Department of Medicine, University of California San Diego, La Jolla CA

Articles in PresS. Am J Physiol Lung Cell Mol Physiol (May 30, 2014). doi:10.1152/ajplung.00123.2014

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Galen and the beginnings of Western p

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Articles in PresS. Am J Physiol Lung Cell Mol Physiol (May 30, 2014). doi:10.1152/ajplung.00123.2014

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Galen and the beginnings of Western physiology

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John B. West

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Department of Medicine, University of California San Diego, La Jolla CA 92093-0623

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Running head: Galen and early physiology

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Correspondence to: John B. West, M.D., Ph.D.

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UCSD Department of Medicine 0623A

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9500 Gilman Drive

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La Jolla, CA 92093-0623

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Telephone:

858-534-4192

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Fax:

858-534-4812

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E-mail:

[email protected]

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Copyright © 2014 by the American Physiological Society.

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Abstract

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Galen (129-c. 216 AD) was a key figure in the early development of Western

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physiology. His teachings incorporated much of the ancient Greek traditions

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including the work of Hippocrates and Aristotle. Galen himself was a well-educated

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Greco-Roman physician and physiologist who at one time was a physician to the

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gladiators in Pergamon. Later he moved to Rome where he was associated with the

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Roman emperors Marcus Aurelius and Lucius Verus. The Galenical school was

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responsible for voluminous writings many of which are still extant. One emphasis

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was on the humors of the body which were believed to be important in disease.

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Another was the cardiopulmonary system including the belief that part of the blood

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from the right ventricle could enter the left through the interventricular septum. An

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extraordinary feature of these teachings is that they dominated thinking for some

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1300 years and became accepted as dogma by both the State and Church. One of the

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first anatomists to challenge the Galenical teachings was Andreas Vesalius who

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produced a magnificent atlas of human anatomy in 1543. At about the same time

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Michael Servetus described the pulmonary transit of blood but he was burned at the

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stake for heresy. Finally with William Harvey and others in the first part of the 17th

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century, the beginnings of modern physiology emerged with an emphasis on

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hypotheses and experimental data. Nevertheless vestiges of Galen’s teaching

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survived into the 19th century.

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Key words: ancient Greeks, body humors, cardiopulmonary system, Vesalius, Harvey

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Introduction

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Claudius Galenus (129-c 216 AD) (Figure 1) who is universally known as Galen of

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Pergamon was a famous Greco-Roman physician and physiologist. He is an

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appropriate subject for this essay on the beginnings of Western physiology for

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several reasons. First he and his school had an extraordinary influence on medical

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science including physiology for about 1300 years. It is not easy to think of a

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comparable situation in any other area of science where one school dominated

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thinking for so long. In fact some medical students were still studying Galen’s

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writings in the 19th century and some of the practices that he advocated, for

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example bloodletting, were still being used at that time.

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Another reason for choosing Galen as an introduction to Western physiology is

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that he was heavily influenced by the teaching of the ancient Greeks. He therefore

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allows us an opportunity to summarize this important body of work. Admittedly

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many of these mainly theoretical musings of over two millennia ago do not resonate

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with present-day physiologists but some of the influences of this group can still be

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seen.

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Finally the writings of Galen and his school were extremely voluminous and much

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of the material still survives. For example Karl Gottlob Kühn collected no less than

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22 volumes (11). Other large collections of Galen’s writings also exist. Therefore

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there is a wealth of information about the man, his school, and his teachings.

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The main purpose of this essay, as with the others in the series, is to introduce

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medical and graduate students to his work, and show how his teachings lasted up to

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the Renaissance. Then with the advent of Vesalius, Harvey, Boyle and many of their

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contemporaries, a sea change in attitudes occurred, and the beginnings of modern

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physiology are clearly seen. For graduate and medical students who would like an

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introduction to Galen, the short books by Singer (19; 20) are recommended. More

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recent extensive studies have been carried out by Nutton (12). An article by Boylan

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(2) has a useful list of primary and secondary sources.

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Brief biography

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Galen was born in Pergamon (modern day Bergama, Turkey) which at the time was

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a very lively intellectual center. The city boasted a fine library which had been

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greatly expanded by King Eumenes II, and it was only bettered by the famous library

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in Alexandria. Galen’s father was a well-educated and affluent man who had high

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hopes that his son would continue in his own philosophical traditions. However a

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remarkable event narrated by Galen was that when he was about 16, he had a

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dream in which the god Asclepius urged his father to have his son study medicine.

