Jump to content

Stomach

From Wikipedia, the free encyclopedia
(Redirected from Gastric canal)
Stomach
Sections of the human stomach
Scheme of digestive tract, with stomach in red
Details
PrecursorForegut
SystemDigestive system
ArteryRight gastric artery, left gastric artery, right gastro-omental artery, left gastro-omental artery, short gastric arteries
VeinRight gastric vein, left gastric vein, right gastroepiploic vein, left gastroepiploic vein, short gastric veins
NerveCeliac ganglia, vagus nerve[1]
LymphCeliac lymph nodes[2]
Identifiers
Latinventriculus, stomachus
Greekστόμαχος
MeSHD013270
TA98A05.5.01.001
TA22901
FMA7148
Anatomical terminology

The stomach is a muscular, hollow organ in the upper gastrointestinal tract of humans and many other animals, including several invertebrates. The stomach has a dilated structure and functions as a vital organ in the digestive system. The stomach is involved in the gastric phase of digestion, following the cephalic phase in which the sight and smell of food and the act of chewing are stimuli. In the stomach a chemical breakdown of food takes place by means of secreted digestive enzymes and gastric acid.

The stomach is located between the esophagus and the small intestine. The pyloric sphincter controls the passage of partially digested food (chyme) from the stomach into the duodenum, the first and shortest part of the small intestine, where peristalsis takes over to move this through the rest of the intestines.

Structure

[edit]

In the human digestive system, the stomach lies between the esophagus and the duodenum (the first part of the small intestine). It is in the left upper quadrant of the abdominal cavity. The top of the stomach lies against the diaphragm. Lying behind the stomach is the pancreas. A large double fold of visceral peritoneum called the greater omentum hangs down from the greater curvature of the stomach. Two sphincters keep the contents of the stomach contained; the lower esophageal sphincter (found in the cardiac region), at the junction of the esophagus and stomach, and the pyloric sphincter at the junction of the stomach with the duodenum.

The stomach is surrounded by parasympathetic (inhibitor) and sympathetic (stimulant) plexuses (networks of blood vessels and nerves in the anterior gastric, posterior, superior and inferior, celiac and myenteric), which regulate both the secretory activity of the stomach and the motor (motion) activity of its muscles.

The stomach is distensible, and can normally expand to hold about one litre of food.[3] In a newborn human baby the stomach will only be able to hold about 30 millilitres. The maximum stomach volume in adults is between 2 and 4 litres,[4][5] although volumes of up to 15 litres have been observed in extreme circumstances.[6]

Sections

[edit]
Diagram showing parts of the stomach

The human stomach can be divided into four sections, beginning at the cardia followed by the fundus, the body and the pylorus.[7][8]

  • The gastric cardia is where the contents of the esophagus empty from the gastroesophageal sphincter into the cardiac orifice, the opening into the gastric cardia.[9][8] A cardiac notch at the left of the cardiac orifice, marks the beginning of the greater curvature of the stomach. A horizontal line across from the cardiac notch gives the dome-shaped region called the fundus.[8] The cardia is a very small region of the stomach that surrounds the esophageal opening.[8]
  • The fundus (from Latin 'bottom') is formed in the upper curved part.
  • The body or corpus is the main, central region of the stomach.
  • The pylorus opens to the body of the stomach. The pylorus (from Greek 'gatekeeper') connects the stomach to the duodenum at the pyloric sphincter.

The cardia is defined as the region following the "z-line" of the gastroesophageal junction, the point at which the epithelium changes from stratified squamous to columnar. Near the cardia is the lower esophageal sphincter.[9]

Anatomical proximity

[edit]

The stomach bed refers to the structures upon which the stomach rests in mammals.[10][11] These include the tail of the pancreas, splenic artery, left kidney, left suprarenal gland, transverse colon and its mesocolon, and the left crus of diaphragm, and the left colic flexure. The term was introduced around 1896 by Philip Polson of the Catholic University School of Medicine, Dublin. However this was brought into disrepute by surgeon anatomist J Massey.[12][13][14]

Blood supply

[edit]
Schematic image of the blood supply to the human stomach: left and right gastric artery, left and right gastroepiploic artery and short gastric arteries[15]

The lesser curvature of the human stomach is supplied by the right gastric artery inferiorly and the left gastric artery superiorly, which also supplies the cardiac region. The greater curvature is supplied by the right gastroepiploic artery inferiorly and the left gastroepiploic artery superiorly. The fundus of the stomach, and also the upper portion of the greater curvature, is supplied by the short gastric arteries, which arise from the splenic artery.

