Transcript Slide 1
Saladin Ch. 25 The Digestive System Digestion Digestion breakdown of larger food molecules into particles small enough for absorption Digestive System organs that collectively perform digestion Digestive System: Overview Figure 23.1 Digestive Process • The GI tract is a “disassembly” line – Nutrients become more available to the body in each step • There are six essential activities: – Ingestion, propulsion, and mechanical digestion – Chemical digestion, absorption, and defecation Digestive Process Figure 23.2 Gastrointestinal Tract Activities • Ingestion – eating • Propulsion – swallowing & peristalsis – Peristalsis – waves of contraction & relaxation of muscles in organ walls • Mechanical digestion – chewing, mixing, & churning food Peristalsis and Segmentation Figure 23.3 Gastrointestinal Tract Activities • Chemical Digestion – Secretion of water, acid, buffers, enzymes. Large molecules are split into smaller pieces. • Absorption – material enters epithelial cells lining GI tract and is passed on to the lymph or blood. • Defecation – elimination of indigestible solid wastes. Digestive & Accessory Organs Digestive • Gastrointestinal (GI) Tract = Alimentary Canal - continuous tube running from mouth to anus. Digests and absorbs. Mouth, pharynx, esophagus, stomach, small intestine, large intestine Accessory Digestive Organs • Aid in processing - food doesn't go into these organs. Teeth, tongue, salivary glands, liver, gallbladder, pancreas. Histology of the Alimentary Canal • All the walls of the GI tract have the same four tunics: – From the lumen outward they are the mucosa, submucosa, muscularis externa, & serosa. Histology of the Alimentary Canal Figure 23.6 Mucosa • Moist epithelial layer that lines the lumen of the alimentary canal. • Three layers: a lining epithelium, lamina propria, & muscularis mucosae. Mucosa: Epithelial Lining • Mouth, pharynx, esophagus, anal canal =non-keratinized stratified squamous. • Stomach, intestines= simple columnar epithelium. • Exocrine glands: Put mucus & fluid in • Enteroendocrine glands - secrete hormones into blood stream. Mucosa: Lamina Propria and Muscularis Mucosae • Lamina Propria: layer of areolar tissue deep to lining - Connects to muscularis mucosae. • Muscularis mucosae - thin smooth muscle fibers - helps increase surface area by moving folds of mucosa so they are fully exposed to nutrients. Submucosa • Submucosa - binds mucosa to muscularis externa; • Areolar CT • Contains submucosal plexus - part of the enteric nervous system • Also contains - glands, blood, lymph Muscularis Externa & Serosa • Muscularis Externa – Smooth muscle layer. – Contains the myenteric plexus - the other enteric nervous system component. • Serosa - superficial layer of GI organs in the abdominal cavity CT and epithelium; – Visceral layer of peritoneum - serous membrane. Enteric Nervous System • Composed of two major intrinsic nerve plexuses: – Submucosal nerve plexus – regulates glands and smooth muscle in the mucosa. – Myenteric nerve plexus – Major nerve supply that controls GI tract mobility. Enteric Nervous System • Segmentation & peristalsis are largely automatic involving local reflex arcs. • Linked to the CNS via long autonomic reflex arc. Peritoneum and Peritoneal Cavity • Peritoneum – serous membrane of the abdominal cavity. – Parietal – lines the body wall. – Visceral – covers external surface of most digestive organs. Peritoneum and Peritoneal Cavity • Peritoneal cavity: – Narrow space between parietal and visceral layers. – Lubricates digestive organs. – Allows them to slide across one another. Peritoneum and Peritoneal Cavity Figure 23.5a Peritoneum and Peritoneal Cavity • Lesser Omentum - from stomach and duodenum - attaches these to the liver. • Greater Omentum - fatty apron hanging down over colon and small intestine on the anterior aspect. • Mesocolon - fold that binds the large intestine to the posterior abdominal wall Peritoneum and Peritoneal Cavity • Retroperitoneal organs – organs outside the peritoneum. – Only have peritoneum on anterior surface. • Peritoneal organs (intraperitoneal) – organs surrounded by peritoneum. Regulation of GI Tract Regulation of digestion involves: – Mechanical & chemical stimuli – stretch receptors, osmolarity, & presence of substrate in the lumen – Extrinsic control – Intrinsic control Nervous Control of the GI Tract • Intrinsic controls: – Nerve plexuses near the GI tract initiate short reflexes. – Short reflexes are mediated by local enteric plexuses (gut brain). Nervous Control of the GI Tract • Extrinsic controls: – Long reflexes arising within or outside the GI tract. – Involve CNS centers and extrinsic autonomic nerves. Regulation of GI Tract • Hormones: – Gastrin, secretin, CCK, histamine, paracrines [see hormone chart] Mouth • Oral or buccal cavity: – Is bounded by lips, cheeks, palate, & tongue. – Vestibule – bounded by the lips & cheeks externally, & teeth and gums internally. Anatomy of the Oral Cavity: Mouth Figure 23.7a Tongue • Skeletal muscle covered with mucous membrane. – Intrinsic muscles – originate and insert in tongue - For swallowing and speech – Extrinsic muscles – originate outside the tongue & insert in it. Move side to side &in & out. Aid in movement of food into bolus. Palate • Palate: – Hard [palatine bones + palatine processes of maxilla; – Soft – skeletal muscle Oral Cavity and Pharynx: Anterior View Figure 23.7b Teeth • Primary and permanent dentitions have formed by age 21. • Primary – 20 deciduous “milk” teeth. • Permanent – 32 secondary teeth, Classification of Teeth • Teeth are classified according to their shape and function. – Incisors – chisel-shaped - adapted for cutting or nipping. – Canines – conical or fanglike - tear or pierce – Premolars (bicuspids) & molars – broad crowns with rounded tips - for grinding or crushing Deciduous Teeth Figure 23.10.1 Permanent Teeth Figure 23.10.2 Tooth Structure • Two main regions – crown & root. – Crown – exposed part above the gingiva (gum). – Root – portion embedded in the jawbone. Tooth Structure • Enamel – acellular, brittle material composed mostly of calcium phosphate. – Enamel is the hardest substance produced by the body. – Encapsulates the crown of the tooth. Tooth Structure Anatomy of a tooth: • Crown, neck, root, apical foramen. • Enamel – hardest substance produced, covers crown; Mostly calcium phosphate • Dentin – bone-like, secreted by cells of pulp Tooth Structure • Cementum – covering of root, similar to bone • Periodontal ligament – anchors tooth to alveolar socket, which is surrounded by gingiva (gums) Tooth Structure Figure 23.11 Salivary Glands • Parotid – anterior to ear over the masseter. – Parotid duct – opens into vestibule next to the second upper molar. – Secretes salivary amylase. – Swollen when infected by mumps virus Salivary Glands • Submandibular – beneath posterior tongue. – Secretes saliva with salivary amylase. • Sublingual – anterior to submandibular gland under the tongue. – Opens into the floor of the mouth. Salivary Glands Figure 23.9a Saliva Saliva • 1-1.5 L/day • Blood filtrate + salivary amylase, mucin & lysozyme Saliva • Control – ANS – food stimulates tactile, pressure and taste sensor salivatory nuclei in medulla – Parasympathetic – normal salivation – facial and glossopharyngeal nerves – Sympathetic – decreased salivation Pharynx • From the mouth, the oro- & laryngopharynx allow passage of: – Food and fluids to the esophagus. – Air to the trachea. • See Ch. 22 Esophagus • Muscular [skeletal to smooth] – a collapsible tube. All 4 layers, modified. • Mucosa – stratified squamous epithelium; esophageal glands in submucosa; musc. Ext. has both smooth and skeletal muscle; serosa replaced with adventitia Esophagus • Passes through mediastinum and diaphragm [esophageal hiatus] “hiatal hernias” • Functions: secretes mucus, transports bolus to stomach [cardiac orifice] Swallowing • Deglutition – swallowing controlled by medulla & pons swallow center – involves trigeminal, facial, glossopharyngeal, & hypoglossal nerves. • 2 phases – – Buccal phase – bolus formation, pharyngealesophageal phase –moves to stomach – Peristalsis – waves of muscular contraction – move bolus Deglutition (Swallowing) Bolus of food Tongue Uvula Pharynx Bolus Epiglottis Epiglottis Glottis Esophagus Trachea (a) Upper esophageal sphincter contracted Bolus (c) Upper esophageal sphincter contracted (b) Upper esophageal