A demo tutorial from our Gross Anatomy Course that teaches you about the embryonic development of the gut tube and mesenteric attachments!
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A demo tutorial from our Gross Anatomy Course that teaches you about the embryonic development of the gut tube and mesenteric attachments!
~ Weeks 4 through 6
Three embryologic divisions of the thoracic and abdominal gastrointestinal tube:
Foregut
Supplied by the celiac artery
Gives rise to the:
Esophagus
Stomach - Liver buds, which ultimately form the liver
Gallbladder
Ventral and dorsal pancreatic buds (aka, diverticula), which will later fuse to form the pancreas
Proximal duodenum
Midgut
Supplied by the superior mesenteric artery
Comprises primary intestinal loop, which connects to the yolk sac via the vitelline duct
Gives rise to the:
Distal duodenum
Jejunum
Ileum
Ascending colon
Proximal 2/3 of the transverse colon
Hindgut
Supplied by the inferior mesenteric artery
Gives rise to the allantois before ending blindly at the cloaca
Gives rise to the:
Distal 1/3 of the transverse colon - Descending and sigmoid colons
The proximal 2/3 of the anorectal canal
INNERVATION
The enteric nervous system, which is derived from neural crest cells, regulates motility to propel the contents of the GI tract.
MESENTERIES
Mesenteries divide the peritoneal cavity and suspend the gastrointestinal tract. Additionally, they provide a protective covering for neurovascular structures.
The ventral mesentery is derived from the septum transversum, and will give rise to ligaments associated with the liver.
The dorsal mesentery secures the gastrointestinal tract to the posterior body wall.
The meso-esophagus attaches the esophagus to the dorsal wall
The mesogastrium anchors the stomach
The mesoduodenum anchors the duodenum
The mesentery proper anchors the primary loop of the midgut
The dorsal mesocolon anchors the hindgut
STUDIES ON THE ANATOMY AND HISTOLOGY OF THE FOREGUT IN ORCHESTIA PLATENSIS KRYER (CRUSTACEA : AMPHIPODA) | UTTAR PRADESH JOURNAL OF ZOOLOGY
Orchestia platensis' digestive tract is a straight tube with a foregut, midgut, and hindgut. The foregut is divided into three sections: the oesophagus, the cardiac stomach, and the pyloric stomach. The oesophagus and ston have comparable histological features: chitinous intima, columnar epithelium, tunica prop circular muscles, and occasionally longitudinal muscles. The cardiac and pyloric stomack walls are folded into a complex pattern, generating a number of ampullae and lamellae. The sophisticated gastric mill system of the cardiac stomach forms a triturating device. The filtration machinery of the posterior triangular pyloric stomach. Please see the link :- http://mbimph.com/index.php/UPJOZ/article/view/1094
I was lucky enough to find a log full of termites behind my house. You know what that means? Gut protists!
Termites can’t actually digest wood for themselves, so they form symbiotic relationships with protists and bacteria to help break down the wood for them
I squished a termite under a slide and saw all these flagellates come out. These unicellular creatures make up a third of the body weight of termites, and I’m lucky enough to be studying them as a lab intern
Another neat fact: termites are actually a type of cockroach!
More Bypass => More Satiety => Less Food Intake
In a model of direct glucose delivery to the hindgut, the length of foregut bypassed directly correlated with degree of GLP-1 increase and ghrelin decrease.[52]
Amplify’d from bariatrictimes.com
In a model of direct glucose delivery to the hindgut, the length of foregut bypassed directly correlated with degree of GLP-1 increase and ghrelin decrease.[52]
Many diet modifications and metabolic surgical techniques have relied on the up-regulation of GLP-1 and peptide YY to exert a strong satiating effect. Exenatide is the first of the antidiabetic drugs related to GLP-1 to receive FDA approval, and its use has shown improvement in diabetes as well as modest weight loss.[51] Intestinal resection or bypass in patients is accompanied by a GLP-1 and PYY surge to meal stimulus that contributes to decreased food intake and improved glucose homeostasis.[35,39] In a model of direct glucose delivery to the hindgut, the length of foregut bypassed directly correlated with degree of GLP-1 increase and ghrelin decrease.[52] Clinically, this correlates to operations with a “malabsorptive” component achieving greater overall weight loss and diabetes resolution.[50] Sleeve gastrectomy seems unique in that increased gastric emptying contributes to less mechanical breakdown of food and resultant greater hindgut stimulation than seen with other purely restrictive procedures.[16]
Hindgut Hormones: Glugagon-Like Peptide (GLP-1) and Peptide-YY (PYY) The “ileal brake” was recognized clinically as the strong feeling of satiation that developed once nutrients reached the hindgut. This phenomenon makes evolutionary sense because further ingestion of food in the presence of nutrients within the distal small bowel would only result in calorie loss in the stool. To prevent this, the hindgut L-cells within the terminal ileum and colon produce GLP-1 and peptideYY to stop ingestion and improve nutrient utilization. GLP-1 is a potent stimulator of insulin secretion and is trophic to beta cell function.[2] It is the hormone believed to play a key role in diabetes resolution after gastric bypass and duodenal switch, but is also likely to be the culprit behind the rare hypoglycemic hyperinsulimia reported after these operations.[48] Both peptideYY and GLP-1 have receptors in the central satiety and metabolism centers, where they exert strong effects to terminate hunger and increase the basal metabolic expenditure rate. Obese and diabetic patients seem to release less circulating GLP-1 and peptide YY in repsonse to a meal than their lean counterparts.[35,49] This is likely because many obese people are “early-intestine dominant” with an excessively long small bowel that is too efficient at processing and absorbing calories. This leaves little residual intraluminal nutrients downstream to stimulate the release of hindgut hormones.[50]
Read more at bariatrictimes.com
See this Amp at http://amplify.com/u/a1bu9c