Lymphatic drainage

[edit]

The two sets of gastric lymph nodes drain the stomach.

Microanatomy

[edit]

Wall

[edit]
The gastrointestinal wall of the human stomach
Layers of the gastrointestinal wall of which the stomach is a dilated part

Like the other parts of the gastrointestinal wall, the human stomach wall from inner to outer, consists of a mucosa, submucosa, muscular layer, subserosa and serosa.[16]

The inner part of the stomach wall is the gastric mucosa a mucous membrane that forms the lining of the stomach. the membrane consists of an outer layer of columnar epithelium, a lamina propria, and a thin layer of smooth muscle called the muscularis mucosa. Beneath the mucosa lies the submucosa, consisting of fibrous connective tissue.[17] Meissner's plexus is in this layer interior to the oblique muscle layer.[18]

Outside of the submucosa lies the muscular layer. It consists of three layers of muscular fibres, with fibres lying at angles to each other. These are the inner oblique, middle circular, and outer longitudinal layers.[19] The presence of the inner oblique layer is distinct from other parts of the gastrointestinal tract, which do not possess this layer.[20] The stomach contains the thickest muscular layer consisting of three layers, thus maximum peristalsis occurs here.

  • The inner oblique layer: This layer is responsible for creating the motion that churns and physically breaks down the food. It is the only layer of the three which is not seen in other parts of the digestive system. The antrum has thicker skin cells in its walls and performs more forceful contractions than the fundus.
  • The middle circular layer: At this layer, the pylorus is surrounded by a thick circular muscular wall, which is normally tonically constricted, forming a functional (if not anatomically discrete) pyloric sphincter, which controls the movement of chyme into the duodenum. This layer is concentric to the longitudinal axis of the stomach.
  • The myenteric plexus (Auerbach's plexus) is found between the outer longitudinal and the middle circular layer and is responsible for the innervation of both (causing peristalsis and mixing).

The outer longitudinal layer is responsible for moving the semi-digested food towards the pylorus of the stomach through muscular shortening.

To the outside of the muscular layer lies a serosa, consisting of layers of connective tissue continuous with the peritoneum.

Smooth mucosa along the inside of the lesser curvature forms a passageway - the gastric canal that fast-tracks liquids entering the stomach, to the pylorus.[8]

Glands

[edit]
Diagram showing gastric pits (13) gastric glands (12) lamina propria (10) epithelium (11)
Histology of normal fundic mucosa. Fundic glands are simple, branched tubular glands that extend from the bottom of the gastric pits to the muscularis mucosae; the more distinctive cells are parietal cells. H&E stain.
Histology of normal antral mucosa. Antral mucosa is formed by branched coiled tubular glands lined by secretory cells similar in appearance to the surface mucous cells. H&E stain.

The mucosa lining the stomach is lined with gastric pits, which receive gastric juice, secreted by between 2 and 7 gastric glands.[citation needed] Gastric juice is an acidic fluid containing hydrochloric acid and digestive enzymes.[21] The glands contains a number of cells, with the function of the glands changing depending on their position within the stomach.[citation needed]

Within the body and fundus of the stomach lie the fundic glands. In general, these glands are lined by column-shaped cells that secrete a protective layer of mucus and bicarbonate. Additional cells present include parietal cells that secrete hydrochloric acid and intrinsic factor, chief cells that secrete pepsinogen (this is a precursor to pepsin- the highly acidic environment converts the pepsinogen to pepsin), and neuroendocrine cells that secrete serotonin.[22][citation needed]

Glands differ where the stomach meets the esophagus and near the pylorus.[23] Near the gastroesophageal junction lie cardiac glands, which primarily secrete mucus.[22] They are fewer in number than the other gastric glands and are more shallowly positioned in the mucosa. There are two kinds - either simple tubular glands with short ducts or compound racemose resembling the duodenal Brunner's glands.[citation needed] Near the pylorus lie pyloric glands located in the antrum of the pylorus. They secrete mucus, as well as gastrin produced by their G cells.[24][citation needed]

Gene and protein expression

[edit]

About 20,000 protein-coding genes are expressed in human cells and nearly 70% of these genes are expressed in the normal stomach.[25][26] Just over 150 of these genes are more specifically expressed in the stomach compared to other organs, with only some 20 genes being highly specific. The corresponding specific proteins expressed in stomach are mainly involved in creating a suitable environment for handling the digestion of food for uptake of nutrients. Highly stomach-specific proteins include gastrokine-1 expressed in the mucosa; pepsinogen and gastric lipase, expressed in gastric chief cells; and a gastric ATPase and gastric intrinsic factor, expressed in parietal cells.[27]

