Iatrophysics

Last updated
A page from Giovanni Borelli's De Motu Animalium, showing how various simple machines can be used to model different limbs Giovanni Borelli - lim joints (De Motu Animalium).jpg
A page from Giovanni Borelli's De Motu Animalium, showing how various simple machines can be used to model different limbs

Iatrophysics or iatromechanics (fr. Greek) is the medical application of physics. It provides an explanation for medical practices with mechanical principles. [1] It was a school of medicine in the seventeenth century which attempted to explain physiological phenomena in mechanical terms. Believers of iatromechanics thought that physiological phenomena of the human body followed the laws of physics. [2] It was related to iatrochemistry in studying the human body in a systematic manner based on observations from the natural world though it had more emphasis on mathematical models rather than chemical processes.

Contents

Background

The Age of Enlightenment was an era of radically changing ways of thought in Western politics, philosophy, and science. Major sociological changes occurred in the Enlightenment, as well as industrial and scientific. In medicine, the Enlightenment brought several discoveries and studies that were impacted by changing ways of thought. For example, capillaries were discovered by Marcello Malpighi. Jan Baptist van Helmont (1580–1644) was the first to consider digestion a fermentation process and identified hydrochloric acid in the stomach. Pathological anatomy and clinical observation were also being integrated into the medical curriculum. The Enlightenment also directly influenced the field of iatrophysics through the development of Antonie von Leeuwenhoek's microscope, the advancement of the field of ophthalmology through the use of physics by René Descartes, and Newton's law of universal gravitation, idea of gravitational force, and his treatise Opticks . [3]

Subfields

Iatrophysicists drew inspiration from various established physical phenomena in order to explain how certain biological processes took place and how this can be applied towards medicine.

Particles

A key component of iatrophysical anatomy was the study of particles. This was particularly influenced by 17th century developments in microbiology, the most prominent being the microscope. Antonie von Leeuwenhoeck was a Dutch scientist who is known for his use of the microscope for identifying single-celled organisms. He was also the first to observe muscle fibers, bacteria, spermatozoa and blood flow in capillaries. [4] Another famous figure in microbiology at the time was Robert Hooke, an English scientist most famous for his use of the microscope for the discovery of cells. [5] In his most famous work, Micrographia (1665), he attributed “occult properties” as elementary “contrivances of nature”. Like Galileo Galilei, he shared an iatrophysical viewpoint and saw living organisms as groups of small machines. The development of the microscope was largely influential in this view. [6]

Mechanics

Machines were used as models by Iatrophysicists to quantitatively describe linear and rotational motion of various biological systems such as human limbs and animals. Some models came into existence before Isaac Newton's formulation of his three laws in classical mechanics, drawing on basic principles of statics and dynamics to represent how a biological system behaved. Giovanni Borelli was prolific in applying mechanics to a wide variety of humans and animals in different degrees of activity, drawing upon an array of simple machines and models for translational and rotational motion and equilibrium. [7] [8] [9]

Fluids

Iatrophysicists were also interested in studying how bodily liquids and gases were processed. They sought to understand how blood circulated throughout the body and what effects it made on the body. System consisted of arteries, veins, and vasculature verified through experiment and microscope by Marcello Malpighi's observations of capillaries in animal lung tissue. Albrecht von Haller, as did Borelli, postulated that friction from the blood on vessel walls lead to body heat and even fever. A hydraulic model for motion by René Descartes implied the body had a system that maintained flow between the brain and muscles in equilibrium state through nerves and blood vessels. [8]

Iatrophysicists

Starting in the 17th century, quantitative fields such as physics and mathematics began gaining legitimacy as a means of studying the natural world with the advent of theory, practices, and instruments. Static principles and simple machines were already in use to create various objects and buildings and thus were established tools that could be used to inspire models of biological systems. The development of medical instruments and techniques, such as the microscope and detailed dissections, changed how natural philosophers thought about how to explain the human body's properties. By enabling more detailed study of aspects of biology, let alone the human body, instrumentation and methods to directly study organic tissue allowed more opportunities for natural philosophers, Iatrophysicists in this case, to postulate and verify their theories. With inspiration from established explanations of natural phenomena and new informative means to study the human body available, iatrophysicists aimed to describe the human body and assert their explanation of various systems of the human body.

