digestive ii

Question 1

Stomach: nerve and blood supply

Answer 1

ANS nerve supply

• sympathetic from thoracic splanchnic nerves via celiac plexus
• parasympathetic via vagus nerve

Blood supply:

• celiac trunk (gastric and splenic branches
• veins of hepatic portal system

Question 2

Stomach microscopic anatomy

Answer 2

4 tunics
Muscularis and mucosa modified
Muscularis external
-3 layers of smooth muscle
-inner oblique layer allows stomach to churn, mix, move, and break down food

Mucosal pits for secretion of gastric juices

Question 3

Stomach mucosa

Answer 3

• simple columnar epithelium composed of mucous cells –> secrete 2-layer coat of alkaline mucus (surface layer traps bicarbonate-rich fluid beneath it)
• dotted with gastric pits, containing gastric glands, producing gastric juices (mostly in body and fundus)

Parietal cell, chief cell, enteroendocrine cells (G cells), mucous neck cells

Question 4

Stomach mucosa parietal cell

Answer 4

secrete HCL –> ph = 1.5-3.5 –> denatures proteins, activates pepsin, breaks down plant walls, and kills bacteria

secretes intrinsic factor = glycoprotein required for absorption of B12 in small intestine –> only func of stomach that’s critical for life

Question 5

Chief cells

Answer 5

secrete pepsinogen = inactive enzyme –> activated to pepsin by HCl and by pepsin itself (positive feedback mechanism)

secretes lipases –> digest 15% of lipids

Question 6

Enteroendocrine cells

Answer 6

secrete chem messengers into lamina propria (NOT LUMEN)

• act as paracrines –> serotonin and histamine
• hormones –> somatostatin (also a paracrine) and gastrin

Question 7

Mucosal barrier

Answer 7

harsh digestive conditions in stomach
has mucosal barrier to protect
-thick layer of bicarbonate-rich mucus
-tight junctions between epithelial cells (prevent juice seeping underneath tissue)
-damaged epithelial cells quickly replaced by division of stem cells (surface cells replaced wvery 3-6 days)

Question 8

Digestive breakdown process in stomach

Answer 8

• mechanical breakdown
• denaturation of prots by HCl
• enzymatic digestion of prots by pepsin (and milk protein by rennin in infants)
• enzymatic digestion of lipids by both salivary and gastric lipase
• delivers chyme to small intestine

Lipid soluble stuff, like alcohol and aspirin absorbed into blood

Only stomach fun esential to life is secretion of intrinsic factor for B12 absorption

• B12 needed –> for RBC maturation
• lack of intrinsic factor causes pernicious anemia
• treated with B12 injections

Question 9

Rgulation of gastric secretions: overview of neural and hormonal

Answer 9

Both neural and hormonal mechanisms
Gastric mucosa makes up to 3 L of gastric juices per day
Vagus nerve stimulation increases the secretions
Sympathetic stimulation decreases the secretions

Hormonal control largely gastrin

• increases enzyme and HCl secretions
• most small intestine secretions are gastrin antagonists

Question 10

Regulation of gastric secretions: first 2 of the 3 phases

Answer 10

1. Cephalic (reflex) phase = conditioned reflex triggered by aroma, taste, sight, thought
2. Gastric phase –> lasts 3-4 hrs; 2/3 gastric juice released
   - stimulated by distension, peptides, low acidity, gastrin (major stimulus)
   - enteroendocrine G cells stimulated by caffein, peptines, and rising pH –> stimulate gastrin

Question 11

Stimuli of gastric phase

Answer 11

Gastrin stimulates enzyme and HCl release
-low pH inhibits gastrin secretion (as between meals)

Buffering action of ingeted proteins –> rising pH stimulates gastrin secretions

3 chems: ACh, histamine, and gastrin stimulate parietal cells through second-messenger system –> all 3 are necessary for max HCl secretion