Development

[edit]

In the early part of the development of the human embryo, the ventral part of the embryo abuts the yolk sac. During the third week of development, as the embryo grows, it begins to surround parts of the yolk sac. The enveloped portions form the basis for the adult gastrointestinal tract.[28] The sac is surrounded by a network of vitelline arteries and veins. Over time, these arteries consolidate into the three main arteries that supply the developing gastrointestinal tract: the celiac artery, superior mesenteric artery, and inferior mesenteric artery. The areas supplied by these arteries are used to define the foregut, midgut, and hindgut.[28] The surrounded sac becomes the primitive gut. Sections of this gut begin to differentiate into the organs of the gastrointestinal tract, and the esophagus, and stomach form from the foregut.[28]

As the stomach rotates during early development, the dorsal and ventral mesentery rotate with it; this rotation produces a space anterior to the expanding stomach called the greater sac, and a space posterior to the stomach called the lesser sac. After this rotation the dorsal mesentery thins and forms the greater omentum, which is attached to the greater curvature of the stomach. The ventral mesentery forms the lesser omentum, and is attached to the developing liver. In the adult, these connective structures of omentum and mesentery form the peritoneum, and act as an insulating and protective layer while also supplying organs with blood and lymph vessels as well as nerves.[29] Arterial supply to all these structures is from the celiac trunk, and venous drainage is by the portal venous system. Lymph from these organs is drained to the prevertebral celiac nodes at the origin of the celiac artery from the aorta.

Function

[edit]

Digestion

[edit]

In the human digestive system, a bolus (a small rounded mass of chewed up food) enters the stomach through the esophagus via the lower esophageal sphincter. The stomach releases proteases (protein-digesting enzymes such as pepsin), and hydrochloric acid, which kills or inhibits bacteria and provides the acidic pH of 2 for the proteases to work. Food is churned by the stomach through peristaltic muscular contractions of the wall – reducing the volume of the bolus, before looping around the fundus[30] and the body of stomach as the boluses are converted into chyme (partially digested food). Chyme slowly passes through the pyloric sphincter and into the duodenum of the small intestine, where the extraction of nutrients begins.

Gastric juice in the stomach also contains pepsinogen. Hydrochloric acid activates this inactive form of enzyme into the active form, pepsin. Pepsin breaks down proteins into polypeptides.

Mechanical digestion

[edit]

Within a few moments after food enters the stomach, mixing waves begin to occur at intervals of approximately 20 seconds. A mixing wave is a unique type of peristalsis that mixes and softens the food with gastric juices to create chyme. The initial mixing waves are relatively gentle, but these are followed by more intense waves, starting at the body of the stomach and increasing in force as they reach the pylorus.

The pylorus, which holds around 30 mL of chyme, acts as a filter, permitting only liquids and small food particles to pass through the mostly, but not fully, closed pyloric sphincter. In a process called gastric emptying, rhythmic mixing waves force about 3 mL of chyme at a time through the pyloric sphincter and into the duodenum. Release of a greater amount of chyme at one time would overwhelm the capacity of the small intestine to handle it. The rest of the chyme is pushed back into the body of the stomach, where it continues mixing. This process is repeated when the next mixing waves force more chyme into the duodenum.

Gastric emptying is regulated by both the stomach and the duodenum. The presence of chyme in the duodenum activates receptors that inhibit gastric secretion. This prevents additional chyme from being released by the stomach before the duodenum is ready to process it.[31]

Chemical digestion

[edit]

The fundus stores both undigested food and gases that are released during the process of chemical digestion. Food may sit in the fundus of the stomach for a while before being mixed with the chyme. While the food is in the fundus, the digestive activities of salivary amylase continue until the food begins mixing with the acidic chyme. Ultimately, mixing waves incorporate this food with the chyme, the acidity of which inactivates salivary amylase and activates lingual lipase. Lingual lipase then begins breaking down triglycerides into free fatty acids, and mono- and diglycerides.

The breakdown of protein begins in the stomach through the actions of hydrochloric acid, and the enzyme pepsin.

The stomach can also produce gastric lipase, which can help digesting fat.

