Salivary and gastric secretions

Question 1

Major glands that secrete saliva

Answer 1

Submandibular

• 70% of saliva
• Saliva is mixed

Parotid:

• 25% of saliva
• Serous saliva

Sublingual

• 5% of salvia
• Mucous saliva

Question 2

Structure of saliva glands

Answer 2

Blind ended acini that drain into major ducts

Question 3

Functions of saliva

Answer 3

Lubrication: swallowing, speech, dissolving substances.

Protection: Oral bacteria, neuralisation of acid from oral bacteria, wash away bacteria, contains substances to inhibit bacterial growth

Digestion:

• alpha amylase; breaks down carbs
• lingual lipase; breaks down lipids

Question 4

Alpha amylase

Answer 4

Also called ptyalin

Enzyme found in saliva that hydrolyses starch

It becomes denatured by gastric acid.

Question 5

Lingual lipase

Answer 5

Enzyme in saliva that hydrolyses triglycerides.

Secreted from salivary glands on the tongue surface and remains active in the stomach.

Question 6

Sjogren’s syndrome

Answer 6

An autoimmune disease that attacks exocrine glands; especially salivary and tear glands.

Symptoms: [sicca symptoms]
Dry mouth
Dry eyes

Question 7

Xerostomia

Answer 7

A condition where a patient lacks adequate saliva.

Consequence:

• Dental cavities due to loss of protection against bacteria.
• Difficulty speaking
• Difficulty swallowing
• Halitosis (bad breath due to bacterial overgrowth).

Question 8

Two types of salivary secretions

Answer 8

Serous:
Mainly composed of ptyalin which hydrolyses starch.

Mucous:
Mainly composed of mucin- lubricant

Question 9

Primary saliva

Answer 9

The fluid firstly released from the acinar cells in the salivary glands.

It resembles acinar fluid.

Question 10

First stage of salivary secretion: Primary fluid secretion

Answer 10

Acinar cells:
- Basolaterally, Na+, K+, 2Cl- cotransporter takes in Cl- ions.

• Apically, Ca2+ activated Cl- channels release Cl- ions into acinar lumen.
• Na+ enters the acinar lumen paracellularly through leaky tight junctions.
• Water enters acinar lumen via aquaporin 5 or paracellularly

Question 11

Second stage of salivary secretion: NaCl reabsorption and K+ secretion.

Answer 11

At the ductal cells:

• Removal of Na+ ions. Apical Na+ channels take Na+ into duct cells.
  Na+ leaves ductal cell via basolateral Na+/K+ ATPase
• Removal of Cl-.
  Cl- channels at the apical and basolateral membrane of the ductal cells.
• Water not reabsorbed. Ductal cell tight junctions are not leaky.
  No aquaporins in apical membranes.
• K+ secrete into ductal lumen via potassium proton exchangers at the apical membrane.
• HCO3- secreted into ductal lumen via bicarbonate chloride exchanger at the apical membrane.

This forms hypotonic saliva.

Question 12

Salivary flow rate

Answer 12

The greater the rate of secretion, the less hypotonic saliva is.

Slower rate of secretion= more time for the reabsorption of electrolytes.

Faster flow = more Na+ and Cl-

Question 13

Electrolyte components in saliva

Answer 13

Na+ and Cl- less than in plasma

HCO3- and K+ greater than that in plasma

Question 14

Central control of salivary secretions

Answer 14

Efferent nerves from salivary nuclei in the pons reach salivary glands;

• Glossopharyngeal nerves
• Facial nerves

AcH is released—> acts on muscarinic receptors

Parasympathetic and sympathetic stimulation.

Question 15

What stimulates and inhibits saliva secretion centrally?

Answer 15

Secretion is stimulated by:

• Thoughts
• Smell
• Taste
• Nauseas

Secretion is inhibited by:

• Dehydration
• Fatigue
• Fear
• Sleep

Question 16

Sympathetic stimulation of the salivary glands

Answer 16

Increases output of amylase

Reduces blood flow to glands = decreased rate of secretion.

Question 17

Parasympathetic stimulation of the salivary glands

Answer 17

Increases blood flow to the glands

Promotes secretion of saliva- myoepithelial cells around acini and duct contracts to eject saliva.

Question 18

Hormonal effect on saliva secretion

Answer 18

Superior cervical ganglion innervates the salivary glands.

Aldosterone is secretion to increase ductal Na+ absorption and K+ secretion.

Question 19

Components of gastric juice

Answer 19

Water, electrolytes

HCl

Pepsin

Mucus: protects surface epithelial cells from acid and pepsin erosion

Intrinsic factor

Question 20

Function of HCl in gastric juice

Answer 20

Hydrolyses fat and starch.

Antiseptic

Provides optimum pH for pepsin- converts pepsinogen to pepsin.

Question 21

Pepsin

Answer 21

Endopeptidase that leaves peptide bonds in proteins

Secreted as inactive pepsinogen- only activated at pH<5

Question 22

Origins of gastric secretions

Answer 22

Exocrine [ pepsin, IF, HCl] : fundus, corpus of the stomach.

Endocrine [secretes gastrin]: antrum

Question 23

Mucous cells

Answer 23

Cell found in the gastric gland that secretes mucus- protective barrier

Question 24

D cells

Answer 24

Endocrine cells that secretes somatostatin

Found in gastric glands

Question 25

Chief cells

Answer 25

Cells of the gastric glands that secrete pepsinogen

Question 26

Parietal/ oxyntic cells

Answer 26

Cells of the exocrine region in the stomach- fundus + corpus.