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His father agreed and Galen was initially a student in Pergamon which was a famous

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medical center and attracted many sick people who could afford to get the best

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treatment. Three years later his father died leaving him wealthy, and he was able to

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travel widely and visit the most important medical centers including the

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outstanding medical school in Alexandria.

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At the age of 28 Galen returned to Pergamon where he became a physician to the

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gladiators. This institution was run by the High Priest of Asia who was enormously

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influential. Galen spent four years treating the gladiators for their wounds and also

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emphasizing their training, fitness and hygiene. It is said that during his period,

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there were only five deaths among the gladiators while he was in charge, and this

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was an enormous improvement over the previous period when many gladiators

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died of their wounds. There is an interesting recent article on head injuries of

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gladiators whose bodies were exhumed from a cemetery in Ephesus, Turkey (9). A

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feature was the large number of extensive fractures of the skull in spite of the fact

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that most gladiators are believed to have worn helmets. Perhaps the blows were

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delivered after the victims had received other serious injuries in order to put them

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out of their misery.

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When he was 33 Galen went to Rome, then the center of the civilized Western

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world. However he recounted that he fell out with some of the prominent physicians

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there and, fearing that he might be harmed, he moved away from the city. A few

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years later he was recalled by the Roman emperors Marcus Aurelius and Lucius

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Verus, who ruled together, to serve in the army. A great plague broke out in Rome at

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that time and large numbers of patients developed severe skin lesions and many

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died. It is now thought that the disease was smallpox. Galen remained in Rome for

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the rest of his life and there has been much discussion on when he died. However

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many historians now believe that his death occurred in about 216 when his age was

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87. This was an exceptionally long life in those times.

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Physiology in ancient Greece

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As indicated above, Galen and his school were much influenced by earlier Greek

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thinking. Students of today often find it difficult to see the relevance of many of

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these developing ideas and there is some reluctance to grapple with them. However

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many vestiges of early Greek thinking remained in the work of the Galenical school,

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for example the notion of how four humors determine the medical status of an

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individual, and it is interesting to review how such concepts developed.

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Historians often chose to start the beginnings of early Greek physiology with the

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work of Anaximenes (ca. 570 BC). He argued that “pneuma” (πνεύμα, Greek for

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breath or spirit) was essential for life. This is hardly surprising because death is

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often signaled by a cessation of respiration. However Anaximenes expanded the

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idea of pneuma which was seen as an all-pervading property that was essential for

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life everywhere. For example he stated “As our soul, being air, sustains us, so

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pneuma and air pervade the whole world” (20).

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About a hundred years later, Empedocles (490-430 BC) wrote about the

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movement of blood, and he developed the idea that this ebbed and flowed from the

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heart in a reciprocating manner. A related notion was “innate heat” which was seen

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as a life-giving principle and was distributed by the blood throughout the body.

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Empedocles was also one of the first philosophers to suggest that all things are

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made up of four essential elements: earth, air, fire and water. This notion evolved

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into the philosophy of the four humors which persisted in different forms right up to

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the European Renaissance. Earth, air, fire, and water represented the concepts of

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solidity, volatility, energy, and liquidity. This idea was taken up a hundred years

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later by Aristotle (384-322 BC) and was still part of physiological dogma 2000 years

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later.

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Hippocrates (c. 460-360 BC) was one of the giants of the ancient Greek period. His

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school produced an enormous volume of work known as the Hippocratic Corpus

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which was studied extensively until the European Renaissance. The emphasis here

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was on the practice of medicine rather than its physiological principles. For example

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this was the origin of the Hippocratic Oath which sets out ethical principles for

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physicians and is still often used in one form or another for graduating medical

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students.

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Many clinical signs that are still taught to medical students can be found in the

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Hippocratic Corpus. For example there is a description of the succussion splash, that

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is the sound that can be heard if a patient with air and fluid in the pleural cavity or

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an abdominal viscus such as the stomach is moved from side to side. Another sign

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included in the Corpus is the pleural friction rub. This is the sound heard through a

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stethoscope, or the ear applied directly to the chest, when there is disease of the

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pleural membranes, and they move over each other during breathing with a rasping

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sound like sandpaper. Hippocrates also described some of the clinical features of

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pulmonary tuberculosis which was rife at the time. For example he stated that the

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disease was associated with fever, the coughing up of blood, and that it was usually

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fatal (8).

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The Hippocratic Corpus also continued the belief, earlier enunciated by

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Empedocles, that the heart is the origin of innate heat and that the primary purpose

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of respiration is to cool this fiery process. Plato (428-348 BC) expanded on these

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views in his book Timaeus where he stated “As the heart might be easily raised to

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too high a temperature by hurtful irritation, the genii placed the lungs in its

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neighbourhood, which adhere to it and fill the cavity of the thorax, in order that

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their air vessels might moderate the great heat of that organ, and reduce the vessels

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to an exact obedience” (15).

