Loading
  • 21 Aug, 2019

  • By, Wikipedia

Anatomist

Anatomy (from Ancient Greek ἀνατομή (anatomḗ) 'dissection') is the branch of morphology concerned with the study of the internal structure of organisms and their parts. Anatomy is a branch of natural science that deals with the structural organization of living things. It is an old science, having its beginnings in prehistoric times. Anatomy is inherently tied to developmental biology, embryology, comparative anatomy, evolutionary biology, and phylogeny, as these are the processes by which anatomy is generated, both over immediate and long-term timescales. Anatomy and physiology, which study the structure and function of organisms and their parts respectively, make a natural pair of related disciplines, and are often studied together. Human anatomy is one of the essential basic sciences that are applied in medicine, and is often studied alongside physiology.

Anatomy is a complex and dynamic field that is constantly evolving as discoveries are made. In recent years, there has been a significant increase in the use of advanced imaging techniques, such as MRI and CT scans, which allow for more detailed and accurate visualizations of the body's structures.

The discipline of anatomy is divided into macroscopic and microscopic parts. Macroscopic anatomy, or gross anatomy, is the examination of an animal's body parts using unaided eyesight. Gross anatomy also includes the branch of superficial anatomy. Microscopic anatomy involves the use of optical instruments in the study of the tissues of various structures, known as histology, and also in the study of cells.

The history of anatomy is characterized by a progressive understanding of the functions of the organs and structures of the human body. Methods have also improved dramatically, advancing from the examination of animals by dissection of carcasses and cadavers (corpses) to 20th-century medical imaging techniques, including X-ray, ultrasound, and magnetic resonance imaging.

Etymology and definition

A dissected body, lying prone on a table, by Charles Landseer

Derived from the Greek ἀνατομή anatomē "dissection" (from ἀνατέμνω anatémnō "I cut up, cut open" from ἀνά aná "up", and τέμνω témnō "I cut"), anatomy is the scientific study of the structure of organisms including their systems, organs and tissues. It includes the appearance and position of the various parts, the materials from which they are composed, and their relationships with other parts. Anatomy is quite distinct from physiology and biochemistry, which deal respectively with the functions of those parts and the chemical processes involved. For example, an anatomist is concerned with the shape, size, position, structure, blood supply and innervation of an organ such as the liver; while a physiologist is interested in the production of bile, the role of the liver in nutrition and the regulation of bodily functions.

The discipline of anatomy can be subdivided into a number of branches, including gross or macroscopic anatomy and microscopic anatomy. Gross anatomy is the study of structures large enough to be seen with the naked eye, and also includes superficial anatomy or surface anatomy, the study by sight of the external body features. Microscopic anatomy is the study of structures on a microscopic scale, along with histology (the study of tissues), and embryology (the study of an organism in its immature condition). Regional anatomy is the study of the interrelationships of all of the structures in a specific body region, such as the abdomen. In contrast, systemic anatomy is the study of the structures that make up a discrete body system—that is, a group of structures that work together to perform a unique body function, such as the digestive system.

Anatomy can be studied using both invasive and non-invasive methods with the goal of obtaining information about the structure and organization of organs and systems. Methods used include dissection, in which a body is opened and its organs studied, and endoscopy, in which a video camera-equipped instrument is inserted through a small incision in the body wall and used to explore the internal organs and other structures. Angiography using X-rays or magnetic resonance angiography are methods to visualize blood vessels.

The term "anatomy" is commonly taken to refer to human anatomy. However, substantially similar structures and tissues are found throughout the rest of the animal kingdom, and the term also includes the anatomy of other animals. The term zootomy is also sometimes used to specifically refer to non-human animals. The structure and tissues of plants are of a dissimilar nature and they are studied in plant anatomy.

Animal tissues

Stylized cutaway diagram of an animal cell (with flagella)

The kingdom Animalia contains multicellular organisms that are heterotrophic and motile (although some have secondarily adopted a sessile lifestyle). Most animals have bodies differentiated into separate tissues and these animals are also known as eumetazoans. They have an internal digestive chamber, with one or two openings; the gametes are produced in multicellular sex organs, and the zygotes include a blastula stage in their embryonic development. Metazoans do not include the sponges, which have undifferentiated cells.

Unlike plant cells, animal cells have neither a cell wall nor chloroplasts. Vacuoles, when present, are more in number and much smaller than those in the plant cell. The body tissues are composed of numerous types of cells, including those found in muscles, nerves and skin. Each typically has a cell membrane formed of phospholipids, cytoplasm and a nucleus. All of the different cells of an animal are derived from the embryonic germ layers. Those simpler invertebrates which are formed from two germ layers of ectoderm and endoderm are called diploblastic and the more developed animals whose structures and organs are formed from three germ layers are called triploblastic. All of a triploblastic animal's tissues and organs are derived from the three germ layers of the embryo, the ectoderm, mesoderm and endoderm.

Animal tissues can be grouped into four basic types: connective, epithelial, muscle and nervous tissue.

Hyaline cartilage at high magnification (H&E stain)

Connective tissue

Connective tissues are fibrous and made up of cells scattered among inorganic material called the extracellular matrix. Often called fascia (from the Latin "fascia," meaning "band" or "bandage"), connective tissues give shape to organs and holds them in place. The main types are loose connective tissue, adipose tissue, fibrous connective tissue, cartilage and bone. The extracellular matrix contains proteins, the chief and most abundant of which is collagen. Collagen plays a major part in organizing and maintaining tissues. The matrix can be modified to form a skeleton to support or protect the body. An exoskeleton is a thickened, rigid cuticle which is stiffened by mineralization, as in crustaceans or by the cross-linking of its proteins as in insects. An endoskeleton is internal and present in all developed animals, as well as in many of those less developed.

Epithelium

Gastric mucosa at low magnification (H&E stain)

Epithelial tissue is composed of closely packed cells, bound to each other by cell adhesion molecules, with little intercellular space. Epithelial cells can be squamous (flat), cuboidal or columnar and rest on a basal lamina, the upper layer of the basement membrane, the lower layer is the reticular lamina lying next to the connective tissue in the extracellular matrix secreted by the epithelial cells. There are many different types of epithelium, modified to suit a particular function. In the respiratory tract there is a type of ciliated epithelial lining; in the small intestine there are microvilli on the epithelial lining and in the large intestine there are intestinal villi. Skin consists of an outer layer of keratinized stratified squamous epithelium that covers the exterior of the vertebrate body. Keratinocytes make up to 95% of the cells in the skin. The epithelial cells on the external surface of the body typically secrete an extracellular matrix in the form of a cuticle. In simple animals this may just be a coat of glycoproteins. In more advanced animals, many glands are formed of epithelial cells.

