GI Tract Secretion

Question 1

How are GI secretions regulated ?

Answer 1

Through hormonal and neural signals, which can be chemical (sight and presence of food), or physical (stretch receptors) + input from higher centers.

Question 2

Identify the main stages of digestion. How many hours does each take ?

Answer 2

Cephalic (thinking about food): 1 hour
Gastric (food is in stomach)
Intestinal (food is in intestines)

Question 3

Identify the primary regulatory events in the cephalic phase.

Answer 3

• Initiated by taste, thought, smell of food (acquired reflex)
• Brain higher integrating centers send signals to parasympathetic and sympathetic branches.
• Changes in the mouth: PSNS branch increases salivary secretions while SNS branch increases blood flow to salivary glands and increases salivary V
• Changes in stomach: PSNS increases secretions in stomach, including HCl, mucus, pepsin, and gastrin secretions (and blood factors such as intrinsic factor), while SNS branch increases blood flow to stomach
• Other changes: PSNS stimulates bile ducts, hepatocytes, and pancreatic acinar cells

Question 4

Identify the primary regulatory events in the gastric phase.

Answer 4

• Initiated by food entering stomach causing release of gastrin by G cells due to:

• Parasympathetic pathways
• Decreased acidity in stomach due to buffering of food (especially caffeine, alcohol, calcium which are all basic)
• Distention of antrum
• Proteins, peptides, and AAs
• Release of gastrin causes increased gastric motility, increased parietal cell secretions (including HCl), and trophic maintenance of GI epithelium
• Low pH (e.g. HCl, stimulated by gastrin release) causes negative feedback and inhibits release of gastrin

Question 5

Identify the primary regulatory events in the intestinal phase.

Answer 5

• Initiated by presence of food in the duodenum

• If the pH > 3, duodenal peptides/AAs cause release of gastrin
If pH < 2, gastric inhibition and intestinal stimulation occurs
• Duodenal fats and breakdown products cause release of CCK and GIP
• Acid entering the intestine causes secretin release

Question 6

What is a secretion ? Identify the main secretions of the GI (and accessory organs).

Answer 6

Addition of substances (enzymes, ions, fluids) into the GI lumen

• Saliva (salivary glands)
• Gastric secretions (cells of gastric mucosa)
• Pancreatic secretions (Exocrine cells of pancreas)
• Bile (liver)

Question 7

SALIVA

• Composition
• Factors which increase it
• Factors which decrease it

Answer 7

SALIVA
-Composition: High HCO3-, high K+, alpha-amylase and lingual lipase
(hypotonic)
-Factors which increase it: PSNS and SNS
-Factors which decrease it: Atropine, sleep, dehydration

Question 8

How much saliva do we produce per day approximately ?

Answer 8

We approximately produce 1 L of saliva per day

Question 9

What are the main functions of saliva ?

Answer 9

• Initial digestion of starches
• Dilution and buffering of ingested food
• Protection of teeth and gums
• Lubrication of ingested food with mucous (mucin) so we can swallow the food

Question 10

Identify the main salivary glands, identify the location of each, and the type of fluid secreted.

Answer 10

• Submandibular gland: under lower edge of mandible, mixed glands containing mucous and serous cells
• Sublingual gland: deep in floor of mouth, underneath tongue, mostly mucous cells
• Parotid: below ear and over the masseter (jaw muscle), serous cells secreting an aqueous fluid composed of water, ions, and enzymes

Question 11

Identify and explain the main stages of salivary production.

Answer 11

Saliva is produced by salivary glands in 3 stages:

1) Acinar cells (furthest away from mouth) secrete primary secretion (isotonic), rich in NaCl, as well as amylase and mucin. This secretion also contains K+ and HCO3-.
2) Myoepithelial cells are then stimulated by neural input to eject saliva into the duct
3) Duct cells perform secondary modification, which consists of reabsorption of Na+ and Cl-, and addition of K+. The concentration of HCO3- is also modified depending on the flow rate; if high flow rate, saliva has ↑ HCO3- whereas if low, more HCO3- is extracted so ↓ HCO3-.

In the mouth, saliva is hypotonic (more dilute than plasma).

Question 12

Describe the main salivary reflexes.