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Aristotle was not only the most eminent biologist of Greek antiquity but many

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would say that he deserved this accolade up to the time of the European

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Renaissance. He was a pupil of Plato, and incidentally also tutored Alexander the

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Great (356-323 BC). Aristotle had an inexhaustible curiosity and his writings on

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various animals give pleasure even today. One of his great strengths was in the

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classification of animals. It is said that he described 540 different species. Aristotle’s

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colorful text De Partibus Animalium (On the Parts of Animals) (1) still makes

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enjoyable reading. For example here is his description of the elephant trunk. “Just

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then as divers are sometimes provided with instruments for respiration, through

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which they can draw air from above the water, and thus may remain for a long time

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under the sea, so also have elephants been furnished by nature with their

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lengthened nostril; and, whenever they have to traverse the water, they lift this up

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above the surface and breathing [sic] through it” (1). It could be argued that

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Aristotle’s contributions to systematizing biology were not equaled until the time of

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Carl Linnaeus (1707-1778). Aristotle’s three great books on biology were History of

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Animals, Parts of Animals, and The Generation of Animals. His contributions include a

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diagram of the “ladder of nature” (scala naturae) shown in Figure 2.

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However although Aristotle had such remarkable insights into the diversity of

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nature, his footing in physiology was not always secure. For example although it had

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previously been concluded by others that the brain was the seat of intelligence,

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Aristotle made a backward step and elevated the heart to this status. As we saw,

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Empedocles had initiated this idea many years before. Also strangely, Aristotle

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believed that the arteries normally contained air. This error resulted from the fact

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that in preparing some animals for dissection by strangulation, the arteries were left

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virtually empty. Another interesting feature of Aristotle’s beliefs was that living

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creatures were fundamentally different from inanimate objects because there was a

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special principle essential for life. This notion, known as vitalism, has recurred many

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times in the history of physiology, and it could be argued that it survived until

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Claude Bernard (1813-1878) finally put it to rest. Having said that, even the great

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British physiologist J.S. Haldane (1860-1936) believed that the lung secreted oxygen

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and his arguments supporting this were associated with a nod towards vitalism (5).

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Erasistratus (c. 304-250 BC) was one of the last, and some would say the greatest

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Greek physiologist prior to Galen. He is credited with promulgating the pneumatic

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theory of respiration. This recognized the critical importance of inspired air but was

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curious in that it taught that air from the lungs passed by way of the pulmonary

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circulation to the left ventricle where it was endowed with “vital spirit”. This was

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distributed by air-filled arteries to the various tisssues. Some of the vital spirit found

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its way to the brain where it was changed to “animal spirit” and then distributed via

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the hollow nerves to the muscles. Venous blood was believed to contain products of

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food, and this was modified by the liver and delivered to the right heart. As we shall

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see, a variant of this scheme was adopted by the Galenical school and dominated

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cardiorespiratory physiology for some 1300 years.

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Physiology of the Galenical school

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The teachings of the Galenical school were based on those of the ancient Greeks

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especially Hipporates for whom Galen had enormous admiration, but also Aristotle,

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Plato and Erasistratus. Two major areas of teaching stand out. The first was the

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dominating effects of the four humors emanating from the four bodily fluids: blood,

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yellow bile, black bile and phlegm. This tradition closely followed the work of

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Hippocrates. Health was seen as a situation where the humors were equally

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balanced. An imbalance resulted in a particular type of temperament or disease. For

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example an overemphasis of blood led to a sanguine personality, too much black bile

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made the subject melancholic, an excess of yellow bile resulted in a choleric

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temperament, and too much phlegm caused the subject to become phlegmatic. We

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can easily see how the present use of these terms reflects the supposed pathological

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basis. People with a sanguine temperament were happy, optimistic, extraverted, and

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generally good company. We could wish we were all like that. People with a

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superabundance of yellow bile had excessive energy and were likely to have short

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tempers. By contrast, an excess of black bile resulted in melancholy, a subdued

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temperament, and perhaps a bipolar personality with periods of depression. Finally

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the phlegmatic personality was on a more even keel but perhaps with a tendency to

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occasional depression. On the other hand these people were affectionate.

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We shall see later that this theory of the four humors had an enormous influence

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on medicine up to the Renaissance. For example the popularity of bloodletting was

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in part due to the belief that if one of the humors was dominating the patient,

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removal of some blood could reduce its influence. Even today we frequently

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characterize people based on their temperament and this is not so different from

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invoking one of the humors.