Muscle tissue

Cross section through skeletal muscle and a small nerve at high magnification (H&E stain)

Muscle cells (myocytes) form the active contractile tissue of the body. Muscle tissue functions to produce force and cause motion, either locomotion or movement within internal organs. Muscle is formed of contractile filaments and is separated into three main types; smooth muscle, skeletal muscle and cardiac muscle. Smooth muscle has no striations when examined microscopically. It contracts slowly but maintains contractibility over a wide range of stretch lengths. It is found in such organs as sea anemone tentacles and the body wall of sea cucumbers. Skeletal muscle contracts rapidly but has a limited range of extension. It is found in the movement of appendages and jaws. Obliquely striated muscle is intermediate between the other two. The filaments are staggered and this is the type of muscle found in earthworms that can extend slowly or make rapid contractions. In higher animals striated muscles occur in bundles attached to bone to provide movement and are often arranged in antagonistic sets. Smooth muscle is found in the walls of the uterus, bladder, intestines, stomach, oesophagus, respiratory airways, and blood vessels. Cardiac muscle is found only in the heart, allowing it to contract and pump blood round the body.

Nervous tissue

Nervous tissue is composed of many nerve cells known as neurons which transmit information. In some slow-moving radially symmetrical marine animals such as ctenophores and cnidarians (including sea anemones and jellyfish), the nerves form a nerve net, but in most animals they are organized longitudinally into bundles. In simple animals, receptor neurons in the body wall cause a local reaction to a stimulus. In more complex animals, specialized receptor cells such as chemoreceptors and photoreceptors are found in groups and send messages along neural networks to other parts of the organism. Neurons can be connected together in ganglia. In higher animals, specialized receptors are the basis of sense organs and there is a central nervous system (brain and spinal cord) and a peripheral nervous system. The latter consists of sensory nerves that transmit information from sense organs and motor nerves that influence target organs. The peripheral nervous system is divided into the somatic nervous system which conveys sensation and controls voluntary muscle, and the autonomic nervous system which involuntarily controls smooth muscle, certain glands and internal organs, including the stomach.

Vertebrate anatomy

Mouse skull. The neck and most of the forelimbs are also seen.

All vertebrates have a similar basic body plan and at some point in their lives, mostly in the embryonic stage, share the major chordate characteristics: a stiffening rod, the notochord; a dorsal hollow tube of nervous material, the neural tube; pharyngeal arches; and a tail posterior to the anus. The spinal cord is protected by the vertebral column and is above the notochord, and the gastrointestinal tract is below it. Nervous tissue is derived from the ectoderm, connective tissues are derived from mesoderm, and gut is derived from the endoderm. At the posterior end is a tail which continues the spinal cord and vertebrae but not the gut. The mouth is found at the anterior end of the animal, and the anus at the base of the tail. The defining characteristic of a vertebrate is the vertebral column, formed in the development of the segmented series of vertebrae. In most vertebrates the notochord becomes the nucleus pulposus of the intervertebral discs. However, a few vertebrates, such as the sturgeon and the coelacanth, retain the notochord into adulthood. Jawed vertebrates are typified by paired appendages, fins or legs, which may be secondarily lost. The limbs of vertebrates are considered to be homologous because the same underlying skeletal structure was inherited from their last common ancestor. This is one of the arguments put forward by Charles Darwin to support his theory of evolution.

Fish anatomy

Cutaway diagram showing various organs of a fish

The body of a fish is divided into a head, trunk and tail, although the divisions between the three are not always externally visible. The skeleton, which forms the support structure inside the fish, is either made of cartilage, in cartilaginous fish, or bone in bony fish. The main skeletal element is the vertebral column, composed of articulating vertebrae which are lightweight yet strong. The ribs attach to the spine and there are no limbs or limb girdles. The main external features of the fish, the fins, are composed of either bony or soft spines called rays, which with the exception of the caudal fins, have no direct connection with the spine. They are supported by the muscles which compose the main part of the trunk. The heart has two chambers and pumps the blood through the respiratory surfaces of the gills and on round the body in a single circulatory loop. The eyes are adapted for seeing underwater and have only local vision. There is an inner ear but no external or middle ear. Low frequency vibrations are detected by the lateral line system of sense organs that run along the length of the sides of fish, and these respond to nearby movements and to changes in water pressure.

Sharks and rays are basal fish with numerous primitive anatomical features similar to those of ancient fish, including skeletons composed of cartilage. Their bodies tend to be dorso-ventrally flattened, they usually have five pairs of gill slits and a large mouth set on the underside of the head. The dermis is covered with separate dermal placoid scales. They have a cloaca into which the urinary and genital passages open, but not a swim bladder. Cartilaginous fish produce a small number of large, yolky eggs. Some species are ovoviviparous and the young develop internally but others are oviparous and the larvae develop externally in egg cases.

The bony fish lineage shows more derived anatomical traits, often with major evolutionary changes from the features of ancient fish. They have a bony skeleton, are generally laterally flattened, have five pairs of gills protected by an operculum, and a mouth at or near the tip of the snout. The dermis is covered with overlapping scales. Bony fish have a swim bladder which helps them maintain a constant depth in the water column, but not a cloaca. They mostly spawn a large number of small eggs with little yolk which they broadcast into the water column.

Amphibian anatomy

Frog skeleton
Skeleton of Surinam horned frog (Ceratophrys cornuta)
Plastic model of a frog

Amphibians are a class of animals comprising frogs, salamanders and caecilians. They are tetrapods, but the caecilians and a few species of salamander have either no limbs or their limbs are much reduced in size. Their main bones are hollow and lightweight and are fully ossified and the vertebrae interlock with each other and have articular processes. Their ribs are usually short and may be fused to the vertebrae. Their skulls are mostly broad and short, and are often incompletely ossified. Their skin contains little keratin and lacks scales, but contains many mucous glands and in some species, poison glands. The hearts of amphibians have three chambers, two atria and one ventricle. They have a urinary bladder and nitrogenous waste products are excreted primarily as urea. Amphibians breathe by means of buccal pumping, a pump action in which air is first drawn into the buccopharyngeal region through the nostrils. These are then closed and the air is forced into the lungs by contraction of the throat. They supplement this with gas exchange through the skin which needs to be kept moist.

In frogs the pelvic girdle is robust and the hind legs are much longer and stronger than the forelimbs. The feet have four or five digits and the toes are often webbed for swimming or have suction pads for climbing. Frogs have large eyes and no tail. Salamanders resemble lizards in appearance; their short legs project sideways, the belly is close to or in contact with the ground and they have a long tail. Caecilians superficially resemble earthworms and are limbless. They burrow by means of zones of muscle contractions which move along the body and they swim by undulating their body from side to side.