One example is the muscle and contraction. Various explanations on a macroscopic and microscopic scale were made to explain how muscles contracted and thus performed movements together. On a macroscopic scale through observation and anatomy, some iatrophysicists such as Borelli focused on explaining how muscles worked in conjunction together to form movements with dynamics or physical models. On a microscopic scale via observation and dissection, the contractility of muscle was to be explained by pneumatic expansion, a popular explanation supported by Descartes and Borelli, or inherent shape deformation, postulated by Nicolas Steno and Albrecht von Haller to an extent, based upon principles of fluids and statics. Other aspects of the human body such as circulation and digestion saw a number of explanations, and thus conflicting views based on the methodology used to derive and obtain an explanation, arise in the 17th and 18th centuries.

Prominent Iatrophysicists

One prominent iatrophysicist was Giovanni Borelli, who modeled the human body, various animals, and their motions using mechanical principles. [7] [10] A colleague of Marcello Malphigi, Borelli was a mathematician who made connections between what he observed in living things and inanimate but relatively simple systems. He dissected animals and examined how muscles were to increase mechanical advantage, observed how a variety of living things performed different movements and activities such as running, carrying loads, swimming, and flying naturally rather than by his intervention, and devised simple methods to calculate a person's center of mass. He also devised relatively simple experiments and devices to make his observations such as a plank and rod for center of mass and a spirometer for volume of air. At the end of his life, his work culminated in De Motu Animalium (1679), a publication showcasing his investigations in similarities and differences in muscles across living things and his understanding of the underlying mechanism of muscle contraction, expansion via influx of fluids or gases released from nerves. He also attempted to describe more complicated processes such as nerve transmission and digestion. [8] [11]

Another notable iatrophysicist was the French philosopher and mathematician René Descartes, who, as a consequence of his philosophy asserting that the human body and soul are two dual entities, treated the human body as a machine that could be quantified, disassembled, and studied. He attempted to model various phenomena such as the brain, movement, sleep, circulation, and senses with analogies to inanimate objects such as reservoirs, pipes, lenses and steam engines that often sought to maintain an equilibrium for certain states. Some of his claims often were independent of physical observation of the organ or body in question and emphasized what he deemed as "simple" or "rational" rather than reality. For example, he asserts that blood circulates throughout the body by expanding as vapor by the heart's heat rather than from contraction. [7] [8]

William Harvey postulated blood flow as a closed, continuous loop that run throughout body that contained a certain quantity of blood. To test his claim, Harvey dissected human corpses and animals and, based on his anatomical findings, devised a simple demonstration of how arteries and veins continuously carried blood throughout the body. Taking advantage of the fact that arteries and veins were at different depths below the skin, he tied a person's arm and had them squeeze a bar to shunt blood from arteries to veins, indicating that blood somehow traveled along arteries and into veins. His claim was elucidated by Malphigi's discovery of capillaries and how they were interconnected with arteries and veins. [7] [8]

One of the most influential iatrophysicists was Hermann Boerhaave, a Dutch physician and chemist at the Leiden University. Like other iatrophysicists, he viewed physiology as a mechanism. While he disagreed with the idea that the body and the mind were connected, he attributed everything related to the body to extension, impenetrability, or motion. [6]

Francis Glisson was known for his work on circulation of the blood, the mechanisms of the nervous system, and hereditary diseases. He was largely influenced by Harvey's work on the sentient nature of blood and his work demonstrates iatrophysical ideology particularly through his views of attraction and irritability, or the concept of how the body fibers react to irritation. In his work, Anatomia hepatis, he argues that branches cross, and carried blood is separated in the liver. This in turn is sucked up by biliary vessels through an attraction that Glisson attributes as similar, magnetic, or natural. [12]

Albrecht von Haller was another prominent iatrophysicist, who like Glisson, focused on physiology as mechanisms of body fibers. He shared Glisson's views on irritability, but unlike Glisson, attributed the reaction to external stimuli solely to body fibers, and not in the inherent power of matter as Glisson had suggested. In his work Physiologiae Corporis Humani (1757–1766), he described organs and muscles of the body as interwoven fibers. His viewpoints on muscles were that they had a contractile tendency which he termed vis mortua, or dead power. He attributed this muscle contraction to irritability, which he described as being an inherent power. He particularly made the distinction between irritability and sensibility, irritability being the power of muscular contraction and sensibility being nerve impulse. Therefore, a part was irritable if it contracted upon contact, and sensible if the contact impacted the mind. [6]