Answer 12

1) Simple (unconditioned) reflex: Chemo/Pressure receptors in mouth activated in presence of food (or other stimulus) → Impulses sent via afferent nerves → Salivary centers in medulla → Impulses via extrinsic autonomic nerves (SNS and PSNS stimulation) → Salivary glands increase saliva production
2) Acquired (conditioned) reflex: Think about/hear/see preparation of food → Cerebral cortex Salivary centers in medulla → Impulses via extrinsic autonomic nerves (SNS and PSNS stimulation) → Salivary glands increase saliva production

Question 13

How are the three stages of saliva production regulated ?

Answer 13

By the SNS and PSNS. In health, PSNS more active whereas in stressful times, SNS more active. Either way, affect acinar and ductal cells and therefore result in slightly different salivary compositions.

• In health, mainly PSNS → large V, watery, enzyme rich saliva
• In stressful times, mainly SNS → small V, thick, mucousy saliva

Question 14

Describe the function of the oesophageal secretions.

Answer 14

No real role in digestion, only secretes mucous for protection and lubrication.

• Main body lined with simple mucous glands (protects against mechanical damage)
• Gastric end (especially) has compound mucous glands (protects against chemical damage)

Question 15

Identify the main secretions of the stomach, along with the name of the cells secreting each secretion, and the location in the stomach of each cells.

Answer 15

►Parietal cells (in body): Intrinsic Factor + HCl to stomach
►Chief cells (in body): Pepsinogen to stomach
►G cells (in antrum): Gastrin to circulation
►Mucous cells (in antrum): Mucous to stomach

Question 16

Explain the function of each of the main gastric secretions.

Answer 16

• Pepsinogen: Protein digestion
• Intrinsic Factor: Vitamin B12 absorption (in ileum)
• HCl: Protein digestion (a bit), mainly for pepsinogen activation at acid pH (creates pH approximately 2)
• Mucous: Protection and lubrication

Question 17

Identify factors which increase, and decrease secretion of HCl.

Answer 17

• Gastrin increases secretions of HCl

- H+ in stomach decreases secretions of HCl

Question 18

Identify factors which increase, and decrease secretion of pepsinogen.

Answer 18

• Acetylcholine increases secretions of pepsinogen

- Chyme in the duodenum decreases secretions of pepsinogen

Question 19

Identify factors which increase, and decrease secretion of intrinsic factor.

Answer 19

• Histamine and parasympathetics increase secretions of intrinsic factor
• Atropine, Somatostatin, Omeprazole, Cimetidine all decrease secretions of intrinsic factor

Question 20

Define gastric pit.

Answer 20

Indentations in the stomach which denote entrances to oxyntic/gastric glands.
These pits increase the stomach SA.

Question 21

Identify the type of cell which gives rise to each gastric secretion. Where in the gastric pits are these located ?

Answer 21

• Mucous neck cells (closest to stomach lumen) → Mucus
• Oxyntic/parietal cells → HCl and Intrinsic Factor
• Peptic/chief cells → Pepsinogen (furthest away from stomach lumen)
• G cells → Gastrin

Question 22

Explain the process of HCl production by parietal/oxyntic cells in the stomach.

Answer 22

1) In apical membrane
- H+ is secreted into the lumen via the H+-K+ ATPase
- Cl- follows by diffusion through an apical channel

This process (secretion of H+ and Cl-) occurs in separate stages, because otherwise formation of HCl in parietal cells would denature them. 
In the lumen, H+ and Cl- can freely associate and dissociate chemically without a problem (protection present, and HCl actually needed there).

2) Basolateral membrane
- HCO3- (out of parietal cell, into blood) is exchanged for Cl- (into parietal cell) via the chloride-bicarbonate exchanger (alkaline tide)
- Eventually HCO3- is secreted back into GI tract in pancreatic secretions

Question 23

What proportion of gastric secretions occurs in each phase of digestion ?

Answer 23

Cephalic- 30%
Gastric- 60%
Intestinal- 10%

Question 24

Describe the gastric effects in the cephalic phase, explaining the nervous pathways involved.

Answer 24

• Direct stimulation of parietal cells by vagus (hence production of HCl and intrinsic factor)
• Indirect stimulation of parietal cells by gastrin (vagal gastrin releasing peptide GPR stimulates gastrin release from G cells. Gastrin hormone enters the circulation and stimulates parietal cells to release HCl).

Question 25

Describe the gastric effects in the gastric phase, explaining the nervous pathways involved.

Answer 25

Distention causes:

• Direct vagal stimulation of parietal cells
• Indirect stimulation of parietal cells via gastrin (direct effect of AAs and small peptides on G cells stimulates gastrin release)
• Local reflexes in the antrum that stimulate gastrin release

Question 26

Describe the gastric effects in the intestinal phase, explaining the nervous pathways involved.