Reptile anatomy

Skeleton of a western diamondback rattlesnake

Reptiles are a class of animals comprising turtles, tuataras, lizards, snakes and crocodiles. They are tetrapods, but the snakes and a few species of lizard either have no limbs or their limbs are much reduced in size. Their bones are better ossified and their skeletons stronger than those of amphibians. The teeth are conical and mostly uniform in size. The surface cells of the epidermis are modified into horny scales which create a waterproof layer. Reptiles are unable to use their skin for respiration as do amphibians and have a more efficient respiratory system drawing air into their lungs by expanding their chest walls. The heart resembles that of the amphibian but there is a septum which more completely separates the oxygenated and deoxygenated bloodstreams. The reproductive system has evolved for internal fertilization, with a copulatory organ present in most species. The eggs are surrounded by amniotic membranes which prevents them from drying out and are laid on land, or develop internally in some species. The bladder is small as nitrogenous waste is excreted as uric acid.

Turtles are notable for their protective shells. They have an inflexible trunk encased in a horny carapace above and a plastron below. These are formed from bony plates embedded in the dermis which are overlain by horny ones and are partially fused with the ribs and spine. The neck is long and flexible and the head and the legs can be drawn back inside the shell. Turtles are vegetarians and the typical reptile teeth have been replaced by sharp, horny plates. In aquatic species, the front legs are modified into flippers.

Tuataras superficially resemble lizards but the lineages diverged in the Triassic period. There is one living species, Sphenodon punctatus. The skull has two openings (fenestrae) on either side and the jaw is rigidly attached to the skull. There is one row of teeth in the lower jaw and this fits between the two rows in the upper jaw when the animal chews. The teeth are merely projections of bony material from the jaw and eventually wear down. The brain and heart are more primitive than those of other reptiles, and the lungs have a single chamber and lack bronchi. The tuatara has a well-developed parietal eye on its forehead.

Lizards have skulls with only one fenestra on each side, the lower bar of bone below the second fenestra having been lost. This results in the jaws being less rigidly attached which allows the mouth to open wider. Lizards are mostly quadrupeds, with the trunk held off the ground by short, sideways-facing legs, but a few species have no limbs and resemble snakes. Lizards have moveable eyelids, eardrums are present and some species have a central parietal eye.

Snakes are closely related to lizards, having branched off from a common ancestral lineage during the Cretaceous period, and they share many of the same features. The skeleton consists of a skull, a hyoid bone, spine and ribs though a few species retain a vestige of the pelvis and rear limbs in the form of pelvic spurs. The bar under the second fenestra has also been lost and the jaws have extreme flexibility allowing the snake to swallow its prey whole. Snakes lack moveable eyelids, the eyes being covered by transparent "spectacle" scales. They do not have eardrums but can detect ground vibrations through the bones of their skull. Their forked tongues are used as organs of taste and smell and some species have sensory pits on their heads enabling them to locate warm-blooded prey.

Crocodilians are large, low-slung aquatic reptiles with long snouts and large numbers of teeth. The head and trunk are dorso-ventrally flattened and the tail is laterally compressed. It undulates from side to side to force the animal through the water when swimming. The tough keratinized scales provide body armour and some are fused to the skull. The nostrils, eyes and ears are elevated above the top of the flat head enabling them to remain above the surface of the water when the animal is floating. Valves seal the nostrils and ears when it is submerged. Unlike other reptiles, crocodilians have hearts with four chambers allowing complete separation of oxygenated and deoxygenated blood.

Bird anatomy

Part of a wing. Albrecht Dürer, c. 1500–1512

Birds are tetrapods but though their hind limbs are used for walking or hopping, their front limbs are wings covered with feathers and adapted for flight. Birds are endothermic, have a high metabolic rate, a light skeletal system and powerful muscles. The long bones are thin, hollow and very light. Air sac extensions from the lungs occupy the centre of some bones. The sternum is wide and usually has a keel and the caudal vertebrae are fused. There are no teeth and the narrow jaws are adapted into a horn-covered beak. The eyes are relatively large, particularly in nocturnal species such as owls. They face forwards in predators and sideways in ducks.

The feathers are outgrowths of the epidermis and are found in localized bands from where they fan out over the skin. Large flight feathers are found on the wings and tail, contour feathers cover the bird's surface and fine down occurs on young birds and under the contour feathers of water birds. The only cutaneous gland is the single uropygial gland near the base of the tail. This produces an oily secretion that waterproofs the feathers when the bird preens. There are scales on the legs, feet and claws on the tips of the toes.

Mammal anatomy

Mammals are a diverse class of animals, mostly terrestrial but some are aquatic and others have evolved flapping or gliding flight. They mostly have four limbs, but some aquatic mammals have no limbs or limbs modified into fins, and the forelimbs of bats are modified into wings. The legs of most mammals are situated below the trunk, which is held well clear of the ground. The bones of mammals are well ossified and their teeth, which are usually differentiated, are coated in a layer of prismatic enamel. The teeth are shed once (milk teeth) during the animal's lifetime or not at all, as is the case in cetaceans. Mammals have three bones in the middle ear and a cochlea in the inner ear. They are clothed in hair and their skin contains glands which secrete sweat. Some of these glands are specialized as mammary glands, producing milk to feed the young. Mammals breathe with lungs and have a muscular diaphragm separating the thorax from the abdomen which helps them draw air into the lungs. The mammalian heart has four chambers, and oxygenated and deoxygenated blood are kept entirely separate. Nitrogenous waste is excreted primarily as urea.

Mammals are amniotes, and most are viviparous, giving birth to live young. Exceptions to this are the egg-laying monotremes, the platypus and the echidnas of Australia. Most other mammals have a placenta through which the developing foetus obtains nourishment, but in marsupials, the foetal stage is very short and the immature young is born and finds its way to its mother's pouch where it latches on to a teat and completes its development.

Human anatomy

Sagittal sections of the head as seen by a modern MRI scan
In humans, dexterous hand movements and increased brain size are likely to have evolved simultaneously.

Humans have the overall body plan of a mammal. Humans have a head, neck, trunk (which includes the thorax and abdomen), two arms and hands, and two legs and feet.

Generally, students of certain biological sciences, paramedics, prosthetists and orthotists, physiotherapists, occupational therapists, nurses, podiatrists, and medical students learn gross anatomy and microscopic anatomy from anatomical models, skeletons, textbooks, diagrams, photographs, lectures and tutorials and in addition, medical students generally also learn gross anatomy through practical experience of dissection and inspection of cadavers. The study of microscopic anatomy (or histology) can be aided by practical experience examining histological preparations (or slides) under a microscope.