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The second major area of teaching that influenced medical thinking right through to the Renaissance was Galen’s scheme for the cardiopulmonary system. This is

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shown in Figure 3 and clearly derives from the work of Erasistratus. In this concept

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food that was absorbed by the gut underwent “concoction” and then was

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transported by the blood to the liver where it was imbued with “natural spirit”. The

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blood then entered the right ventricle of the heart and most of it flowed through the

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pulmonary artery to nourish the lungs. However some passed through “invisible

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pores” in the interventricular septum to the left ventricle where the blood was

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mixed with pneuma from the inspired air and thus endowed with “vital spirit”. This

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air reached the left ventricle from the lungs via the pulmonary vein. “Fuliginous

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(sooty) wastes” traveled back from the heart to the lungs along the same blood

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vessel. From the left ventricle the blood with its “vital spirit” was distributed

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throughout the body in the arteries. Blood that arrived in the brain formed “animal

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spirit” and was distributed to the various organs of the body through the hollow

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nerves. As we have seen, much of this scheme was originally suggested by

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Erasistratus. Also there are clear parallels with modern views on pulmonary gas

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exchange. For example the addition of pneuma to the blood to provide vital spirit

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has similarities with the process of oxygenation, and the removal of fuliginous

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wastes via the lung reminds us of the elimination of carbon dioxide which is a

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product of metabolism.

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Galen’s scheme may seem strange to us today but it included some basic

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physiological principles having to do with the movement of substances through

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tubes. Admittedly some features of the scheme were difficult to understand. For

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example his notion that air entered the left ventricle from the lung via the

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pulmonary vein, but in addition, “fuliginous wastes” traveled back from the ventricle

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to the lungs along the same route puzzled Harvey 1400 years later (3). He could not

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understand how a tube could carry flow in both directions simultaneously. Having

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said this, the great Harvey was confused about some aspects of the pulmonary

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circulation. For example he wondered why the lung needed such an enormous blood

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flow stating “it is altogether incongruous to suppose that the lungs need for their

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nourishment so large a supply of blood” (7).

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In addition to his teachings on the importance of the four humors, and his

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elaborate scheme for cardiopulmonary function, Galen made many other

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contributions to physiology especially in the area of respiration. As has already been

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pointed out, Galen was the physician to the gladiators in Pergamon and as such he

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must have seen many serious injuries. One of the most interesting observations he

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made had to do with the effects of dislocations of the neck. He recognized that some

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of the injured men died immediately but others who were paralyzed below the neck

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were able to continue to breathe because the diaphragm was still active.

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Remarkably Galen was able to make sense of these observations using experiments

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on pigs. He found that when the spinal cord was cut halfway through affecting only

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one side, the muscles below this were paralyzed. Furthermore he was able to

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demonstrate that if the spinal cord was completely cut at the level of the third

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cervical vertebra, the animal stopped breathing. However when the spinal cord was

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severed between the seventh and eighth cervical vertebrae, he showed that the

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animal continued to breathe with the diaphragm. Related to these studies, he

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reported that the diaphragm was controlled by the phrenic nerve that had its origin

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from cervical levels three, four and five. A good source for these observations of

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Galen can be found in Fulton (4).

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The Galenical school made other contributions to the physiology of respiration.

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The diaphragm was seen as not only a partition between the thorax and the

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abdomen, but it was also recognized to be an important muscle of respiration. It was

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also stated that the abdominal muscles were used for forced expiration and also for

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the production of voice (16). Galen described the larynx in some detail and

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remarkably reported that cutting the recurrent laryngeal nerve prevented squealing

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in pigs. He also understood how the lung expands when he stated “When the whole

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thorax expands in inspiration... [this] causes the entire lung to expand to fill the

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space left vacant”. He reported that on inspiration, the airways increase both their

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caliber and length, and he recognized the importance of the upper airways in

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modifying the inspired air. He wrote that one of the functions of the nose and

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nasopharynx was to warm the inspired gas and filter out dust particles. He went on

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to say that the walls of the airways were lined with sticky substances that retain the

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dust that fell on them.

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In addition to these very perceptive insights on physiology, the Galenical school

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made important advances in anatomy. Here they were at a disadvantage because

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dissection of human cadavers had been forbidden in Rome since about 150 BC. As a

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result Galen turned to the Barbary macaque ape, Macaca inuus, which resembles

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humans in many respects but of course is not identical. Other studies were carried

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out on pigs. The anatomical work was reported in 16 books. For description of

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bones, Galen had access to human skeletons and the long bones and spine were

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described in some detail. Pioneering work was done on the anatomy of muscles

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although necessarily most of this was on animals. Galen’s description of the cranial

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nerves was the basis of teaching until the Renaissance. He stated that there were

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seven pairs of cranial nerves including the optic, oculomotor, trigeminal, facial,

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glossopharyngeal and hypoglossal nerves. In his work on the anatomy of arteries he

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corrected the error made by Erasistratus that the arteries contain air, showing by

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applying ligatures proximally and distally that they only contain blood.