Other Iatrophysicists

Santorio Santorio was a Venetian doctor who, in attempt to quantify human digestion, carefully measured his food/water intake and excretion weight over many years. To establish a mathematical relationship between food/water intake and excretion, Santorius designed a special chair that had a balance that weighed a subject's meal and consequent excrement. Based on these measurements, he then calculated the net change in weight for each day. In addition to knowing what he took in, he also analyzed the contents of his excretions and secretions, categorizing it by type and origin. He also made other clinical instruments to measure other medical quantities such as temperature and pulse. [7] [8]

Nicolas Steno was a Danish scientist who developed a purely mechanical and geometrical model of muscle. In this model, he treated a muscle as an interwoven yet simple network of long fibers, forming a uniform and robust geometric shape. Contraction was then explained as the reshaping of this network to either shorten or lengthen along one direction, thus the muscle changed shape at a fixed volume by only changing the angles between each fibre. This explanation of contraction, and his consequent theory that the heart contracted by many of its fibers shortening and lengthening, was considered radical. The most popular explanation, supported by well known Iatrophysicists such as Descartes and Borelli, asserted that the heart contracted from its fibers inflating themselves through a chemical reaction. [8] [13]

Relationship with Iatrochemistry

Similar to iatrophysics, iatrochemistry was a school of thought that related medicine and anatomy to chemistry, instead of mechanics. Iatrophysics and iatrochemistry were closely related. Many prominent iatrophysicists such as Borelli and Descartes utilized chemistry in order to explain physiological processes. Particularly, Franciscus Sylvius was an adamant believer in chemical processes as an explanation for the body. He emphasized fermentation and effervescence for the input of chemistry and circulation into physiology. [6]

Iatrochemistry and iatrophysics had similar ways of thinking, and went hand-in-hand in many aspects. But they also conflicted at times. For example, the concept of fermentation arose from an iatrochemical background. Like the Parisian apothecary Henri Louis de Rouvière, who connected fermentation with health in his book titled: Reflexions sur la Fermentation, et sur la Nature du Feu (1708). However, this publication also dismissed the relationship of mechanics with health and the mechanistic model of the body. Another conflict arose in explanation of digestion. While iatrophysicists explained the event through mechanistic terms, iatrochemists argued for fermentation as the reason for the digestive processes in the body. Furthermore, while iatrophysicists rejected acid-base theory as an explanation for bodily processes, iatrochemists embraced the theory. [14]

Influence on Medicine

In the Middle Ages, Galenic anatomo-physiology prevailed as the leading medical thought. Furthermore, Aristotelian natural philosophy had dominated for centuries, including the humoral system as a primary method of medical thought. However, the philosophies of Aristotle, Hippocrates, and Galen began to wane in popularity, replaced by anatomical and philosophical schools of thought based on mechanics and chemical naturalism. Ideologies such as iatrophysics and iatrochemistry began to prevail. The decline of Galenic philosophy-based medicine coupled with the rise of new ideologies was spurred by the advent of new discoveries in anatomy and physiology, such as that of William Harvey's work centered on circulation of the blood. His idea that pulse, respiration, and nutrition were all working components of a unified system revolutionized preexisting ideas about blood, nutrition, and heat. The discovery of the circulation of the blood was crucial in the development of iatrophysics in that it was the first that related “circulations” to physiological functions. This led to the advent of new discoveries such as the circulation of nutritive fluid, circulation of lymph, and circulation of nervous juice, all of which relate a machine-like mechanism to anatomy. [6]

Traditionally, physiological functions were believed to be regulated by purposeful tendencies. However, the advent of the new medicinal schools of thought transformed the way physiology was approached. Secretion and excretion were no longer due to attractive tendencies, the function of the lungs were now due to the mixing of different parts of the blood, digestion was seen as a process of grinding and mincing, and health and disease were associated with movement, obstruction, and stagnation of the various bodily fluids running through the body. The body increasingly became viewed as a function of a machine, especially with the development of Isaac Newton's theory of gravitation and motion. Newtonian physics came to widely influence the way the body was viewed, and physiology was increasingly focused on a clockwork mechanism, and the later hydraulics was even applied to the movement of bodily fluids. Furthermore, with the publication of Newton's Opticks in 1704, physiologists increasingly depended on the notions of ether and effluvia in their anatomical observations. [6]

Related Research Articles

<span class="mw-page-title-main">Aorta</span> Largest artery in the human body

The aorta is the main and largest artery in the human body, originating from the left ventricle of the heart, branching upwards immediately after, and extending down to the abdomen, where it splits at the aortic bifurcation into two smaller arteries. The aorta distributes oxygenated blood to all parts of the body through the systemic circulation.