Answer 26

Following presence of breakdown products of proteins in the duodenum, activity in the stomach pretty much ceases (residual activity, i.e. 10% of gastric secretions, are for lubrication and protection)

Question 27

When and how is HCl secretion inhibited ?

Answer 27

When: HCl secretion is inhibited when HCl is no longer needed to convert pepsinogen into pepsin. This occurs after the chyme moves into the small intestine and the H+ buffering capacity of the food is no longer a factor

How: SOMATOSTATIN

• Direct pathway: binds to receptors on parietal cells and inhibits Adenylate Cyclase via Gi protein so inhibits HCl release
• Indirect pathway: inhibits hiaatamine release from stomach and gastrin release from G cells so HCl inhibited

Question 28

What factors stimulate pepsinogen secretion ?

Answer 28

• Vagal stimulation

- H+ triggers local reflexes which stimulate chief cells to secrete pepsinogen

Question 29

Briefly explain how pepsinogen is activated ?

Answer 29

• Pepsinogen inactive (which prevents gastric pit cells from being digested).
• Activated by pH of 2-3 (when comes into contact with HCl)

Question 30

What amount of pancreatic secretions are secreted into the duodenum per day ?

Answer 30

Approximately 1 L of exocrine pancreatic secretions are secreted into the duodenum per day

Question 31

Describe the composition of pancreatic secretions into the duodenum. What is the function of this secretion ?

Answer 31

• Aqueous solution containing enzymes (pancreatic lipase, amylase, and proteases) and high concentration of HCO3- (isotonic). Enzymes are stored in condensed zymogen granules until released (to avoid digestion of pancreas itself)
• Function of this secretion is to neutralise stomach H+, and enzymes digest carbs, proteins and lipids

Question 32

Name the factors that increase pancreatic secretions, as well as any factors which inhibit pancreatic secretions.

Answer 32

Secretin
Cholecystokinin (CCK, potentates secretin)
Parasympathetic innervation from the vagus

Sympathetic innervation inhibits pancreatic secretions

Question 33

Why don’t the pancreatic enzymes digest the pancreas itself ?

Answer 33

Because they are stored in condensed zymogen granules until released.

Question 34

Describe the process of formation of pancreatic secretion.

Answer 34

1) Aqueous component of secretion released from centroacinar cells and ductal cells. This is isotonic and contains Na+, K+, Cl-, and HCO3-. Modification of the ion composition by the ductal cells (bicarbonate chloride exchanger bringing bicarbonate into ductal lumen for chloride which goes into pancreatic ductal cell) results in a fluid secretion rich in HCO3-
2) Enzymatic component of secretion is released from acinar cells. Pancreatic amylase and lipase are secreted as active enzymes. Pancreatic proteases are secreted in an inactive form and activated in the duodenum.

Final pancreatic secretion is also isotonic.

Question 35

Identify the reaction catalysed by each kind of pancreatic enzyme.

Answer 35

• Pancreatic amylase: Polysaccharde → Disaccharide
• Pancreatic lipase: Triglycerides → Monoglycerides + FA
• Pancreatic proteases: Proteins → AAs and small peptides

Question 36

Which of salivary or pancreatic amylase is more important ?

Answer 36

Pancreatic amylase is much more important than salivary amylase

Question 37

Identify the different kinds of proteolytic pancreatic enzymes. Are these active or inactive ? Why ?

Answer 37

• Trypsinogen
• Chymotrypsinogen
• Procarboxypeptidase

These are all inactive (in zymogens) to prevent self-digestion

Question 38

Explain how proteolytic pancreatic enzymes are activated.

Answer 38

Trypsinogen is activated by enteropeptidase (aka enterokinase) in luminal border of cells lining duodenal mucosa, forming Trypsin.

Trypsin is the duodenal lumen:

1) activates more trypsinogen to form more Trypsin
2) activates chymotrypsinogen into chymotrypsin
3) activates procarboxypeptidase into carboxypeptidase

Question 39

Explain the regulation of pancreatic secretions in the three phases of digestion.

Answer 39

Cephalic phase: some secretion initiated by vagus nerve (mainly enzymatic secretion)

Gastric phase: some secretion initiated by stomach distention and mediated by vagus nerve (mainly enzymatic secretion)

Intestinal phase: initiated by distention of duodenum, accounts for 80% of pancreatic secretions (both enzymatic and aqueous secretions are stimulated)

Question 40

Describe the pancreatic response in the intestinal phase.