Question 12

HCl formation

Answer 12

Parietal cells pump H+ from carbonic acid breakdown into stomach lumen

• K+ goes into cells to balance charge
• HCO3- is made from carbonic acid breakdown
• HCO3- enters blood through Cl- and HCO3- antiporter –> blood leaving the stomach is more alkaline (called alkaline tide)
• Cl- follows the H+ to make HCl

Question 13

Third phase of gastric secretion

• stimulatory component
• inhibitory component
• override

Answer 13

Intestinal phase:

Stimulatory component
-partially digested food enters small intestine –> brief intestinal gastrin release

Inhibitory effects (enterogastric reflex and enterogastrones)

• chyme with H+, fats, peptides, irritating substances –> inhibit gastrin
• enterogastrones = secretin, cholecystokinin (CCK), vasoactive intestinal peptide (VIP) –> all inhibit gastrin

If small intestine is pushed to accept more chyme = “dumping system”

• naesea and vomiting
• common in gastric reduction for weight loss

Question 14

Enterogastric reflex

Answer 14

3 reflexes act to:

• inhibit vagal nuclei in medulla
• inhibit local reflexes
• activate sympathetic fibers –> tightening of pyloric sphincter –> no more food entry to small intestine

These lead to decreased gastric activity and protects the small intestine from excessive acidity

Question 15

Response of stomach to filling

Answer 15

stretches to accommodate incoming food

• pressure constant until 1.5 L food ingested
• reflex-mediated receptive relaxation
• coordinated by swallowing center of brainstem

gastric accommodation –> plasticity (stress-relaxation response) of smooth muscle –> basically is capable of establishing a new set point of stretch

Question 16

Gastric contractile activity

Answer 16

Peristaltic waves move toward pylorus at rate of 3 per minute

• basic electrical rhythm (BER) set by enteric pacemaker cells (formerly interstitial cells of Cajal)
• pacemaker cells linked by gap junctions –> entire muscularis contracts

Distension and gastrin increase force of contraction

Most vigorous near pylorus

Chyme is either

• delivered in 3 ml spurts to duadenum or
• forced backward into stomach (retropulsion)

Question 17

Regulation of Gastric emptying

Answer 17

as chyme enters duadenum

• receptors respond to stretch and chem signals
• enterogastric reflex and enterogastrones inhibit gastric secretions and duodenal filling

Carb-rich chyme moves quickly through duodenum

Fatty chyme remains in duodenum 6+ hrs

Question 18

Jejunum and Ileum

Answer 18

Jejunum extends from duodenum to ileum and is about 2.5 m long

Ileum joins large intestine at ileocecal valve and is about 3.6 m long

Question 19

Liver and Gallbladder

Answer 19

Liver
-biggest gland in body
-4 lobes –> right, left, caudate, and quadrate
-many funcs: only digestive func is bile production (bile = fat emulsifier)
BILE IS NOT AN ENZYME

Gallbladder

• chief function = bile storage (w/o water from liver)
• DOES NOT MAKE BILE, JUST STORES IT

Question 20

Liver Associated Structures

Answer 20

• lesser omentum anchors liver to stomach
• hepatic artery and vein enter at porta hepatis

bile ducts

• common hepatic duct leaves liver
• cystic duct connects to gallbladder
• bile duct formed by union of common hepatic and cystic ducts

Question 21

Liver microscopic anatomy

Answer 21

Liver lobules

• hexagonal structural and functional units
• composed of plates of hepatocytes (liver cells) –> filter and process nutrient rich blood
• central vein in longitudinal axis

Portal triad at each corner of lobule

• Branch of hepatic artery supplies oxygen
• branch of hepatic portal vein brings nutrient-rich blood
• bile duct receives bile from bile canaliculi and takes it to GI tract

Liver sinusoids = leaky capillaries bt hepatic plates

Stellate macrophages (hepatic macrophages/ Kupffer cells) in liver sinusoids remove debris and old RBCs