sphincter relaxed Relaxed muscles Relaxed muscles Circular muscles contract, constricting passageway and pushing bolus down Bolus of food Gastroesophageal sphincter open Longitudinal muscles contract, shortening passageway ahead of bolus Gastroesophageal sphincter closed Stomach (d) (e) Figure 23.13 Stomach • Functions – Storage – Mechanical breakdown of food – Enzymatic digestion of food – Absorption of simple compounds – Produces gastrin – Bacterial protection – Produces intrinsic factor Stomach • Cardiac region – surrounds the cardiac orifice. • Fundus – dome-shaped region beneath the diaphragm. • Body – midportion of the stomach. • Pyloric region – made up of the antrum and canal, through the pyloric sphincter. Stomach Figure 23.14a Stomach Innervation & circulation • Para = vagus, sym = celiac ganglion • Arterial – celiac artery, venous – hepatic portal system Stomach Wall • Muscularis – 3 layers instead of two – longitudinal, circular and oblique smooth layers • Submucosa & mucosa - Ruggae – large folds in mucosa • Mucosa – simple columnar epithelium Glands of the Stomach Fundus and Body • Gastric Pits of the fundus & body have a variety of secretory cells: – Mucous cells –> mucus – Parietal cells –> HCl & intrinsic factor – Chief cells –> pepsinogen • Pepsinogen is activated to pepsin by: Glands of the Stomach Fundus and Body – Enteroendocrine cells –> gastrin, histamine, serotonin, & somatostatin into the lamina propria Microscopic Anatomy of the Stomach Figure 23.15 Gastric Secretions • Produces 2-3L of gastric juice/day • HCl – get H from CO2 – carbonic anhydrase reaction [parietal cells] pumped out by active transport. • Pepsin – digests protein; also get chymosin & gastric lipase in infants Gastric Secretions • Intrinsic factor - also from parietal cells – needed to absorb B12 [only indispensable function of stomach] • Chemical messengers enteroendocrine cells make up to 20 – include gut-brain peptides like substance P, vasoactive intestinal peptide, secretin, etc. • Stomach Lining • To keep from digesting itself, the stomach has a mucosal barrier with: – A thick coat of bicarbonate-rich mucus on the stomach wall. – Epithelial cells that are joined by tight junctions. – Gastric juices released only in presence of food which dilutes its effects Gastric Motility • Receptive-relaxation response – stomach relaxes to receive food [stim. by medulla] • Peristaltic contractions – increasing in strength. • Squirts 3 mL of chime into duodenum/ wave Vomiting • Emetic center of medulla • Usually preceded by nausea & retching • Projectile vomiting – no prior nausea, etc. – common in infants. • Bulimia – eating disorder – erodes tooth enamel, aspiration of acid injures respiratory tree, acid reflux damages esophagus Regulation of Gastric Secretion • Neural & hormonal mechanisms regulate release of gastric juice. • 3 phases of events: – Cephalic (reflex) phase: prior to food entry. – Gastric phase: once food enters the stomach. – Intestinal phase: as partially digested food enters the duodenum. Cephalic Phase • Events include: – Sight or thought of food; Stimulation of taste or smell receptors. – Stimulate secretions from parietal cells, Chief cells, and mucus cells. Gastric Phase • Events include: – Release of gastrin to the blood. – Stomach distension & increase in pH due to food. Intestinal Phase • Mostly inhibitory – small intestine receptors are activated by influx of chyme – enterogastric reflex. • Slows exit of chyme and prevents duodenal overload. Intestinal Phase • Chyme also stimulates enteroendocrine cells to release secretin, CCK and gastric inhibitory protein. • Secretin & CCK stim. pancreas and gallbladder. All 3 suppress gastric secretion & motility • Release of Gastric Juice Figure 23.16 Liver • The largest gland in the body • Functions: – Synthesis of bile salts – Excretion of bile Liver • 2 Lobes [R,L] separated by falciform running from diaphragm between lobes. – The right lobe is further subdivided into two lobes - the quadrate and caudate. • Falciform Ligament - binds liver to anterior wall. • The round ligament exits the falciform ligament from the liver - former umbilical vein. Liver: Microscopic Anatomy • Lobes are divided into