Answer 40

1) Acinar cells
-Duodenal I cells secrete CCK in response to the presence of AAs, small peptides, and FAs in the small intestine lumen
-Vagal release of ACh potentiates CCK action
This all triggers acinar cells to produce enzymes

2) Ductal cells
-Secretin released by S cells of the duodenum is the major stimulus for aqueous rich HCO3- secretion
-Secretin release is triggered by the arrival of acidic chyme in the duodenum
-ACh and CCK potentiate secretin action
This triggers ductal cells to produce Na+, K+, Cl-, HCO3- (bicarbonate will hence buffer acidic chyme to prevent it damaging duodenum)

Question 41

What are the main functions of the gallbladder ?

Answer 41

• Stores bile
• Concentrates bile (epithelial cells lining gallbladder absorb ions and water iso-osmotically)
• Ejects bile

Question 42

Which cells produce bile ? How does bile flow from here to the gallbladder ?

Answer 42

Hepatocytes

Through bile ducts

Question 43

How soon after a meal does bile start to get ejected ? What is the main stimulus for bile ejection ?

Answer 43

Bile ejections starts about 30 minutes after a meal

Major stimulus for ejection is release of CCK from I cells in duodenum and jejunum

Question 44

What is the function of bile ?

Answer 44

Essential for digestion and absorption of lipids; bile salts emulsify lipids to prepare them for digestion and solubilise the products of digestion into packets called micelles.

Question 45

What are the main components of bile ?

Answer 45

By decreasing order of presence

Bile acids, phospholipids, cholesterol, bile pigments (e.g. bilirubin), HCO3- (NO ENZYMES)

Question 46

Describe the regulation of bile secretion in between meals.

Answer 46

• Bile salts are recirculated to the liver via the enterohepatic system (i.e. more bile produced)
• Bile is then stored and concentrated in the gallbladder.

Question 47

Describe the regulation of bile secretion in the cephalic phase.

Answer 47

Neural (parasympathetic) stimulation via the vagus nerve to increase bile flow towards duodenum.

Question 48

Describe the regulation of bile secretion during/after a meal.

Answer 48

Chyme in duodenum stimulates release of CCK and secretin.

• CCK triggers release of stored bile through gall bladder contraction + Sphincter of Odi relaxation
• Secretin triggers bile secretion, especially NaHCO3- (bicarbonate ions)

Hence, the bile enters the duodenum.

Question 49

Summarise the regulation of biliary secretions by secretin and CCK.

Answer 49

• Chyme in duodenal lumen in intestinal phase
• Secretin release from duodenal mucosa
(Secretin carried by blood)
• Hepatocytes and bile duct cells
• ↑HCO3- rich bile secretion
(Neutralisation of duodenal H+ and micelle formation)
• Back to top
——–
• Chyme in duodenal lumen in intestinal phase
• CCK release from duodenal mucosa
(CCK carried by blood)
• Gallbladder contraction and sphincter of Odi relaxation
(Digestion of lipid rich chyme contents, presence of food results in flow of bile)
• Back to top

Question 50

Identify all stimuli for biliary secretion.

Answer 50

• Secretin (bile production)
• CCK (gallbladder contraction and sphincter of Odi relaxation)
• Some central and enteric nerve input

Question 51

Identify the main secretion of the large intestine. What is the function of this secretion ?

Answer 51

Alkaline mucus (no digestive enzymes, high [K+] and [HCO3-])

Functions: protection and lubrication + neutralisation of H+ produced by gut bacteria

Question 52

What is the trigger to the secretion of the alkaline mucus in the large intestine ?

Answer 52

• Greatest trigger is distention/mechanical stimulation of walls
• Increased secretion triggered by ACh and vasoactive intestinal peptide
• Decreased secretion triggered by adrenaline and somatostatin

Question 53

What is the result of extreme parasympathetic stimulation on alkaline mucus secretion in the large intestine ?

Answer 53

Extreme/increased PSNS stimulation → Excess mucus → Increased defecation (e.g. nervousness, stress) (since amount of mucus impacts on motility in large intestine)

Question 54

True or false: sometimes in disease, mucus production can increase, which can result in diarrhea.

Answer 54

True. Sometimes in disease, mucus production can increase, which can result in diarrhea.