<span class="mw-page-title-main">Marcello Malpighi</span> Italian biologist and physician

Marcello Malpighi was an Italian biologist and physician, who is referred to as the "Founder of microscopical anatomy, histology & Father of physiology and embryology". Malpighi's name is borne by several physiological features related to the biological excretory system, such as the Malpighian corpuscles and Malpighian pyramids of the kidneys and the Malpighian tubule system of insects. The splenic lymphoid nodules are often called the "Malpighian bodies of the spleen" or Malpighian corpuscles. The botanical family Malpighiaceae is also named after him. He was the first person to see capillaries in animals, and he discovered the link between arteries and veins that had eluded William Harvey. Malpighi was one of the earliest people to observe red blood cells under a microscope, after Jan Swammerdam. His treatise De polypo cordis (1666) was important for understanding blood composition, as well as how blood clots. In it, Malpighi described how the form of a blood clot differed in the right against the left sides of the heart.

<span class="mw-page-title-main">Artery</span> Blood vessels that carry blood away from the heart

An artery is a blood vessel in humans and most animals that takes blood away from the heart to one or more parts of the body. Most arteries carry oxygenated blood; the two exceptions are the pulmonary and the umbilical arteries, which carry deoxygenated blood to the organs that oxygenate it. The effective arterial blood volume is that extracellular fluid which fills the arterial system.

<span class="mw-page-title-main">Heart</span> Organ found inside most animals

The heart is a muscular organ in most animals. This organ pumps blood through the blood vessels of the circulatory system. The pumped blood carries oxygen and nutrients to the body, while carrying metabolic waste such as carbon dioxide to the lungs. In humans, the heart is approximately the size of a closed fist and is located between the lungs, in the middle compartment of the chest, called the mediastinum.

<span class="mw-page-title-main">Blood vessel</span> Tubular structure of the circulatory system which transports blood

Blood vessels are the components of the circulatory system that transport blood throughout the human body. These vessels transport blood cells, nutrients, and oxygen to the tissues of the body. They also take waste and carbon dioxide away from the tissues. Blood vessels are needed to sustain life, because all of the body's tissues rely on their functionality.

<span class="mw-page-title-main">Human body</span> Entire structure of a human being

The human body is the structure of a human being. It is composed of many different types of cells that together create tissues and subsequently organ systems. They ensure homeostasis and the viability of the human body.

<span class="mw-page-title-main">Circulatory system</span> Organ system for circulating blood in animals

The blood circulatory system is a system of organs that includes the heart, blood vessels, and blood which is circulated throughout the entire body of a human or other vertebrate. It includes the cardiovascular system, or vascular system, that consists of the heart and blood vessels. The circulatory system has two divisions, a systemic circulation or circuit, and a pulmonary circulation or circuit. Some sources use the terms cardiovascular system and vascular system interchangeably with the circulatory system.

<span class="mw-page-title-main">Esophagus</span> Vertebrate organ through which food passes to the stomach

The esophagus or oesophagus, colloquially known also as the food pipe or gullet, is an organ in vertebrates through which food passes, aided by peristaltic contractions, from the pharynx to the stomach. The esophagus is a fibromuscular tube, about 25 cm (10 in) long in adults, that travels behind the trachea and heart, passes through the diaphragm, and empties into the uppermost region of the stomach. During swallowing, the epiglottis tilts backwards to prevent food from going down the larynx and lungs. The word oesophagus is from Ancient Greek οἰσοφάγος (oisophágos), from οἴσω (oísō), future form of φέρω + ἔφαγον.

Systole is the part of the cardiac cycle during which some chambers of the heart contract after refilling with blood.

<span class="mw-page-title-main">Cremaster muscle</span> Muscle covering the testis and spermatic cord

The cremaster muscle is a paired structure made of thin layers of striated and smooth muscle that covers the testis and the spermatic cord in human males. It consists of the lateral and medial parts. Cremaster is an involuntary muscle, responsible for the cremasteric reflex; a protective and physiologic superficial reflex of the testicles. The reflex raises and lowers the testicles in order to keep them protected. Along with the dartos muscle of the scrotum, it regulates testicular temperature, thus aiding the process of spermatogenesis.