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Galen was a skilled surgeon and operated on many human patients. Some of the

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procedures that he initiated were not used again for many centuries. Remarkably he

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attempted to cure blindness caused by cataract by removing the opaque lens using a

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needle.

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Galen’s legacy

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In the years following Galen’s death in 216 there was a dramatic decline in science

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in Western Europe. In 391 the great library in Alexandria where Galen had studied

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was destroyed by Christian fanatics. Shortly after, in 410, Rome was conquered by

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the barbarians and theologians such as St. Augustine of Hippo emphasized

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preparing for the afterlife rather than survive in the dismal conditions that

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prevailed at the time. In central Europe the centers of learning were mainly limited

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to the monasteries, and while theology was studied, science withered.

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It was very fortunate however that much of the knowledge accumulated in Greek

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antiquity and expounded at great length by the Galenical school was picked up by

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the Islamic civilization. In fact the period from the eighth to the fifteenth century is

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sometimes described as the Islamic Golden Age. At that time the Islamic empire was

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enormous, and extended from the Iberian peninsula in the west to the Indus Valley

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in the east. In addition it covered the area from the southern part of Arabia to the

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Caspian Sea in the north. Eminent scholarly institutions existed with some of the

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most important being Baghdad, Damascus and Cairo. Whether the term Islamic

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science is accurate has been discussed by some scholars who prefer the term Arab

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science since many of the writings were in Arabic which was the common language

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of the movement. On the other hand although most of the scientists were Arab, some

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of them including the most distinguished, Avicenna (c.980-1037) were in fact

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Persian. It has also been pointed out that although the majority of the scholars were

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Muslims, some were not.

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Some of the institutions that developed had similarities with modern research

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universities in that they consisted of groups of academicians whose role was

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teaching. Often these institutions were associated with large hospitals or libraries

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such as that in Alexandria. Some historians claim that the University of al-Karaouine

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in Fes, Morocco is the oldest university in the world having been founded in 859.

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Another eminent institution was the al-Azhar University in Cairo which began in the

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10th century and offered academic degrees. One of the most notable scholars was

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Avicenna (c. 980-1037) who was born in Persia in what is now Uzbekistan. He wrote

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very influential textbooks including “The Canon of Medicine” and “The Book of

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Healing” and made contributions in many areas including pharmacology, physiology

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and infectious diseases.

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An important figure from the point of view of Galen’s teachings was Ibn al-Nafis

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(1213-1288) who was born in Damascus but spent much of his adult life in Cairo. He

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published a notable book titled “Commentary on Anatomy in Avicenna’s Canon” and

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this included one of the first challenges to Galen’s scheme of the cardiopulmonary

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system shown in Figure 3. Ibn al-Nafis stated very vigorously that blood could not

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pass through the interventricular septum because there are no invisible pores. The

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statement is important because it shows that although the academics of the Islamic

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Golden Age are mainly praised for their work in preserving the advances of the

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Greco-Roman schools, they also challenged some of Galen’s writings.

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It is not easy at first to understand how Galen’s writings developed such an

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enormous influence which lasted for 1300 years until the end of the sixteenth

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century. But it is a fact that the prodigious written output of the school became the

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official canon not only of medicine but of the Church itself. Remarkably his scientific

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edifice was seen as consistent with Christian dogma and indeed Galen’s authority

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became so great that people who challenged his doctrine could be branded heretical

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by both Church and State. His books were copied and re-copied by innumerable

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scribes before the dawn of printing and many manuscripts are still extant. The fact

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that Galen’s views were adopted as official canon of the Church is often not widely

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appreciated but it helps to explain why the Church reacted so violently to his critics

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such as Vesalius and Servetus when the European Renaissance began.

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Andreas Vesalius and the rebirth of anatomy and physiology

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One of the first big challenges to Galen’s teachings came from Andreas Vesalius

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(1514-1564) who published a splendid atlas of human anatomy in 1543 titled De

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humani corporis fabrica (On the fabric of the human body). This immediately

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challenged many of Galen’s conclusions and resulted in a sea change in thinking

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about human anatomy. Vesalius founded anatomy as a modern science by

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reestablishing the experimental method. This inspired people to throw off the

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encumbrances of theological dogma and start thinking again for themselves.