Human anatomy, physiology and biochemistry are complementary basic medical sciences, which are generally taught to medical students in their first year at medical school. Human anatomy can be taught regionally or systemically; that is, respectively, studying anatomy by bodily regions such as the head and chest, or studying by specific systems, such as the nervous or respiratory systems. The major anatomy textbook, Gray's Anatomy, has been reorganized from a systems format to a regional format, in line with modern teaching methods. A thorough working knowledge of anatomy is required by physicians, especially surgeons and doctors working in some diagnostic specialties, such as histopathology and radiology.

Academic anatomists are usually employed by universities, medical schools or teaching hospitals. They are often involved in teaching anatomy, and research into certain systems, organs, tissues or cells.

Invertebrate anatomy

Head of a male Daphnia, a planktonic crustacean

Invertebrates constitute a vast array of living organisms ranging from the simplest unicellular eukaryotes such as Paramecium to such complex multicellular animals as the octopus, lobster and dragonfly. They constitute about 95% of the animal species. By definition, none of these creatures has a backbone. The cells of single-cell protozoans have the same basic structure as those of multicellular animals but some parts are specialized into the equivalent of tissues and organs. Locomotion is often provided by cilia or flagella or may proceed via the advance of pseudopodia, food may be gathered by phagocytosis, energy needs may be supplied by photosynthesis and the cell may be supported by an endoskeleton or an exoskeleton. Some protozoans can form multicellular colonies.

Metazoans are a multicellular organism, with different groups of cells serving different functions. The most basic types of metazoan tissues are epithelium and connective tissue, both of which are present in nearly all invertebrates. The outer surface of the epidermis is normally formed of epithelial cells and secretes an extracellular matrix which provides support to the organism. An endoskeleton derived from the mesoderm is present in echinoderms, sponges and some cephalopods. Exoskeletons are derived from the epidermis and is composed of chitin in arthropods (insects, spiders, ticks, shrimps, crabs, lobsters). Calcium carbonate constitutes the shells of molluscs, brachiopods and some tube-building polychaete worms and silica forms the exoskeleton of the microscopic diatoms and radiolaria. Other invertebrates may have no rigid structures but the epidermis may secrete a variety of surface coatings such as the pinacoderm of sponges, the gelatinous cuticle of cnidarians (polyps, sea anemones, jellyfish) and the collagenous cuticle of annelids. The outer epithelial layer may include cells of several types including sensory cells, gland cells and stinging cells. There may also be protrusions such as microvilli, cilia, bristles, spines and tubercles.

Marcello Malpighi, the father of microscopical anatomy, discovered that plants had tubules similar to those he saw in insects like the silk worm. He observed that when a ring-like portion of bark was removed on a trunk a swelling occurred in the tissues above the ring, and he unmistakably interpreted this as growth stimulated by food coming down from the leaves, and being captured above the ring.

Arthropod anatomy

Arthropods comprise the largest phylum of invertebrates in the animal kingdom with over a million known species.

Insects possess segmented bodies supported by a hard-jointed outer covering, the exoskeleton, made mostly of chitin. The segments of the body are organized into three distinct parts, a head, a thorax and an abdomen. The head typically bears a pair of sensory antennae, a pair of compound eyes, one to three simple eyes (ocelli) and three sets of modified appendages that form the mouthparts. The thorax has three pairs of segmented legs, one pair each for the three segments that compose the thorax and one or two pairs of wings. The abdomen is composed of eleven segments, some of which may be fused and houses the digestive, respiratory, excretory and reproductive systems. There is considerable variation between species and many adaptations to the body parts, especially wings, legs, antennae and mouthparts.

Spiders a class of arachnids have four pairs of legs; a body of two segments—a cephalothorax and an abdomen. Spiders have no wings and no antennae. They have mouthparts called chelicerae which are often connected to venom glands as most spiders are venomous. They have a second pair of appendages called pedipalps attached to the cephalothorax. These have similar segmentation to the legs and function as taste and smell organs. At the end of each male pedipalp is a spoon-shaped cymbium that acts to support the copulatory organ.

Other branches of anatomy

  • Surface anatomy is important as the study of anatomical landmarks that can be readily seen from the exterior contours of the body. It enables medics and veterinarians to gauge the position and anatomy of the associated deeper structures. Superficial is a directional term that indicates that structures are located relatively close to the surface of the body.
  • Comparative anatomy relates to the comparison of anatomical structures (both gross and microscopic) in different animals.
  • Artistic anatomy relates to anatomic studies of body proportions for artistic reasons.

History

Ancient

Image of early rendition of anatomy findings

In 1600 BCE, the Edwin Smith Papyrus, an Ancient Egyptian medical text, described the heart and its vessels, as well as the brain and its meninges and cerebrospinal fluid, and the liver, spleen, kidneys, uterus and bladder. It showed the blood vessels diverging from the heart. The Ebers Papyrus (c. 1550 BCE) features a "treatise on the heart", with vessels carrying all the body's fluids to or from every member of the body.

Ancient Greek anatomy and physiology underwent great changes and advances throughout the early medieval world. Over time, this medical practice expanded due to a continually developing understanding of the functions of organs and structures in the body. Phenomenal anatomical observations of the human body were made, which contributed to the understanding of the brain, eye, liver, reproductive organs, and nervous system.

The Hellenistic Egyptian city of Alexandria was the stepping-stone for Greek anatomy and physiology. Alexandria not only housed the biggest library for medical records and books of the liberal arts in the world during the time of the Greeks but was also home to many medical practitioners and philosophers. Great patronage of the arts and sciences from the Ptolemaic dynasty of Egypt helped raise Alexandria up, further rivalling other Greek states' cultural and scientific achievements.

An anatomy thangka, part of Desi Sangye Gyatso's The Blue Beryl, 17th century

Some of the most striking advances in early anatomy and physiology took place in Hellenistic Alexandria. Two of the most famous anatomists and physiologists of the third century were Herophilus and Erasistratus. These two physicians helped pioneer human dissection for medical research, using the cadavers of condemned criminals, which was considered taboo until the Renaissance—Herophilus was recognized as the first person to perform systematic dissections. Herophilus became known for his anatomical works, making impressive contributions to many branches of anatomy and many other aspects of medicine. Some of the works included classifying the system of the pulse, the discovery that human arteries had thicker walls than veins, and that the atria were parts of the heart. Herophilus's knowledge of the human body has provided vital input towards understanding the brain, eye, liver, reproductive organs, and nervous system and characterizing the course of the disease. Erasistratus accurately described the structure of the brain, including the cavities and membranes, and made a distinction between its cerebrum and cerebellum During his study in Alexandria, Erasistratus was particularly concerned with studies of the circulatory and nervous systems. He could distinguish the human body's sensory and motor nerves and believed air entered the lungs and heart, which was then carried throughout the body. His distinction between the arteries and veins—the arteries carrying the air through the body, while the veins carry the blood from the heart was a great anatomical discovery. Erasistratus was also responsible for naming and describing the function of the epiglottis and the heart's valves, including the tricuspid. During the third century, Greek physicians were able to differentiate nerves from blood vessels and tendons and to realize that the nerves convey neural impulses. It was Herophilus who made the point that damage to motor nerves induced paralysis. Herophilus named the meninges and ventricles in the brain, appreciated the division between cerebellum and cerebrum and recognized that the brain was the "seat of intellect" and not a "cooling chamber" as propounded by Aristotle Herophilus is also credited with describing the optic, oculomotor, motor division of the trigeminal, facial, vestibulocochlear and hypoglossal nerves.