<span class="mw-page-title-main">Cardiac muscle</span> Muscular tissue of heart in vertebrates

Cardiac muscle is one of three types of vertebrate muscle tissues, with the other two being skeletal muscle and smooth muscle. It is an involuntary, striated muscle that constitutes the main tissue of the wall of the heart. The cardiac muscle (myocardium) forms a thick middle layer between the outer layer of the heart wall and the inner layer, with blood supplied via the coronary circulation. It is composed of individual cardiac muscle cells joined by intercalated discs, and encased by collagen fibers and other substances that form the extracellular matrix.

<span class="mw-page-title-main">Pulmonary circulation</span> Part of the circulatory system which carries blood from heart to lungs and back to the heart

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.

<span class="mw-page-title-main">Striated muscle tissue</span> Muscle tissue with repeating functional units called sarcomeres

Striated muscle tissue is a muscle tissue that features repeating functional units called sarcomeres. The presence of sarcomeres manifests as a series of bands visible along the muscle fibers, which is responsible for the striated appearance observed in microscopic images of this tissue. There are two types of striated muscle:

<span class="mw-page-title-main">Cardiac conduction system</span> Aspect of heart function

The cardiac conduction system(CCS) (also called the electrical conduction system of the heart) transmits the signals generated by the sinoatrial node – the heart's pacemaker, to cause the heart muscle to contract, and pump blood through the body's circulatory system. The pacemaking signal travels through the right atrium to the atrioventricular node, along the bundle of His, and through the bundle branches to Purkinje fibers in the walls of the ventricles. The Purkinje fibers transmit the signals more rapidly to stimulate contraction of the ventricles.

<span class="mw-page-title-main">Theodor Schwann</span> German physiologist (1810–1882)

Theodor Schwann was a German physician and physiologist. His most significant contribution to biology is considered to be the extension of cell theory to animals. Other contributions include the discovery of Schwann cells in the peripheral nervous system, the discovery and study of pepsin, the discovery of the organic nature of yeast, and the invention of the term "metabolism".

<span class="mw-page-title-main">Soleus muscle</span> Powerful muscle in the back part of the lower leg

In humans and some other mammals, the soleus is a powerful muscle in the back part of the lower leg. It runs from just below the knee to the heel, and is involved in standing and walking. It is closely connected to the gastrocnemius muscle and some anatomists consider them to be a single muscle, the triceps surae. Its name is derived from the Latin word "solea", meaning "sandal".

<span class="mw-page-title-main">Iatrochemistry</span> Early modern branch of medicine

Iatrochemistry is a branch of both chemistry and medicine. Having its roots in alchemy, iatrochemistry seeks to provide chemical solutions to diseases and medical ailments.

<span class="mw-page-title-main">Ibn al-Nafis</span> Arab polymath and physician (1213–1288)

ʿAlāʾ al-Dīn Abū al-Ḥasan ʿAlī ibn Abī Ḥazm al-Qarashī al-Dimashqī, known as Ibn al-Nafīs, was an Arab polymath whose areas of work included medicine, surgery, physiology, anatomy, biology, Islamic studies, jurisprudence, and philosophy. He is known for being the first to describe the pulmonary circulation of the blood. The work of Ibn al-Nafis regarding the right sided (pulmonary) circulation pre-dates the later work (1628) of William Harvey's De motu cordis. Both theories attempt to explain circulation. 2nd century Greek physician Galen's theory about the physiology of the circulatory system remained unchallenged until the works of Ibn al-Nafis, for which he has been described as "the father of circulatory physiology".

<span class="mw-page-title-main">Cardiac cycle</span> Performance of the human heart

The cardiac cycle is the performance of the human heart from the beginning of one heartbeat to the beginning of the next. It consists of two periods: one during which the heart muscle relaxes and refills with blood, called diastole, following a period of robust contraction and pumping of blood, called systole. After emptying, the heart relaxes and expands to receive another influx of blood returning from the lungs and other systems of the body, before again contracting to pump blood to the lungs and those systems. A normally performing heart must be fully expanded before it can efficiently pump again. Assuming a healthy heart and a typical rate of 70 to 75 beats per minute, each cardiac cycle, or heartbeat, takes about 0.8 second to complete the cycle. There are two atrial and two ventricle chambers of the heart; they are paired as the left heart and the right heart—that is, the left atrium with the left ventricle, the right atrium with the right ventricle—and they work in concert to repeat the cardiac cycle continuously. At the start of the cycle, during ventricular diastole–early, the heart relaxes and expands while receiving blood into both ventricles through both atria; then, near the end of ventricular diastole–late, the two atria begin to contract, and each atrium pumps blood into the ventricle below it. During ventricular systole the ventricles are contracting and vigorously pulsing two separated blood supplies from the heart—one to the lungs and one to all other body organs and systems—while the two atria are relaxed. This precise coordination ensures that blood is efficiently collected and circulated throughout the body.