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Vesalius was born in Brussels, Belgium and received his early training in Louvain.

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He then moved to Paris where he carried out dissections, and when he was only 22

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he began to have doubts about some features of the Galenical texts. These attitudes

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worried his director, Joannes Guinterius, who was an ardent Galenist and other

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people as well. At the age of 23 Vesalius moved to the University of Padua where

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one of his responsibilities was to conduct dissections for both the students and also

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the public. The university had a famous steeply raked lecture room for anatomy

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demonstrations which was built in 1594 and which remarkably still exists.

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At the age of 28 Vesalius published his masterpiece De humani corporis fabrica, a

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magnificent production of nearly 700 pages. Many reproductions of the famous

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woodcuts exist. An accessible series is on the Web at https://tinyurl.com/k43mh3n.

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Another useful source is Saunders and O’Malley (17). Figure 4 shows one of the

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most famous plates. Note that the artist has decorated the rather stark illustration of

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anatomy with part of the Italian countryside. The genius of this book was that for

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the first time the structure of the human body was systematically described and

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accurately depicted in detailed images. It is interesting that the book was published

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in the same year as that by Nicolaus Copernicus’s De revolutionibus orbium

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coelestium (On the revolutions of the celestial spheres) that removed the earth from

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the center of the universe and thus helped to overturn the medieval teachings on

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cosmology.

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Vesalius’s masterpiece De humani corporis fabrica consists of seven books, the

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first being on bones and joints. An interesting tidbit is that a skeleton prepared by

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him is still extant. Vesalius was passing through Basel where his book had been

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printed several years before and he presented the skeleton to the University where

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it remains to this day and is probably the oldest anatomical preparation in existence.

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The seven books of De humani corporis fabrica deal with the skeleton, muscles,

395

vascular system, nervous system, abdominal viscera, heart and lungs, and brain

396

respectively. A number of differences from the structures described by the Galenical

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school are noted. Of particular interest to us are Vesalius’ comments on the

398

interventricular septum of the heart. Recall that in the Galenical scheme shown in

399

Figure 3, part of the blood from the right ventricle was thought to enter the left

400

through pores in the septum. However in the second edition of De humani, Vesalius

401

wrote “Not long ago I would not have dared to turn aside even a nail’s breadth from

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the opinion of Galen the prince of physicians... But the septum of the heart is as

403

thick, dense, and compact as the rest of the heart. I do not, therefore, know... in what

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way even the smallest particle can be transferred from the right to the left ventricle

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through the substance of the septum...” (18).

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Vesalius was subjected to a number of attacks because his great book challenged

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the accepted views of Galen and the Church. At one stage the Emperor Charles V set

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up an inquiry to determine the religious errors in his work, and although Vesalius

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was not found guilty at that time, some attacks continued. Many people were

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unwilling to accept the new anatomy and clung to the teachings of Galen. A

411

remarkable rebuke came from Jacobus Sylvius (1478-1555) with whom Vesalius

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412

had worked in Paris and who was an ardent Galenist. Sylvius stated in writing that

413

the anatomy of the human body must have changed since Galen described it!

414 415

Michael Servetus and his assertion of the pulmonary transit of blood

416

Interestingly Vesalius did not remark on the possibility of the movement of the

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blood from the right to the left side of the heart through the lungs, although Galen

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recognized this as did Ibn al-Nafis. However a famous early statement of the

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pulmonary transit was made by Michael Servetus (1511-1553) who was a physician,

420

physiologist and theologian. He was born in Villeneuve in northern Spain and

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studied law in Toulouse in southern France at the university there. Later he traveled

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to Paris to study medicine where his teachers included the anatomist Jacobus

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Sylvius, known for aqueduct of Sylvius in the brain, and Jean Fernel who apparently

424

was the first person to introduce the term “physiology” into medicine.

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Servetus has the distinction of being the first European to state categorically that

426

blood could not pass through the interventricular septum and, in keeping with this,

427

that it moved from the pulmonary artery to the pulmonary vein. This was the first

428

assertion of the pulmonary transit. Curiously, the statement was made in a

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theological context in his book Christianismi Restitutio (The Restoration of

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Christianity). Servetus was concerned with how the God-given spirit could be

431

spread throughout the human body. He argued that it did this by entering the blood

432

in the lungs and was thus delivered to the left ventricle and from here to the rest of

433

the body. He wrote about the pulmonary blood flow as follows “However, this

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communication [from the right to the left ventricle] is made not through the middle

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435

wall of the heart, as is commonly believed, but by a very ingenious arrangement the

436

refined blood is urged forward from the right ventricle of the heart over a long

437

course through the lungs; it is treated by the lungs, becomes reddish-yellow and is

438

poured from the pulmonary artery into the pulmonary vein” (13). As we have seen,

439

Ibn al-Nafis made a similar statement 200 years earlier but it was probably not

440

known to Servetus.

