 6 1877 80 doi 10 1152 japplphysiol 91171 2008 PMC 2612469 PMID 18845773 a b c d e f g h i Bestetti RB Restini CB Couto LB December 2014 Development of anatomophysiologic knowledge regarding the cardiovascular system from Egyptians to Harvey Arquivos Brasileiros de Cardiologia 103 6 538 45 doi 10 5935 abc 20140148 PMC 4290745 PMID 25590934 a b c d ElMaghawry M Zanatta A Zampieri F 2014 The discovery of pulmonary circulation From Imhotep to William Harvey Global Cardiology Science amp Practice 2014 2 103 16 doi 10 5339 gcsp 2014 31 PMC 4220440 PMID 25405183 Nunn JF 1996 Ancient Egyptian Medicine pp 57 68 ISBN 978 0 7141 0981 7 PMID 10326089 a href Template Cite book html title Template Cite book cite book a journal ignored help Loukas M Tubbs RS Louis RG Pinyard J Vaid S Curry B August 2007 The cardiovascular system in the pre Hippocratic era International Journal of Cardiology 120 2 145 9 doi 10 1016 j ijcard 2006 11 122 PMID 17316844 a b Aird WC July 2011 Discovery of the cardiovascular system from Galen to William Harvey Journal of Thrombosis and Haemostasis 9 Suppl 1 Suppl 1 118 29 doi 10 1111 j 1538 7836 2011 04312 x PMID 21781247 S2CID 12092592 External links edit nbsp Media related to Pulmonary circulation at Wikimedia Commons Official Journal of the Pulmonary Vascular Research Institute Retrieved from https en wikipedia org w index php title Pulmonary circulation amp oldid 1182155614, wikipedia, wiki, book, books, library,

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