Surgical instruments were invented by Abulcasis in the 11th century
Anatomy of the eye for the first time in history by Hunayn ibn Ishaq in the 9th century
13th century anatomical illustration

Incredible feats were made during the third century BCE in both the digestive and reproductive systems. Herophilus discovered and described not only the salivary glands but also the small intestine and liver. He showed that the uterus is a hollow organ and described the ovaries and uterine tubes. He recognized that spermatozoa were produced by the testes and was the first to identify the prostate gland.

The anatomy of the muscles and skeleton is described in the Hippocratic Corpus, an Ancient Greek medical work written by unknown authors. Aristotle described vertebrate anatomy based on animal dissection. Praxagoras identified the difference between arteries and veins. Also in the 4th century BCE, Herophilos and Erasistratus produced more accurate anatomical descriptions based on vivisection of criminals in Alexandria during the Ptolemaic period.

In the 2nd century, Galen of Pergamum, an anatomist, clinician, writer, and philosopher, wrote the final and highly influential anatomy treatise of ancient times. He compiled existing knowledge and studied anatomy through the dissection of animals. He was one of the first experimental physiologists through his vivisection experiments on animals. Galen's drawings, based mostly on dog anatomy, became effectively the only anatomical textbook for the next thousand years. His work was known to Renaissance doctors only through Islamic Golden Age medicine until it was translated from Greek sometime in the 15th century.

Medieval to early modern

Anatomical study of the arm, by Leonardo da Vinci, (about 1510)
Anatomical chart in Vesalius's Epitome, 1543
Michiel Jansz van MiereveltAnatomy lesson of Dr. Willem van der Meer, 1617

Anatomy developed little from classical times until the sixteenth century; as the historian Marie Boas writes, "Progress in anatomy before the sixteenth century is as mysteriously slow as its development after 1500 is startlingly rapid". Between 1275 and 1326, the anatomists Mondino de Luzzi, Alessandro Achillini and Antonio Benivieni at Bologna carried out the first systematic human dissections since ancient times. Mondino's Anatomy of 1316 was the first textbook in the medieval rediscovery of human anatomy. It describes the body in the order followed in Mondino's dissections, starting with the abdomen, thorax, head, and limbs. It was the standard anatomy textbook for the next century.

Leonardo da Vinci (1452–1519) was trained in anatomy by Andrea del Verrocchio. He made use of his anatomical knowledge in his artwork, making many sketches of skeletal structures, muscles and organs of humans and other vertebrates that he dissected.

Andreas Vesalius (1514–1564), professor of anatomy at the University of Padua, is considered the founder of modern human anatomy. Originally from Brabant, Vesalius published the influential book De humani corporis fabrica ("the structure of the human body"), a large format book in seven volumes, in 1543. The accurate and intricately detailed illustrations, often in allegorical poses against Italianate landscapes, are thought to have been made by the artist Jan van Calcar, a pupil of Titian.

In England, anatomy was the subject of the first public lectures given in any science; these were provided by the Company of Barbers and Surgeons in the 16th century, joined in 1583 by the Lumleian lectures in surgery at the Royal College of Physicians.

Late modern

Anatomy teaching with female students, 1891–1893

Medical schools began to be set up in the United States towards the end of the 18th century. Classes in anatomy needed a continual stream of cadavers for dissection, and these were difficult to obtain. Philadelphia, Baltimore, and New York were all renowned for body snatching activity as criminals raided graveyards at night, removing newly buried corpses from their coffins. A similar problem existed in Britain where demand for bodies became so great that grave-raiding and even anatomy murder were practised to obtain cadavers. Some graveyards were, in consequence, protected with watchtowers. The practice was halted in Britain by the Anatomy Act of 1832, while in the United States, similar legislation was enacted after the physician William S. Forbes of Jefferson Medical College was found guilty in 1882 of "complicity with resurrectionists in the despoliation of graves in Lebanon Cemetery".

The teaching of anatomy in Britain was transformed by Sir John Struthers, Regius Professor of Anatomy at the University of Aberdeen from 1863 to 1889. He was responsible for setting up the system of three years of "pre-clinical" academic teaching in the sciences underlying medicine, including especially anatomy. This system lasted until the reform of medical training in 1993 and 2003. As well as teaching, he collected many vertebrate skeletons for his museum of comparative anatomy, published over 70 research papers, and became famous for his public dissection of the Tay Whale. From 1822 the Royal College of Surgeons regulated the teaching of anatomy in medical schools. Medical museums provided examples in comparative anatomy, and were often used in teaching. Ignaz Semmelweis investigated puerperal fever and he discovered how it was caused. He noticed that the frequently fatal fever occurred more often in mothers examined by medical students than by midwives. The students went from the dissecting room to the hospital ward and examined women in childbirth. Semmelweis showed that when the trainees washed their hands in chlorinated lime before each clinical examination, the incidence of puerperal fever among the mothers could be reduced dramatically.

An electron microscope from 1973

Before the modern medical era, the primary means for studying the internal structures of the body were dissection of the dead and inspection, palpation, and auscultation of the living. The advent of microscopy opened up an understanding of the building blocks that constituted living tissues. Technical advances in the development of achromatic lenses increased the resolving power of the microscope, and around 1839, Matthias Jakob Schleiden and Theodor Schwann identified that cells were the fundamental unit of organization of all living things. The study of small structures involved passing light through them, and the microtome was invented to provide sufficiently thin slices of tissue to examine. Staining techniques using artificial dyes were established to help distinguish between different tissue types. Advances in the fields of histology and cytology began in the late 19th century along with advances in surgical techniques allowing for the painless and safe removal of biopsy specimens. The invention of the electron microscope brought a significant advance in resolution power and allowed research into the ultrastructure of cells and the organelles and other structures within them. About the same time, in the 1950s, the use of X-ray diffraction for studying the crystal structures of proteins, nucleic acids, and other biological molecules gave rise to a new field of molecular anatomy.