working units called lobules – Plates of hepatocytes [specialized epithelium] that secrete bile – Central vein Liver: Microscopic Anatomy • Liver sinusoids – enlarged, leaky capillaries located between hepatic plates. – Blood from stomach & SI is filtered and glucose, amino acids, iron, vitamins, etc are removed, as are toxins, drugs, etc. • Kupffer cells – hepatic macrophages found in liver sinusoids. Microscopic Anatomy of the Liver Figure 23.24c, d Liver: Bile • Produced by hepatocytes. • Bile leaves the liver via: – Bile canalculi to bile ducts – Bile ducts fuse into the common hepatic duct Liver: Bile – The common hepatic duct fuses with the cystic duct the bile duct – Bile duct [joins pancreatic duct hepatopancreatic ampulla SI Gallbladder • Thin-walled, green muscular sac on the ventral surface of the liver. • Releases bile via the cystic duct, which flows into the bile duct. • Stores and concentrates bile by absorbing its water and ions. Composition of Bile • Bile - Yellow, brownish to olive green 500-1000mL/day • Water, bile acids, bile salts, cholesterol, ions, phospholipids [lecithin] bile pigments [bilirubin etc.] • Bile Salts [acids] = steroids made from cholesterol–emulsify fats Composition of Bile • Recycled – 80% reabsorbed by SI and re-secreted by liver • Wastes – include from RBC breakdown bilirubin from heme -- intestine broken into stercobilin, Gallbladder and Associated Ducts Figure 23.20 Pancreas • Size – 5 inches long and 1 inch thick • Regions – head, body, tail • Ducts – – 1 – pancreatic duct fuses with common bile duct forming the hepatopancreatic ampulla - enters duodenum about 4 inches below pylorus – 2 – accessory duct – enters 1 inch above ampulla Pancreas • Exocrine function - Secretes pancreatic juice which breaks down all categories of foodstuff. • Endocrine function – release of insulin & glucagon. Acinus of the Pancreas Figure 23.26a Pancreatic Juice • Pancreatic Juice – clear, colorless, 1.21.5L/day, pH about 8 • Mostly water • Sodium bicarbonate – increase pH, buffers acidic chyme, stops pepsin action • Salts Composition & Function of Pancreatic Juice • Enzymes secreted: – Trypsinogen is activated to trypsin – Carboxypeptidase – Chymotrypsinogen – Amylase, lipases, & nucleases – These enzymes require ions or bile for optimal activity Regulation of Secretion • Increased with parasympathetic, decreased with sympathetic. • Bile & pancreatic juice stim. By CCK, gastrin & secretin • CCK released from duodenum response to acid & fat contraction of gallbladder, secretion of pancreatic enzymes, relaxation of hepatopancreatic sphincter Regulation of Secretion • Secretin – stimulates secretion of bicarbonate to neutralize stomach acid in duodenum. Small Intestine: Gross Anatomy • Runs from pyloric sphincter to the ileocecal valve. • 3 subdivisions: duodenum, jejunum, & ileum. • Ileocecal valve = sphincter to the large intestines. • Mesentery – peritoneum supporting the small intestines. Small Intestine: Microscopic Anatomy • Structural modifications of the small intestine wall increase surface area. – Circular folds of the mucosa • Villus – structure with a lamina propria core containing arterioles, venules, capillary nets and lymphatic lacteals, covered with simple columnar epithelium with microvilli , goblet cells and absorptive cells Small Intestine: Microscopic Anatomy – Lacteals-absorption of fats – Goblet cells - secrete mucus – Absorptive cells – simple columnar epithelium - absorb and make brush border enzymes – Intestinal Crypts - tubular glands in floor of SI between villi bases – secrete intestinal juice [enzymes] Small Intestine: Microscopic Anatomy – Paneth Cells - phagocytic - produce lysozyme – Enteroendocrine glands - secrete secretin and CCK – Duodenal [Brunner's] in submucosa -secrete alkaline mucus – neutralizes stomach acid Small Intestine: Microscopic Anatomy Figure 23.21 Intestinal Juice • Clear yellow - 1-2 L/day, pH 7.6 • Contains water, mucus, enzymes - aid absorption of nutrients from chyme • Resorbed by villi Motility in the Small Intestine • Segmentation– Localized mixing motions bring contents in contact with mucosa. – Regulated by pacemaker cells – 12 contractions/ min – duod.; 8-9 ileum. • After