Question 22

Hepatocytes

Answer 22

increased rough and smooth ER, golgi, peroxisomes, and mitochondria

func:

• process bloodborne nutrients
• store fat-soluble vitamins
• perform detoxification
• makes 900 ml bile per day —–> KNOW THIS

Question 23

Liver regenerative capacity

Answer 23

• restores full size in 6-12 months after 80%

- injury –> hepatocytes –> growth factors –> endothelial cell production

Question 24

Bile

Answer 24

yellow-green alkaline solution containing:

• bile salts = cholesterol derivatives that function in fat emulsification and absorption
• bilirubin = pigment formed from heme –> bacteria break down in intestine to stercobilin –> brown color of feces
• cholesterol, triglycerides, phospholipids, and electrolytes

BILES ISN’T A DIGESTIVE ENZYME –> it doesn’t break chem bonds –> it emulsifies, turning big fat globules into little fat globules

Question 25

Enterohepatic circulation

Answer 25

-recycles bile salts

bile salts –> duodenum –> reabsorbed from ileum –> hepatic portal blood –> liver –> secreted into bile

Question 26

Gallbladder

Answer 26

• Thin-walled muscular sac on ventral surface of liver
• stores and concentrates bile by absorbing water and ions
• muscular contractions release bile via cystic duct which flows into bile duct. –> contractions are stimulated by CCK from small intestine

Question 27

Pancreas

Answer 27

Location

• mostly retroperitoneal, deep to greater curvature of stomach
• head encircled by duodenum –> tail abuts spleen

Endocrine func: pancreatic islets secrete insulin and glucagon

Exocrine func:

• acini (clusters of secretory cells) secrete pancreatic juice to duodenum via main pancreatic duct
• zymogen granules of acini cells contain proenzymes

Question 28

Pancreatic juice

Answer 28

1200-1500 ml/day

• watery alkaline solution (ph 8) neutralizes chyme
• electrolytes (mostly HCO3-) actually secreted by cells lining ducts, not acinar cells

Enzymes

• amylase, lipases, nucleases secreted in active form but require ions or bile for optimal activity
• proteases secreted in inactive form

Question 29

Protease activation in duodenum

Answer 29

• trypsinogen activated to trypsin by brush border enzyme enteropeptidase (enterokinase)
• Procarboxypeptidase, proelastase, and chymotrypsinogen activated by tripsin

Question 30

Regulation of Bile Secretion

Answer 30

Bile secretion stimulated by

• bile salts in enterohepatic circulation
• Secretin from intestinal cells exposed to HCl and fatty chyme

Hepatopancreatic sphyncter closed unless digestion active –> bile stored in gallbladder
-released to small intestine usually only with contraction

Gallbladder contraction stimulated by

• cholecytokinin (CCK) from intestinal cells exposed to acidic, fatty chyme
• vagal stimulation (minor stimulus)
• CCK also causes secretion of pancreatic juice and hepatopancreatic sphincter to relax

Question 31

Regulation of Pancreatic Secretion

Answer 31

CCK induces secretion of enzyme rich pancreatic juice by acini

• secretin causes secretion of bicarbonate-rich pancreatic juice by duct cells
• vagal stimulation also causes release of pancreatic juice (minor stimulus)

Question 32

Steps for release of bile and pancreatic juice

Answer 32

1. chyme entering duodenum causes duodenal enteroendocrine cells to release cholecystokinin (CCK) and secretin
2. CCK and secretin enter bloodstream
3. CCK induces secretion of enzyme-rich pancreatic juice. Secretin causes secretion of HCO3- rich pancreatic juice
4. Bile salts and, to a lesser extent, secretin transported via bloodstream stimulate liver to produce bile more rapidly
5. CCK (via blood stream) causes gallbladder to contract and Hepatopancreatic Sphincter to relax. Bile enters duodenu
6. During cephalic and gastric phases, vagal nerce stimulates gallbladder to contract weakly