The contents of the stomach are completely emptied into the duodenum within two to four hours after the meal is eaten. Different types of food take different amounts of time to process. Foods heavy in carbohydrates empty fastest, followed by high-protein foods. Meals with a high triglyceride content remain in the stomach the longest. Since enzymes in the small intestine digest fats slowly, food can stay in the stomach for 6 hours or longer when the duodenum is processing fatty chyme. However, this is still a fraction of the 24 to 72 hours that full digestion typically takes from start to finish.[31]

Absorption

[edit]

Although the absorption in the human digestive system is mainly a function of the small intestine, some absorption of certain small molecules nevertheless does occur in the stomach through its lining. This includes:

The parietal cells of the human stomach are responsible for producing intrinsic factor, which is necessary for the absorption of vitamin B12. B12 is used in cellular metabolism and is necessary for the production of red blood cells, and the functioning of the nervous system.

Control of secretion and motility

[edit]
Emptying of stomach chyme into the duodenum through the pyloric sphincter

Chyme from the stomach is slowly released into the duodenum through coordinated peristalsis and opening of the pyloric sphincter. The movement and the flow of chemicals into the stomach are controlled by both the autonomic nervous system and by the various digestive hormones of the digestive system:

Gastrin The hormone gastrin causes an increase in the secretion of HCl from the parietal cells and pepsinogen from chief cells in the stomach. It also causes increased motility in the stomach. Gastrin is released by G cells in the stomach in response to distension of the antrum and digestive products (especially large quantities of incompletely digested proteins). It is inhibited by a pH normally less than 4(high acid), as well as the hormone somatostatin.
Cholecystokinin Cholecystokinin (CCK) has most effect on the gall bladder, causing gall bladder contractions, but it also decreases gastric emptying and increases release of pancreatic juice, which is alkaline and neutralizes the chyme. CCK is synthesized by I-cells in the mucosal epithelium of the small intestine.
Secretin In a different and rare manner, secretin, which has the most effects on the pancreas, also diminishes acid secretion in the stomach. Secretin is synthesized by S-cells, which are located in the duodenal mucosa as well as in the jejunal mucosa in smaller numbers.
Gastric inhibitory polypeptide Gastric inhibitory polypeptide (GIP) decreases both gastric acid release and motility. GIP is synthesized by K-cells, which are located in the duodenal and jejunal mucosa.
Enteroglucagon Enteroglucagon decreases both gastric acid and motility.

Other than gastrin, these hormones all act to turn off the stomach action. This is in response to food products in the liver and gall bladder, which have not yet been absorbed. The stomach needs to push food into the small intestine only when the intestine is not busy. While the intestine is full and still digesting food, the stomach acts as storage for food.

Other

[edit]
Effects of EGF

Epidermal growth factor (EGF) results in cellular proliferation, differentiation, and survival.[36] EGF is a low-molecular-weight polypeptide first purified from the mouse submandibular gland, but since then found in many human tissues including the submandibular gland, and the parotid gland. Salivary EGF, which also seems to be regulated by dietary inorganic iodine, also plays an important physiological role in the maintenance of oro-esophageal and gastric tissue integrity. The biological effects of salivary EGF include healing of oral and gastroesophageal ulcers, inhibition of gastric acid secretion, stimulation of DNA synthesis, and mucosal protection from intraluminal injurious factors such as gastric acid, bile acids, pepsin, and trypsin and from physical, chemical, and bacterial agents.[37]

Stomach as nutrition sensor

The human stomach has receptors responsive to sodium glutamate[38] and this information is passed to the lateral hypothalamus and limbic system in the brain as a palatability signal through the vagus nerve.[39] The stomach can also sense, independently of tongue and oral taste receptors, glucose,[40] carbohydrates,[41] proteins,[41] and fats.[42] This allows the brain to link nutritional value of foods to their tastes.[40]

Thyrogastric syndrome

This syndrome defines the association between thyroid disease and chronic gastritis, which was first described in the 1960s.[43] This term was coined also to indicate the presence of thyroid autoantibodies or autoimmune thyroid disease in patients with pernicious anemia, a late clinical stage of atrophic gastritis.[44] In 1993, a more complete investigation on the stomach and thyroid was published,[45] reporting that the thyroid is, embryogenetically and phylogenetically, derived from a primitive stomach, and that the thyroid cells, such as primitive gastroenteric cells, migrated and specialized in uptake of iodide and in storage and elaboration of iodine compounds during vertebrate evolution. In fact, the stomach and thyroid share iodine-concentrating ability and many morphological and functional similarities, such as cell polarity and apical microvilli, similar organ-specific antigens and associated autoimmune diseases, secretion of glycoproteins (thyroglobulin and mucin) and peptide hormones, the digesting and readsorbing ability, and lastly, similar ability to form iodotyrosines by peroxidase activity, where iodide acts as an electron donor in the presence of H2O2. In the following years, many researchers published reviews about this syndrome.[46]