441

The writings of Servetus were very confrontational in many ways and he was

442

accused of heresy by both the Church of Rome and the Protestant Calvinists. The

443

main theological issue was that he believed that the manifestation of God in Jesus

444

occurred at the moment of conception and was not eternal. He therefore referred to

445

Christ as “the Son of the eternal God” rather than “the eternal Son of God”. For this

446

heresy he was condemned to be burned at the stake. The great physician William

447

Osler (14) described the terrible event as follows. In the procession to the place of

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execution Servetus was exhorted by the pastor accompanying him to change his

449

statement about Christ. After being bound to the stake he cried out “Jesus, thou son

450

of the eternal God, have mercy upon me” but the fire was lit and he perished.

451

Strange, is it not, that could he have cried, “Jesu, thou eternal Son of God” even at

452

this last moment he would have been spared. Such were the monstrous attitudes of

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those times.

454

This ghastly episode in the chronicle of man’s inhumanity to man reminds us of

455

one more that took place about one hundred years later. Galileo Galilei (1564-1642),

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having observed the moons circling Jupiter, promoted the heliocentric view of the

457

world first suggested by Copernicus in the same year as the publication of De

18

458

humani corporis fabrica. As a result, the Holy Office of the Inquisition ordered

459

Galileo to stand trial. He was found vehemently suspected of heresy, he was shown

460

the instruments of torture, he was required to abjure, curse and detest his views, he

461

was forbidden to publish anymore, and he remained under house arrest for the rest

462

of his life. Little had changed in the hundred years.

463

William Harvey and the beginnings of modern physiology

464

William Harvey (1578-1657) is a convenient figure with which to announce the

465

emergence of modern physiology. The publication of Exercitatio anatomica de motu

466

cordis et sanguinis in animalibus (An anatomical exercise on the motion of the heart

467

and blood in living beings) in 1628 describing the circulation of the blood was a

468

turning point in the history of physiology. The book was an example of the vigorous

469

use of scientific method and the result was an abrupt acceleration of knowledge.

470

During the ensuing 50 years a host of new advances in physiology were made and

471

men such as Torricelli, Pascal, Boyle, Hooke, Malpighi, Lower, and Mayow all made

472

important contributions. The attitudes towards hypothesis, experimental data, and

473

other evidence were very different from the situation one hundred years before.

474

Having said this, it should not be thought that physiologists of the 17th century

475

necessarily made a clean break with the past. For example John Aubrey (1626-

476

1697) was a well-known writer, and his selection of biographies known as Brief

477

Lives contained colorful accounts of many 17th-century luminaries. He met Harvey

478

on several occasions in Oxford and elsewhere and in 1651 when Aubrey was

479

contemplating a trip to Italy he wrote the following. “He [Harvey] was very

480

communicative and willing to instruct any that were modest and respectful to him.

19

481

And in order to my journey gave me, that is dictated to me, what company to keep,

482

what bookes to read, how to manage my studies; in short, he bid me goe to the

483

fountain head and read Aristotle, Cicero, Avicen [Avicenna], and did call the

484

neoteriques shitt-breeches” (10). Neoteriques referred to people with the latest

485

ideas.

486

Finally it should be noted that although there was a great renaissance in

487

physiology in the 17th century, vestiges of Galenism lasted well into the 18th and

488

even 19th centuries. Bloodletting continued to be prescribed although increasingly

489

leeches were used rather than venesection. Indeed there are images of bloodletting

490

by venesection as late as 1860. Even today venesection is occasionally used for

491

diseases such as hemachromatosis and polycythemia although of course the reason

492

is not because of the humoral theory.

493

In conclusion, Galen was a key figure in the early history of Western physiology.

494

The voluminous writings of his school were based on the advances of the classical

495

Greeks including Hippocrates and Aristotle. An extraordinary feature of the

496

Galenical school was that its influence on medicine and physiology lasted some

497

1300 years right up to the European Renaissance. One of the first challenges to the

498

teachings of the school came from Andreas Vesalius who produced a magnificent

499

book on human anatomy. Finally in the early 17th century William Harvey used

500

modern scientific methods including hypotheses and reliance on experimental

501

findings. This resulted in an enormous acceleration of new knowledge in the mid-

502

17th century. However vestiges of Galen’s teachings could still be seen in the 19th

20

503

century. It is not easy to find another example of a school whose teachings had such

504

a long-lived influence as that of Galen.