Equally important advances have occurred in non-invasive techniques for examining the body's interior structures. X-rays can be passed through the body and used in medical radiography and fluoroscopy to differentiate interior structures that have varying degrees of opaqueness. Magnetic resonance imaging, computed tomography, and ultrasound imaging have all enabled the examination of internal structures in unprecedented detail to a degree far beyond the imagination of earlier generations.

See also

References

  1. ^ "anatomy". Merriam-Webster.com Dictionary. Merriam-Webster.
  2. ^ Rotimi, Booktionary. "Anatomy". Archived from the original on 1 August 2017. Retrieved 18 June 2017.
  3. ^ Gray, Henry (1918). "Introduction". Anatomy of the Human Body (20th ed.). Archived from the original on 16 March 2007. Retrieved 19 March 2007 – via Bartleby.com.
  4. ^ Arráez-Aybar; et al. (2010). "Relevance of human anatomy in daily clinical practice". Annals of Anatomy. 192 (6): 341–48. doi:10.1016/j.aanat.2010.05.002. PMID 20591641.
  5. ^ Ghosh, Sanjib Kumar (2 March 2017). "Human cadaveric dissection: a historical account from ancient Greece to the modern era". Anatomy & Cell Biology. 48 (3): 153–169. doi:10.5115/acb.2015.48.3.153. PMC 4582158. PMID 26417475.
  6. ^ "Anatomical Imaging". McGraw Hill Higher Education. 1998. Archived from the original on 3 March 2016. Retrieved 25 June 2013.
  7. ^ O.D.E. 2nd edition 2005
  8. ^ Bozman, E. F., ed. (1967). Everyman's Encyclopedia: Anatomy. J. M. Dent & Sons. p. 272. ASIN B0066E44EC.
  9. ^ "Anatomy". The Free Dictionary. Farlex. 2007. Archived from the original on 15 November 2018. Retrieved 8 July 2013.
  10. ^ J. Gordon Betts (2013). "1.1 Overview of Anatomy and Physiology". Anatomy & physiology. Houston, Texas: OpenStax. ISBN 978-1-947172-04-3. Archived from the original on 3 April 2023. Retrieved 14 May 2023.
  11. ^ Gribble N, Reynolds K (1993). "Use of Angiography to Outline the Cardiovascular Anatomy of the Sand Crab Portunus pelagicus Linnaeus". Journal of Crustacean Biology. 13 (4): 627–637. doi:10.1163/193724093x00192. JSTOR 1549093.
  12. ^ Benson KG, Forrest L (1999). "Characterization of the Renal Portal System of the Common Green Iguana (Iguana iguana) by Digital Subtraction Imaging". Journal of Zoo and Wildlife Medicine. 30 (2): 235–241. PMID 10484138.
  13. ^ "Magnetic Resonance Angiography (MRA)". Johns Hopkins Medicine. Archived from the original on 7 October 2017. Retrieved 29 April 2014.
  14. ^ "Angiography". National Health Service. Archived from the original on 7 September 2017. Retrieved 29 April 2014.
  15. ^ Dorit, R. L.; Walker, W. F.; Barnes, R. D. (1991). Zoology. Saunders College Publishing. pp. 547–549. ISBN 978-0-03-030504-7.
  16. ^ Ruppert, Edward E.; Fox, Richard, S.; Barnes, Robert D. (2004). Invertebrate Zoology, 7th edition. Cengage Learning. pp. 59–60. ISBN 978-81-315-0104-7.{{cite book}}: CS1 maint: multiple names: authors list (link)
  17. ^ Dorland's (2012). Illustrated Medical Dictionary. Elsevier Saunders. p. 203. ISBN 978-1-4160-6257-8.
  18. ^ Dorland's (2012). Illustrated Medical Dictionary. Elsevier Saunders. p. 1002. ISBN 978-1-4160-6257-8.
  19. ^ McGrath, J.A.; Eady, R.A.; Pope, F.M. (2004). Rook's Textbook of Dermatology (7th ed.). Blackwell Publishing. pp. 3.1–3.6. ISBN 978-0-632-06429-8.
  20. ^ Bernd, Karen (2010). "Glandular epithelium". Epithelial Cells. Davidson College. Archived from the original on 28 January 2020. Retrieved 25 June 2013.
  21. ^ Ruppert, Edward E.; Fox, Richard, S.; Barnes, Robert D. (2004). Invertebrate Zoology, 7th edition. Cengage Learning. p. 103. ISBN 978-81-315-0104-7.{{cite book}}: CS1 maint: multiple names: authors list (link)
  22. ^ Ruppert, Edward E.; Fox, Richard, S.; Barnes, Robert D. (2004). Invertebrate Zoology, 7th edition. Cengage Learning. p. 104. ISBN 978-81-315-0104-7.{{cite book}}: CS1 maint: multiple names: authors list (link)
  23. ^ Johnston, T.B; Whillis, J, eds. (1944). Grey's Anatomy: Descriptive and Applied (28 ed.). Langmans. p. 1038.
  24. ^ Ruppert, Edward E.; Fox, Richard, S.; Barnes, Robert D. (2004). Invertebrate Zoology, 7th edition. Cengage Learning. pp. 105–107. ISBN 978-81-315-0104-7.{{cite book}}: CS1 maint: multiple names: authors list (link)
  25. ^ Moore, K.; Agur, A.; Dalley, A. F. (2010). "Essesntial Clinical Anatomy". Nervous System (4th ed.). Inkling. Archived from the original on 8 March 2021. Retrieved 30 April 2014.
  26. ^ Waggoner, Ben. "Vertebrates: More on Morphology". UCMP. Archived from the original on 10 October 2018. Retrieved 13 July 2011.
  27. ^ Romer, Alfred Sherwood (1985). The Vertebrate Body. Holt Rinehart & Winston. ISBN 978-0-03-058446-6.
  28. ^ Liem, Karel F.; Warren Franklin Walker (2001). Functional anatomy of the vertebrates: an evolutionary perspective. Harcourt College Publishers. p. 277. ISBN 978-0-03-022369-3.
  29. ^ "What is Homology?". National Center for Science Education. 17 October 2008. Archived from the original on 31 March 2019. Retrieved 28 June 2013.
  30. ^ Dorit, R. L.; Walker, W. F.; Barnes, R. D. (1991). Zoology. Saunders College Publishing. pp. 816–818. ISBN 978-0-03-030504-7.
  31. ^ "The fish heart". ThinkQuest. Oracle. Archived from the original on 28 April 2012. Retrieved 27 June 2013.