Secretes acid and intrinsic factor

Question 27

Histamine cells

Answer 27

Cells of the exocrine region in the stomach.

Secretes histamine which stimulates gastric secretion.

Question 28

Endocrine G cells

Answer 28

Cells of the endocrine region in the stomach that produces gastrin.

Question 29

Protection against self digestion and mechanical damage

Answer 29

Secretion of mucus layer by mucous cells.

Mucin and HCO3- released neutralise H+ ions.

Tight junctions between cells prevent acid from entering underlying tissue.

The mucosal barrier has a pH of around 7, prevents the activation of pepsinogen— prevents enzymatic damage.

Question 30

Gastritis

Answer 30

Inflammation of the gastric mucosa.

Most commonly bacterial cause.

Can also be caused by:

• smoking
• alcohol
• NSAIDs
• chronic stress

Question 31

Regeneration of gastric cells

Answer 31

When the surface epithelium is damaged, stem cells at the neck of gastric glands rapidly divide.

This is called restitution- helps to heal gastritis

Question 32

Acid secretion from oxyntic cell

Answer 32

Tubulovesicular membrane contains H+/K+- ATPase that causes acid secretion.

When stimulated, tubulovesicular membrane fuses to form canalicular membrane- increased SA.

Fusion causes more K+/H+- ATPasee to be inserted into canalicular membrane.
- K+ and Cl- channels also inserted

Question 33

Formation of acid in oxyntic cells

Answer 33

H+ and HCO3- generated via H2CO3 breakdown via carbonic anhydrase.

H+ pumped into lumen via H+/K+ ATPase

HCO3-/ Cl- exchanger in the basolateral membrane brings Cl- into the cell.

Cl- leaves cell via Cl- channel, down its concentration gradient.

Question 34

Postprandial alkaline tide

Answer 34

State where the gastric blood becomes alkaline due to the entry of HCO3- during acid production.

HCO3- is exchanged for Cl- basolaterally.

Question 35

Proton pump inhibitors

Answer 35

Drugs that inhibit H+/K+- ATPase on the luminal surface of oxyntic cells.

Example: Omeprazole

Question 36

Stimulators of acid secretion

Answer 36

Gastrin- from antral G cells.

Histamine- mast cells

AcH- postsynaptic vagal fibres innervating gastric mucosa.

Question 37

Paracrine inhibitors of gastric acid secretion

Answer 37

Somatostatin- antral and oxyntic D cells.
- Pancreatic cells

Prostaglandins- mucosal cells

Question 38

Gastrin and AcH stimulation

Answer 38

Both stimulants of acid secretion.

Stimulation is triggered by an increase in intracellular Ca2+.

Question 39

Histamine

Answer 39

Acid secreting stimulant released by mast cells.

Binds to H2 receptors on oxyntic cells.

Stimulates acid secretion by increasing intracellular cAM.

Question 40

Prostaglandin E2

Answer 40

Molecule produced in the stomach.

Antagonist of histamine - inhibits intracellular production of cAMP

This inhibits acid secretion.

NSAIDs inhibits prostaglandin E2

Question 41

Atrophic gastritis

Answer 41

Autoimmune condition where antibodies attack gastric parietal cells.

Causes hypochlorhydria and IF deficiency- leads to pernicious anaemia.

Question 42

Hypochlorhydria

Answer 42

Condition that describes insufficient acid secretion.

Question 43

Cephalic controlled gastric secretion

Answer 43

This accounts for 35% control of secretion.

Triggered by sight, smell, taste, chewing.

This stimulates the vagus nerve to secrete AcH at the synapse of gastric cells.

This increases intracellular Ca2+ and stimulates the secretion of gastrin from G cells.

Acts on parietal cells and causes the release of HCl and pepsin.

Question 44

Gastric regulation of gastric secretion

Answer 44

This accounts for controlling 60% of gastric secretions.

1. Distension of the stomach stimulates vago-vagal and local reflexes.
2. This stimulates the release of ACh at nerve endings.
3. Stimulates release of gastrin from G cells of the stomach.
4. Gastrin acts on parietal cells to stimulate release of HCl and Pepsin

Question 45

Intestinal regulation of gastric secretion

Answer 45

This accounts for 5% of gastric secretion regulation.

1. Amino acids from protein digestion in the duodenum is detected.
2. Stimulates G cells in the intestines to stimulate parietal cells.
3. This stimulates gastric secretions.

Inhibitory effects:

• Protein digestion detected stimulates CCK (cholecystokinin) and GIP (gastric inhibitory polypeptide).
• CCK and GIP inhibit the secretion of gastrin and inhibits gastric parietal cells.

Question 46

Gastrin

Answer 46

A hormone released from the G cells in the pylorus and duodenum.
- Acts on CCK2 receptors

Secretion is stimulated by the release of amino acids and peptides in the stomach.

Secretion is inhibited by low pH.

Question 47

Histamine

Answer 47

Molecule released by ECL cells close to parietal cells.

ECL cells stimulated by gastrin and ACh cause the release of histamine.

Histamine acts on parietal cells to stimulate gastric secretions.

Question 48

GRP

Answer 48

Gastrin releasing peptide

Stimulated by vagal stimulation

Released from G cells to stimulate gastrin release.

Inhibits the release of somatostatin from D cells.