Balloonist theory was a theory in early neuroscience that attempted to explain muscle movement by asserting that muscles contract by inflating with air or fluid. The Greek physician Galen believed that muscles contracted due to a fluid flowing into them, and for 1500 years afterward, it was believed that nerves were hollow and that they carried fluid. René Descartes, who was interested in hydraulics and used fluid pressure to explain various aspects of physiology such as the reflex arc, proposed that "animal spirits" flowed into muscle and were responsible for their contraction. In the model, which Descartes used to explain reflexes, the spirits would flow from the ventricles of the brain, through the nerves, and to the muscles to animate the latter.

References

  1. Bynum, W.F. (1994). Science and the Practice of Medicine in the Nineteenth Century. Cambridge: Cambridge University Press. p. 93. ISBN   9780521272056.
  2. Lindemann, Mary (2010). Medicine and Society in Early Modern Europe. Cambridge: Cambridge University Press. p. 105. ISBN   9780521732567.
  3. admin (3 December 2013). "The enlightenment era-importance & impact in history of medicine | Homeopathy Resource by Homeobook.com". www.homeobook.com. Retrieved 2017-03-24.
  4. "History of the microscope.org – Its all about microscope history". www.history-of-the-microscope.org. Retrieved 2017-03-03.
  5. "UCMP – University of California Museum of Paleontology". www.ucmp.berkeley.edu. Retrieved 2017-03-03.
  6. 1 2 3 4 5 6 "Anatomy and Physiology – Dictionary definition of Anatomy and Physiology | Encyclopedia.com: FREE online dictionary". www.encyclopedia.com. Retrieved 2017-03-03.
  7. 1 2 3 4 5 Lindemann, Mary (2010). Medicine and Society in Early Modern Europe. Cambridge: Cambridge University Press. pp. 96–97, 105–106. ISBN   9780521732567.
  8. 1 2 3 4 5 6 7 Lutz, Peter (2002). The Rise of Experimental Biology . Totawa, New Jersey: Humana Press. pp.  96–103. ISBN   0-89603-835-1.
  9. Maquet, Paul (1992). "Iatrophysics to Biomechanics: From Borelli (1608–1679) TO PauwelsS (1885–1980)" (PDF). The Journal of Bone and Joint Surgery. British Volume. 74-B (3): 335–337. doi:10.1302/0301-620x.74b3.1587872. PMID   1587872.
  10. Humphrey, J. D. (2003-01-08). "Review Paper: Continuum biomechanics of soft biological tissues". Proceedings of the Royal Society of London A: Mathematical, Physical and Engineering Sciences. 459 (2029): 3–46. CiteSeerX   10.1.1.729.5207 . doi:10.1098/rspa.2002.1060. ISSN   1364-5021. S2CID   108637580.
  11. Maquet, Paul (1992). "Iatrophysics to Biomechanics: From Borelli (1608–1679) TO PauwelsS (1885–1980)" (PDF). The Journal of Bone and Joint Surgery. British Volume. 74-B (3): 335–337. doi:10.1302/0301-620x.74b3.1587872. PMID   1587872.
  12. "Francis Glisson facts, information, pictures | Encyclopedia.com articles about Francis Glisson". www.encyclopedia.com. Retrieved 2017-03-03.
  13. Perrini, Paolo; Lanzino, Giuseppe; Parenti, Giuliano Francesco (2010-07-01). "Niels Stensen (1638–1686): Scientist, Neuroanatomist, and Saint". Neurosurgery. 67 (1): 3–9. doi:10.1227/01.neu.0000370248.80291.c5. ISSN   0148-396X. PMID   20559086. S2CID   25853167.
  14. Debus, Allen George (2002-08-15). The French Paracelsians: The Chemical Challenge to Medical and Scientific Tradition in Early Modern France. Cambridge University Press. ISBN   9780521894449.

Further reading