  32. ^ Kotpal, R. L. (2010). Modern Text Book of Zoology: Vertebrates. Rastogi Publications. p. 193. ISBN 978-81-7133-891-7.
  33. ^ Stebbins, Robert C.; Cohen, Nathan W. (1995). A Natural History of Amphibians. Princeton University Press. pp. 24–25. ISBN 978-0-691-03281-8.
  34. ^ Dorit, R. L.; Walker, W. F.; Barnes, R. D. (1991). Zoology. Saunders College Publishing. pp. 843–859. ISBN 978-0-03-030504-7.
  35. ^ Stebbins, Robert C.; Cohen, Nathan W. (1995). A Natural History of Amphibians. Princeton University Press. pp. 26–35. ISBN 978-0-691-03281-8.
  36. ^ Dorit, R. L.; Walker, W. F.; Barnes, R. D. (1991). Zoology. Saunders College Publishing. pp. 861–865. ISBN 978-0-03-030504-7.
  37. ^ Dorit, R. L.; Walker, W. F.; Barnes, R. D. (1991). Zoology. Saunders College Publishing. pp. 865–868. ISBN 978-0-03-030504-7.
  38. ^ Dorit, R. L.; Walker, W. F.; Barnes, R. D. (1991). Zoology. Saunders College Publishing. p. 870. ISBN 978-0-03-030504-7.
  39. ^ Dorit, R. L.; Walker, W. F.; Barnes, R. D. (1991). Zoology. Saunders College Publishing. p. 874. ISBN 978-0-03-030504-7.
  40. ^ Dorit, R. L.; Walker, W. F.; Barnes, R. D. (1991). Zoology. Saunders College Publishing. pp. 881–895. ISBN 978-0-03-030504-7.
  41. ^ Dorit, R. L.; Walker, W. F.; Barnes, R. D. (1991). Zoology. Saunders College Publishing. pp. 909–914. ISBN 978-0-03-030504-7.
  42. ^ "Hand". Encyclopædia Britannica 2006 Ultimate Reference Suite DVD. Archived from the original on 17 May 2014. Retrieved 15 May 2014.
  43. ^ "Studying medicine". Medschools Online. Archived from the original on 28 January 2013. Retrieved 27 June 2013.
  44. ^ Drake, Richard Lee; Gray, Henry; Vogl, Wayne; Mitchell, Adam W. M. (2004). Publisher's page for Gray's Anatomy. 39th edition (UK). ISBN 978-0-443-07168-3.
  45. ^ Drake, Richard Lee; Gray, Henry; Vogl, Wayne; Mitchell, Adam W. M. (2004). Publisher's page for Gray's Anatomy. 39th edition (US). ISBN 978-0-443-07168-3.
  46. ^ "American Association of Anatomists". Archived from the original on 4 April 2019. Retrieved 27 June 2013.
  47. ^ Ruppert, Edward E.; Fox, Richard, S.; Barnes, Robert D. (2004). Invertebrate Zoology, 7th edition. Cengage Learning. pp. 23–24. ISBN 978-81-315-0104-7.{{cite book}}: CS1 maint: multiple names: authors list (link)
  48. ^ "Exoskeleton". Encyclopædia Britannica. Archived from the original on 3 May 2015. Retrieved 2 July 2013.
  49. ^ Ebling, F. J. G. "Integument". Encyclopædia Britannica. Archived from the original on 30 April 2015. Retrieved 2 July 2013.
  50. ^ Arber, Agnes (1942). "Nehemiah Grew (1641–1712) and Marcello Malpighi (1628–1694): an essay in comparison". Isis. 34 (1): 7–16. doi:10.1086/347742. JSTOR 225992. S2CID 143008947.
  51. ^ Britannica Concise Encyclopaedia 2007
  52. ^ "O. Orkin Insect zoo". Mississippi State University. 1997. Archived from the original on 2 June 2009. Retrieved 23 June 2013.
  53. ^ Gullan, P.J.; Cranston, P. S. (2005). The Insects: An Outline of Entomology (3 ed.). Oxford: Blackwell Publishing. pp. 22–48. ISBN 978-1-4051-1113-3.
  54. ^ Ruppert, Edward E.; Fox, Richard, S.; Barnes, Robert D. (2004). Invertebrate Zoology, 7th edition. Cengage Learning. pp. 218–225. ISBN 978-81-315-0104-7.{{cite book}}: CS1 maint: multiple names: authors list (link)
  55. ^ Marieb, Elaine (2010). Human Anatomy & Physiology. San Francisco: Pearson. p. 12.
  56. ^ Rose, F. Clifford (16 March 2006). "The History of Cerebral Trauma". In Evans, Randolph W. (ed.). Neurology and Trauma. Oxford University Press, USA. ISBN 978-0-19-517032-0. Archived from the original on 26 March 2023. Retrieved 14 March 2023.
  57. ^ Atta, Hussein M. (December 1999). "Edwin Smith Surgical Papyrus: The Oldest Known Surgical Treatise". The American Surgeon. 65 (12): 1190–1192. doi:10.1177/000313489906501222. ISSN 0003-1348. PMID 10597074. S2CID 30179363. Archived from the original on 7 March 2023. Retrieved 7 March 2023.
  58. ^ Boehm, Thomas; Bleul, Conrad C. (February 2007). "The evolutionary history of lymphoid organs". Nature Immunology. 8 (2): 131–135. doi:10.1038/ni1435. ISSN 1529-2908. PMID 17242686. S2CID 45581056. Archived from the original on 7 March 2023. Retrieved 7 March 2023. Important landmark discoveries included the first description of the spleen found in the Edwin Smith Papyrus, containing medical information from Egypt dating back as early as 3000 BC...
  59. ^ Porter, R. (1997). The Greatest Benefit to Mankind: A Medical History of Humanity from Antiquity to the Present. Harper Collins. pp. 49–50. ISBN 978-0-00-215173-3.
  60. ^ Longrigg, James (December 1988). "Anatomy in Alexandria in the Third Century B.C". The British Journal for the History of Science. 21 (4): 455–488. doi:10.1017/s000708740002536x. JSTOR 4026964. PMID 11621690. S2CID 37575399.
  61. ^ Bay, Noel Si Yang; Bay, Boon-Huat (2010). "Greek Anatomists Herophilus: The Father of Anatomy". Anatomy and Cell Biology. 43 (3): 280–283. doi:10.5115/acb.2010.43.4.280. PMC 3026179. PMID 21267401.
  62. ^ Von Staden, H (1992). "The Discovery of the Body: Human Dissection and Its Cultural Contexts in Ancient Greece". The Yale Journal of Biology and Medicine. 65 (3): 223–241. PMC 2589595. PMID 1285450.
  63. ^ "Erasistratus Biography (304B.C-250B.C)". Free Health Encyclopedia - faqs.org. Archived from the original on 16 November 2018. Retrieved 23 February 2022.{{cite web}}: CS1 maint: bot: original URL status unknown (link)