Clinical significance

[edit]
An endoscopy of a normal stomach of a healthy 65-year-old woman
Endoscopic image of a fundic gland polyp

Diseases

[edit]

A series of radiographs can be used to examine the stomach for various disorders. This will often include the use of a barium swallow. Another method of examination of the stomach, is the use of an endoscope. A gastric emptying study is considered the gold standard to assess the gastric emptying rate.[47]

A large number of studies have indicated that most cases of peptic ulcers, and gastritis, in humans are caused by Helicobacter pylori infection, and an association has been seen with the development of stomach cancer.[48]

A stomach rumble is actually noise from the intestines.

Surgery

[edit]

In humans, many bariatric surgery procedures involve the stomach, in order to lose weight. A gastric band may be placed around the cardia area, which can adjust to limit intake. The anatomy of the stomach may be modified, or the stomach may be bypassed entirely.

Surgical removal of the stomach is called a gastrectomy, and removal of the cardia area is a called a cardiectomy. "Cardiectomy" is a term that is also used to describe the removal of the heart.[49][50][51] A gastrectomy may be carried out because of gastric cancer or severe perforation of the stomach wall.

Fundoplication is stomach surgery in which the fundus is wrapped around the lower esophagus and stitched into place. It is used to treat gastroesophageal reflux disease (GERD).[52]

Etymology

[edit]

The word stomach is derived from Greek stomachos (στόμαχος), ultimately from stoma (στόμα) 'mouth'.[53] Gastro- and gastric (meaning 'related to the stomach') are both derived from Greek gaster (γαστήρ) 'belly'.[54][55][56]

Other animals

[edit]

Although the precise shape and size of the stomach varies widely among different vertebrates, the relative positions of the esophageal and duodenal openings remain relatively constant. As a result, the organ always curves somewhat to the left before curving back to meet the pyloric sphincter. However, lampreys, hagfishes, chimaeras, lungfishes, and some teleost fish have no stomach at all, with the esophagus opening directly into the intestine. These animals all consume diets that require little storage of food, no predigestion with gastric juices, or both.[57]

Comparison of stomach glandular regions from several mammalian species. Frequency of glands may vary more smoothly between regions than is diagrammed here. Asterisk (ruminant) represents the omasum, which is absent in Tylopoda (Tylopoda also have some cardiac glands opening onto ventral reticulum and rumen[58]) Many other variations exist among the mammals.[59][60]
Yellow
Esophagus
Green
Esophageal (nonglandular) region.[61]
Purple
Cardiac gland region.[61]
Red
Fundic gland region.[61]
Blue
Pyloric gland region.[61]
Dark blue
Duodenum

The gastric lining is usually divided into two regions, an anterior portion lined by fundic glands and a posterior portion lined with pyloric glands. Cardiac glands are unique to mammals, and even then are absent in a number of species. The distributions of these glands vary between species, and do not always correspond with the same regions as in humans. Furthermore, in many non-human mammals, a portion of the stomach anterior to the cardiac glands is lined with epithelium essentially identical to that of the esophagus. Ruminants, in particular, have a complex four-chambered stomach. The first three chambers (rumen, reticulum, and omasum) are all lined with esophageal mucosa,[57] while the final chamber functions like a monogastric stomach, which is called the abomasum.

In birds and crocodilians, the stomach is divided into two regions. Anteriorly is a narrow tubular region, the proventriculus, lined by fundic glands, and connecting the true stomach to the crop. Beyond lies the powerful muscular gizzard, lined by pyloric glands, and, in some species, containing stones that the animal swallows to help grind up food.[57]

In insects, there is also a crop. The insect stomach is called the midgut.

Information about the stomach in echinoderms or molluscs can be found under the respective articles.

Additional images

[edit]

See also

[edit]