505 506 507 508 509 510 511 512 513 514 515 516 517 518 519 520 521 522 523 524 525

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526

References

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1. Aristotle. De Partibus Animalium. Oxford, UK: Clarendon, 1911, p. 658b.

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2. Boylan M. Galen (130-200 C.E.) In The Internet Encyclopedia of Philosophy

529 530 531 532 533

http://www.iep.utm.edu/galen/ 3. Fleming D. Galen on the motions of the blood in the heart and lungs. Isis 46: 1421, 1955. 4. Fulton JF. Michael Servetus, Humanist and Martyr. New York: Herbert Reichner, 1953.

534

5. Haldane JS and Priestly JG. Respiration (preface). Oxford: Clarendon Press, 1935.

535

6. Harvey W. Exercitatio anatomica de motu cordis et sanguinis in animalibus.

536 537 538

Frankfurt: William Fitzer, 1628. 7. Harvey W. The Works of William Harvey, translated by Willis R. Philadelphia, PA: Univ. of Pennsylvania Press, 1989.

539

8. Hippocrates. Aphorisms. Translated by Thomas Coar. London: Valpy, 1822.

540

9. Kanz F and Grossschmidt K. Head injuries of Roman gladiators. Forensic Sci Int

541

160: 207-216, 2006.

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10. Keynes G. The Life of William Harvey. Oxford: Clarendon Press, 1966.

543

11. Kühn KG (ed). Medicorum Graecorum opera quae exstant. Leipzig: C. Cnobloch,

544

1821-1833.

545

12. Nutton V. From Democedes to Harvey. London: Variorum Reprints, 1988.

546

13. O’Malley CD. Michael Servetus. Philadelphia: American Physiological Society,

547 548

1953. 14. Osler W. Michael Servetus. London: Oxford University Press, 1909.

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549 550

15. Plato. Timaeus, c. 360 BC. Translation from: Thomson T. Chemistry of Animal Bodies. Edinburgh: Adam and Charles Black, 1843, p. 604.

551

16. Proctor DF. A history of breathing physiology. New York: Dekker, 1995.

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17. Saunders CM, O’Malley CD. The Illustrations From the Works of Andreas Vesalius

553

of Brussels; With Annotations and Translations, A Discussion of the Plates and

554

Their Background, Authorship and Influence, and A Biographical Sketch of

555

Vesalius. Cleveland, OH: World Pub. Co., 1950.

556

18. Singer C. The discovery of the circulation of the blood. London: Bell, 1922.

557

19. Singer C. A short history of anatomy and physiology from the Greeks to Harvey.

558

New York: Dover Publications, 1957.

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20. Singer C. A short history of scientific ideas to 1900. London: Oxford, 1959.

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21. Vesalius A. De humani corporis fabrica. Basel: Joannis Oporini, 1543.

561 562 563 564 565 566 567 568 569 570 571

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Figure captions

573

Figure 1

574

Galen of Pergamon (Claude Galien in French). Lithograph by Pierre Roche Vigneron,

575

Paris ca. 1865.

576 577

Figure 2

578

The Ladder of Nature (scala naturae) of Aristotle demonstrating the great breadth of

579

his interests in the whole animal kingdom, plants and inanimate materials. From

580

(19) by permission.

581 582

Figure 3

583

Galen’s cardiopulmonary system which held sway for 1300 years. During

584

inspiration, pneuma entered the lung through the trachea and reached the left

585

ventricle via the pulmonary vein. Blood was formed in the liver, and imbued there

586

with natural spirit, and entered the right ventricle. Most then entered the lung but a

587

portion passed through minute channels in the interventricular septum to the left

588

ventricle. Here vital spirit was added and this was distributed through arteries to

589

the rest of the body. The blood that reached the brain was charged with animal

590

spirit which was distributed through the hollow nerves. From (19) by permission.

591 592 593 594

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595

Figure 4

596

Typical woodcut from De humani corporis fabrica by Vesalius. From (21).

597 598

Figure 5

599

Michael Servetus (1511-1553). He was the first European to describe the pulmonary

600

transit and was burned at the stake for heresy as indicated in the upper part of the

601

image. From an engraving by Christian Friedrich Fritzsch (1719-1774).

602 603

Figure 6

604

Title page of William Harvey’s book Exercitatio anatomica de motu cordis et

605

sanguinis in animalibus. From (6).

606 607 608 609 610 611 612 613 614 615 616

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