  64. ^ "Erasistratus of Ceos: Greek Physician". Encyclopædia Britannica. 3 April 2018. Archived from the original on 21 April 2019.
  65. ^ Wiltse, LL; Pait, TG (1 September 1998). "Herophilus of Alexandria (325-255 B.C.) The Father of Anatomy". Spine. 23 (17): 1904–1914. doi:10.1097/00007632-199809010-00022. PMID 9762750.
  66. ^ Wills, Adrian (1999). "Herophilus, Ersasistratus, and the birth of neuroscience". The Lancet. 354 (9191): 1719–1720. doi:10.1016/S0140-6736(99)02081-4. PMID 10568587. S2CID 30110082. Archived from the original on 28 October 2019. Retrieved 25 November 2015.
  67. ^ Von Staden, Heinrich (October 2007). Herophilus: The Art of Medicine in Early Alexandria. Cambridge University Press. ISBN 9780521041782. Archived from the original on 8 December 2015. Retrieved 25 November 2015.
  68. ^ Gillispie, Charles Coulston (1972). Dictionary of Scientific Biography. Vol. VI. New York: Charles Scribner's Sons. pp. 419–427.
  69. ^ Lang, Philippa (2013). Medicine and Society in Ptolemaic Egypt. Brill NV. p. 256. ISBN 978-9004218581. Archived from the original on 16 April 2021. Retrieved 15 October 2020.
  70. ^ "Alexandrian Medicine" Archived 20 February 2017 at the Wayback Machine. Antiqua Medicina – from Homer to Vesalius. University of Virginia.
  71. ^ Hutton, Vivien. "Galen of Pergamum". Encyclopædia Britannica 2006 Ultimate Reference Suite DVD. Archived from the original on 6 April 2012. Retrieved 13 May 2014.
  72. ^ Charon NW, Johnson RC, Muschel LH (1975). "Antileptospiral activity in lower-vertebrate sera". Infect. Immun. 12 (6): 1386–1391. doi:10.1128/IAI.12.6.1386-1391.1975. PMC 415446. PMID 1081972.
  73. ^ Brock, Arthur John (translator) Galen. On the Natural Faculties. Edinburgh, 1916. Introduction, page xxxiii.
  74. ^ Boas, Marie (1970) [first published by Collins, 1962]. The Scientific Renaissance 1450–1630. Fontana. pp. 120–143.
  75. ^ Zimmerman, Leo M.; Veith, Ilza (1993). Great Ideas in the History of Surgery. Norman. ISBN 978-0-930405-53-3. Archived from the original on 15 April 2016. Retrieved 31 July 2017.
  76. ^ Crombie, Alistair Cameron (1959). The History of Science From Augustine to Galileo. Courier Dover Publications. ISBN 978-0-486-28850-5. Archived from the original on 9 April 2016. Retrieved 31 July 2017.
  77. ^ Thorndike, Lynn (1958). A History of Magic and Experimental Science: Fourteenth and fifteenth centuries. Columbia University Press. ISBN 978-0-231-08797-1. Archived from the original on 16 April 2016. Retrieved 31 July 2017.
  78. ^ Mason, Stephen F. (1962). A History of the Sciences. New York: Collier. p. 550.
  79. ^ "Warwick honorary professor explores new material from founder of modern human anatomy". Press release. University of Warwick. Archived from the original on 6 November 2018. Retrieved 8 July 2013.
  80. ^ Vesalius, Andreas. De humani corporis fabrica libri septem. Basileae [Basel]: Ex officina Joannis Oporini, 1543.
  81. ^ O'Malley, C.D. Andreas Vesalius of Brussels, 1514–1564. Berkeley: University of California Press, 1964.
  82. ^ Boas, Marie (1970) [first published by Collins, 1962]. The Scientific Renaissance 1450–1630. Fontana. p. 229.
  83. ^ Sappol, Michael (2002). A traffic of dead bodies: anatomy and embodied social identity in nineteenth-century America. Princeton, NJ: Princeton University Press. ISBN 978-0-691-05925-9. Archived from the original on 16 April 2021. Retrieved 15 October 2020.
  84. ^ Rosner, Lisa. 2010. The Anatomy Murders. Being the True and Spectacular History of Edinburgh's Notorious Burke and Hare and of the Man of Science Who Abetted Them in the Commission of Their Most Heinous Crimes. University of Pennsylvania Press
  85. ^ Richardson, Ruth (1989). Death, Dissection, and the Destitute. Penguin. ISBN 978-0-14-022862-5.
  86. ^ Johnson, D.R. "Introductory Anatomy". University of Leeds. Archived from the original on 4 November 2008. Retrieved 25 June 2013.
  87. ^ "Reproduction of Portrait of Professor William S. Forbes". Jefferson: Eakins Gallery. Archived from the original on 16 October 2013. Retrieved 14 October 2013.
  88. ^ Waterston SW, Laing MR, Hutchison JD (2007). "Nineteenth century medical education for tomorrow's doctors". Scottish Medical Journal. 52 (1): 45–49. doi:10.1258/rsmsmj.52.1.45. PMID 17373426. S2CID 30286930.
  89. ^ Waterston SW, Hutchison JD (2004). "Sir John Struthers MD FRCS Edin LLD Glasg: Anatomist, zoologist and pioneer in medical education". The Surgeon. 2 (6): 347–351. doi:10.1016/s1479-666x(04)80035-0. PMID 15712576.
  90. ^ McLachlan J., Patten D. (2006). "Anatomy teaching: ghosts of the past, present and future". Medical Education. 40 (3): 243–253. doi:10.1111/j.1365-2929.2006.02401.x. PMID 16483327. S2CID 30909540.
  91. ^ Reinarz J (2005). "The age of museum medicine: The rise and fall of the medical museum at Birmingham's School of Medicine". Social History of Medicine. 18 (3): 419–437. doi:10.1093/shm/hki050.
  92. ^ "Ignaz Philipp Semmelweis". Encyclopædia Britannica. Retrieved 15 October 2013.
  93. ^ "Microscopic anatomy". Encyclopædia Britannica. Archived from the original on 28 October 2014. Retrieved 14 October 2013.

Sources

 This article incorporates text from a free content work. Licensed under CC BY 4.0. Text taken from Openstax Anatomy and Physiology​, J. Gordon Betts et al, Openstax.