References

[edit]
  1. ^ Nosek, Thomas M. "Section 6/6ch2/s6ch2_30". Essentials of Human Physiology. Archived from the original on 2016-03-24.
  2. ^ The Stomach at The Anatomy Lesson by Wesley Norman (Georgetown University)
  3. ^ Sherwood, Lauralee (1997). Human physiology: from cells to systems. Belmont, CA: Wadsworth Pub. Co. ISBN 978-0-314-09245-8. OCLC 35270048.
  4. ^ Wenzel V, Idris AH, Banner MJ, Kubilis PS, Band R, Williams JL, et al. (1998). "Respiratory system compliance decreases after cardiopulmonary resuscitation and stomach inflation: impact of large and small tidal volumes on calculated peak airway pressure". Resuscitation. 38 (2): 113–8. doi:10.1016/S0300-9572(98)00095-1. PMID 9863573.
  5. ^ Curtis, Helena & N. Sue Barnes (1994). Invitation to Biology (5 ed.). Worth.
  6. ^ Morris D. Kerstein, Barry Goldberg, Barry Panter, M. David Tilson, Howard Spiro, Gastric Infarction, Gastroenterology, Volume 67, Issue 6, 1974, Pages 1238–1239, ISSN 0016-5085, https://doi.org/10.1016/S0016-5085(19)32710-6.
  7. ^ Tortora, Gerard J.; Derrickson, Bryan H. (2009). Principles of anatomy and physiology (12., internat. student version ed.). Hoboken, NJ: Wiley. pp. 937–942. ISBN 9780470233474.
  8. ^ a b c d e Standring, Susan, Gray's Anatomy (42nd ed.), Elsevier, pp. 1160–1163
  9. ^ a b Brunicardi, F. Charles; Andersen, Dana K.; et al., eds. (2010). Schwartz's principles of surgery (9th ed.). New York: McGraw-Hill, Medical Pub. Division. ISBN 978-0071547703.
  10. ^ [1] Habershon, S. H. "Diseases of the Stomach: A Manual for Practitioners and Students,"Chicago Medical Book Company, 1909, page 11.
  11. ^ [2] Weber, John and Shearer, Edwin Morrill "Shearer's manual of human dissection, Eighth Edition," McGraw Hill, 1999, page 157. ISBN 0-07-134624-4.
  12. ^ [3] Transactions of the Royal Academy of Medicine in Ireland, Volume 14, 1896, "Birmingham, A(mbrose), "Topographical anatomy of the spleen, pancreas, duodenum, kidneys, &c.", pages 363-385. Retrieved 29 February 2011.
  13. ^ [4] The Lancet, Volume 1, Part 1, 22 February 1902. page 524, "Royal Academy of Medicine in Ireland." Retrieved 28 February 2012
  14. ^ [5] The Dublin journal of medical science, Volume 114, page 353."Reviews and bibliographical notes." Retrieved 28 February 2012.
  15. ^ Anne M. R. Agur; Moore, Keith L. (2007). Essential Clinical Anatomy (Point (Lippincott Williams & Wilkins)). Hagerstown, MD: Lippincott Williams & Wilkins. ISBN 978-0-7817-6274-8. OCLC 172964542.; p. 150
  16. ^ "University of Rochester medical center". 2020. Archived from the original on 2021-11-19. Retrieved 2021-12-19.
  17. ^ "Stomach histology". Kenhub. Retrieved 2021-01-09.
  18. ^ Welcome, Menizibeya Osain (2018). Gastrointestinal physiology : development, principles and mechanisms of regulation. Cham, Switzerland: Springer. p. 628. ISBN 978-3-319-91056-7. OCLC 1042217248.
  19. ^ "22.5C: Muscularis". Medicine LibreTexts. 2018-07-22. Retrieved 2024-02-09.
  20. ^ "SIU SOM Histology GI". www.siumed.edu. Archived from the original on 2021-01-11. Retrieved 2021-01-09.
  21. ^ "How does the Stomach Work?". National Institute of Health: National Library of Medicine. Institute for Quality and Efficiency in Health Care (IQWiG). 21 August 2009. Retrieved 16 June 2024.
  22. ^ a b Dorland's (2012). Dorland's Illustrated Medical Dictionary (32nd ed.). Elsevier. p. 777. ISBN 978-1-4160-6257-8.
  23. ^ Gallego-Huidobro, J; Pastor, L M (April 1996). "Histology of the mucosa of the oesophagogastric junction and the stomach in adult Rana perezi". Journal of Anatomy. 188 (Pt 2): 439–444. ISSN 0021-8782. PMC 1167580. PMID 8621343.