nutrients have been absorbed: – Peristalsis begins. – Meal remnants, bacteria, mucosal cells, & debris are moved into large intestine. Control of Motility and Secretion • Local enteric neurons of the GI tract coordinate intestinal motility: – Distension – Presence of Chyme – Vasoactive intestinal polypeptide [VIP] increases secretions – Gastrin Control of Motility and Secretion • ANS: – Parasympathetic – increases motility. – Sympathetic-decreases motility. Chemical Digestion: Carbohydrates • Enzymes: salivary amylase, pancreatic amylase, & brush border enzymes • Absorption - glucose and galactose enter epithelial cells via symporters, accompanied by Na+ ions. Fructose enters by facilitated diffusion. • All exit to the blood by facilitated diffusion. • Lactose intolerance – lack enzyme lactase [large proportion of world population] Chemical Digestion: Proteins • Enzymes used: pepsin in the stomach. • Enzymes acting in the small intestine: – Pancreatic enzymes – trypsin, chymotrypsin – Brush border enzymes – peptidases. Chemical Digestion: Proteins Absorption • Amino acids, di and tripeptides - aa by simple active transport or in symporters with Na+ • Di and tripeptides - by symporters with H+. All exit to blood by diffusion. Chemical Digestion: Proteins Figure 23.34 Chemical Digestion: Fats • Lipids - digested by lipases • Fats emulsified by bile salts first – Products are fatty acids[FFA’s]and monoglycerides – Micelles in bile take up phospholipids & cholesterol, fat soluble vitamins, FFA’s and monoglycerides and transport to intestinal cells Chemical Digestion: Fats Figure 23.35 Chemical Digestion: Fats – FFA’s and monoglycerides enter epithelial cells and are re-assembled into triglycerides, combine with cholesterol, phospholipids and protein to form chylomicrons and exit by exocytosis into lacteals Fatty Acid Absorption Figure 23.36 Chemical Digestion: Nucleic Acids • Enzymes used: pancreatic nucleases in the small intestines. • Brush Border enzymes: nucleosidases, phosphatases. • Sugars, bases and phosphate ions absorbed by active transport across epithelium and into blood Vitamins & Minerals • Vitamins - water soluble diffuse, lipid soluble enter with lipids [A,D,E,K] • Minerals [Electrolytes] - absorbed through entire length of SI by diffusion or active transport - Na+/K+ and chloride/bicarbonate pumps. • Fe & Ca absorbed as needed, rest absorbed at constant rate regardless of need. Water • Water - absorbed by osmosis - 9L into system - about 8L absorbed - into blood • Diarrhea occurs when the large intestine absorbs too little • Constipation occurs when passage through the LI is too slow and too much water is absorbed Large Intestine • Functions: – Absorption, manufacture of some vitamins. – Formation & expulsion of feces. LI Anatomy • 1.5 M long, runs from cecum to rectum • Ileocecal sphincter - joins SI to LI. • Cecum - region of LI inferior to the ileocecal sphincter. • Appendix - next to the cecum. LI Anatomy • Colon - above sphincter - ascending, transverse, descending and Sigmoid regions • Rectum & valves- region inferior to sigmoid colon • Anal Canal - below rectum LI Anatomy • Taenia coli - longitudinal bands of muscles running the length of the LI • Haustra - pouches produced in the LI by tonal contraction of taenia coli. Large Intestine Figure 23.29a Large Intestine: Microscopic Anatomy • Mucosa – Simple columnar epithelium – no villi or enzyme secreting cells goblet cells Bacterial Flora • These bacteria: – Colonize the colon – Ferment indigestible carbohydrates – Release irritating acids and gases (flatus) – Synthesize B complex vitamins and vitamin K Motility of the Large Intestine • Haustral contractions: – Slow segmenting movements that move the contents of the colon. – Haustra sequentially contract as they are stimulated by distension. • Presence of food in the stomach: – Activates the gastrocolic reflex. – Initiates peristalsis that forces contents toward the rectum. Defecation Defecation Reflexes – initiated by rectal stretching • Intrinsic – entirely within enteric system – weak peristalsis • Sympathetic = Spinal cord reflex - Sends message to CNS – to decide whether to relax external sphincter. Defecation Figure 23.32