  24. ^ Dorland's (2012). Dorland's Illustrated Medical Dictionary (32nd ed.). Elsevier. p. 762. ISBN 978-1-4160-6257-8.
  25. ^ "The human proteome in stomach - The Human Protein Atlas". www.proteinatlas.org. Retrieved 2017-09-25.
  26. ^ Uhlén, Mathias; Fagerberg, Linn; Hallström, Björn M.; Lindskog, Cecilia; Oksvold, Per; Mardinoglu, Adil; Sivertsson, Åsa; Kampf, Caroline; Sjöstedt, Evelina (2015-01-23). "Tissue-based map of the human proteome". Science. 347 (6220): 1260419. doi:10.1126/science.1260419. ISSN 0036-8075. PMID 25613900. S2CID 802377.
  27. ^ Gremel, Gabriela; Wanders, Alkwin; Cedernaes, Jonathan; Fagerberg, Linn; Hallström, Björn; Edlund, Karolina; Sjöstedt, Evelina; Uhlén, Mathias; Pontén, Fredrik (2015-01-01). "The human gastrointestinal tract-specific transcriptome and proteome as defined by RNA sequencing and antibody-based profiling". Journal of Gastroenterology. 50 (1): 46–57. doi:10.1007/s00535-014-0958-7. ISSN 0944-1174. PMID 24789573. S2CID 21302849.
  28. ^ a b c Gary C. Schoenwolf (2009). "Development of the Gastrointestinal Tract". Larsen's human embryology (4th ed.). Philadelphia: Churchill Livingstone/Elsevier. ISBN 978-0-443-06811-9.
  29. ^ Sadler, T.W, (2011) Langman’s Medical Embryology (12th edition), LWW, Baltimore, MD
  30. ^ Richard M. Gore; Marc S. Levine. (2007). Textbook of Gastrointestinal Radiology. Philadelphia, PA.: Saunders. ISBN 978-1-4160-2332-6.
  31. ^ a b  This article incorporates text available under the CC BY 4.0 license. Betts, J Gordon; Desaix, Peter; Johnson, Eddie; Johnson, Jody E; Korol, Oksana; Kruse, Dean; Poe, Brandon; Wise, James; Womble, Mark D; Young, Kelly A (September 13, 2023). Anatomy & Physiology. Houston: OpenStax CNX. 23.4 The Stomach. ISBN 978-1-947172-04-3.
  32. ^ Krehbiel, C.R.; Matthews, J.C. "Absorption of Amino acids and Peptides" (PDF). In D'Mello, J.P.F. (ed.). Amino Acids in Animal Nutrition (2nd ed.). pp. 41–70. Archived from the original (PDF) on 2015-07-15. Retrieved 2015-04-25.
  33. ^ "Alcohol and the Human Body". Intoximeters, Inc. Retrieved 30 July 2012.
  34. ^ Debry, Gérard (1994). Coffee and Health (PDF (eBook)). Montrouge: John Libbey Eurotext. p. 129. ISBN 9782742000371. Retrieved 2015-04-26.
  35. ^ McGuire, Michelle; Beerman, Kathy (2012-01-01). Nutritional Sciences: From Fundamentals to Food (3 ed.). Cengage Learning. p. 419. ISBN 978-1133707387.
  36. ^ Herbst RS (2004). "Review of epidermal growth factor receptor biology". International Journal of Radiation Oncology, Biology, Physics. 59 (2 Suppl): 21–6. doi:10.1016/j.ijrobp.2003.11.041. PMID 15142631.
  37. ^ Venturi S.; Venturi M. (2009). "Iodine in evolution of salivary glands and in oral health". Nutrition and Health. 20 (2): 119–134. doi:10.1177/026010600902000204. PMID 19835108. S2CID 25710052.
  38. ^ Uematsu, A; Tsurugizawa, T; Kondoh, T; Torii, K. (2009). "Conditioned flavor preference learning by intragastric administration of L-glutamate in rats". Neurosci. Lett. 451 (3): 190–3. doi:10.1016/j.neulet.2008.12.054. PMID 19146916. S2CID 21764940.
  39. ^ Uematsu, A; Tsurugizawa, T; Uneyama, H; Torii, K. (2010). "Brain-gut communication via vagus nerve modulates conditioned flavor preference". Eur J Neurosci. 31 (6): 1136–43. doi:10.1111/j.1460-9568.2010.07136.x. PMID 20377626. S2CID 23319470.
  40. ^ a b De Araujo, Ivan E.; Oliveira-Maia, Albino J.; Sotnikova, Tatyana D.; Gainetdinov, Raul R.; Caron, Marc G.; Nicolelis, Miguel A.L.; Simon, Sidney A. (2008). "Food Reward in the Absence of Taste Receptor Signaling". Neuron. 57 (6): 930–41. doi:10.1016/j.neuron.2008.01.032. PMID 18367093. S2CID 47453450.
  41. ^ a b Perez, C.; Ackroff, K.; Sclafani, A. (1996). "Carbohydrate- and protein conditioned flavor preferences: effects of nutrient preloads". Physiol. Behav. 59 (3): 467–474. doi:10.1016/0031-9384(95)02085-3. PMID 8700948. S2CID 23422504.
  42. ^ Ackroff, K.; Lucas, F.; Sclafani, A. (2005). "Flavor preference conditioning as a function of fat source". Physiol. Behav. 85 (4): 448–460. doi:10.1016/j.physbeh.2005.05.006. PMID 15990126. S2CID 7875868.
  43. ^ Doniach, D.; Roitt, I.M.; Taylor, K.B. (1965). "Autoimmunity in pernicious anemia and thyroiditis: a family study". Ann N Y Acad Sci. 124 (2): 605–25. Bibcode:1965NYASA.124..605D. doi:10.1111/j.1749-6632.1965.tb18990.x. PMID 5320499. S2CID 39456072.
  44. ^ Cruchaud, A.; Juditz, E. (1968). "An analysis of gastric parietal cell antibodies and thyroid cell antibodies in patients with pernicious anaemia and thyroid disorders". Clin Exp Immunol. 3 (8): 771–81. PMC 1578967. PMID 4180858.
  45. ^ Venturi, S.; Venturi, A.; Cimini, D., Arduini, C; Venturi, M; Guidi, A. (1993). "A new hypothesis: iodine and gastric cancer". Eur J Cancer Prev. 2 (1): 17–23. doi:10.1097/00008469-199301000-00004. PMID 8428171.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  46. ^ Lahner, E.; Conti, L.; Cicone, F. ; Capriello, S; Cazzato, M; Centanni, M; Annibale, B; Virili, C. (2019). "Thyro-entero-gastric autoimmunity: Pathophysiology and implications for patient management. A review". Best Pract Res Clin Endocrinol Metab. 33 (6): 101373. doi:10.1016/j.beem.2019.101373. PMID 31864909. S2CID 209446096.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  47. ^ Masaoka, Tatsuhiro; Tack, Jan (30 September 2009). "Gastroparesis: Current Concepts and Management". Gut and Liver. 3 (3): 166–173. doi:10.5009/gnl.2009.3.3.166. PMC 2852706. PMID 20431741.
  48. ^ Brown, LM (2000). "Helicobacter pylori: epidemiology and routes of transmission". Epidemiologic Reviews. 22 (2): 283–97. doi:10.1093/oxfordjournals.epirev.a018040. PMID 11218379.
  49. ^ cardiectomy at dictionary.reference.com
  50. ^ Barlow, O. W. (1929). "The survival of the circulation in the frog web after cardiectomy". Journal of Pharmacology and Experimental Therapeutics. 35 (1): 17–24. Retrieved February 24, 2008.
  51. ^ Meltzer, S. J. (1913). "The effect of strychnin in cardiectomized frogs with destroyed lymph hearts; a demonstration". Proceedings of the Society for Experimental Biology and Medicine. 10 (2): 23–24. doi:10.3181/00379727-10-16. S2CID 76506379.
  52. ^ Minjarez, Renee C.; Jobe, Blair A. (2006). "Surgical therapy for gastroesophageal reflux disease". GI Motility Online. doi:10.1038/gimo56 (inactive 1 November 2024).{{cite journal}}: CS1 maint: DOI inactive as of November 2024 (link)
  53. ^ Simpson, J. A. (1989). The Oxford English dictionary (2nd ed.). Oxford: Clarendon Press. Stomach. ISBN 9780198611868.
  54. ^ gasth/r. The New Testament Greek Lexicon
  55. ^ gaster. dictionary.reference.com
  56. ^ Simpson, J. A. (1989). The Oxford English dictionary (2nd ed.). Oxford: Clarendon Press. Gastro, Gastric. ISBN 9780198611868.
  57. ^ a b c Romer, Alfred Sherwood; Parsons, Thomas S. (1977). The Vertebrate Body. Philadelphia, PA: Holt-Saunders International. pp. 345–349. ISBN 978-0-03-910284-5.
  58. ^ William O. Reece (2005). Functional Anatomy and Physiology of Domestic Animals. Wiley. ISBN 978-0-7817-4333-4.
  59. ^ Finegan, Esther J. & Stevens, C. Edward. "Digestive System of Vertebrates". Archived from the original on 2008-12-01.
  60. ^ Khalil, Muhammad. "The anatomy of the digestive system". onemedicine.tuskegee.edu. Archived from the original on 2010-11-30.
  61. ^ a b c d Wilke, W. L.; Fails, A. D.; Frandson, R. D. (2009). Anatomy and physiology of farm animals. Ames, Iowa: Wiley-Blackwell. p. 346. ISBN 978-0-8138-1394-3.
[edit]