RCSI Gastric Function Year 2 GIHEP Lecture Notes PDF

Summary

This document covers the introduction to gastric function, including learning outcomes, a detailed outline, and a discussion of the control of the GI tract, enteric nervous system, and gastric phases. It appears to be a set of lecture notes for a course in GI function.

Full Transcript

RCSI Royal College of Surgeons in Ireland Coláiste Ríoga na Máinleá in Éirinn

Gastric Function

Class Year 2
Course GIHEP

Title Introduction to Gastric Function
Lecturer Prof. Christopher Torrens
Presented by Dr Ebrahim Rajab
Date 12/09/24
Learning Outcomes
Explain the nervous control of the GIT and how enteric reflexes and hormonal
influences affect gastrointestinal function

Explain the initiation of slow waves and describe the three main motor functions of
the stomach: storage, mixing, emptying

Explain the role that the stomach plays play in digestion, describe secretions of the
stomach and name important substances absorbed by the stomach

Describe the mediators of gastric acid secretion, biochemical pathways within the
oxyntic cell and the main factors that inhibit gastric acid secretion

List the main causes of gastritis and peptic ulcer disease
Outline of Lecture
1) Control of the GI Tract
a. intrinsic and extrinsic control

2) Motor function
a. proximal and distal stomach

3) Secretary function
a. gastric juice and gastric glands
b. oxyntic or parietal cell
c. dysregulation of acid secretion

4) Absorption from the stomach
a. structural problems to absorption
Control of the GI Tract
Control of the GI tract occurs via a combination of neural and humoral
factors

Intrinsic control by the enteric nervous system (ENS)

Extrinsic control by autonomic nervous system (ANS)

Intrinsic & extrinsic control GI hormones
– more on these in the GI hormones lecture

Intrinsic smooth muscle action
Enteric Nervous System (ENS)
The ENS is contained entirely within the GI tract
– has three types of neurons

Sensory neurons, receive information from the
mucosa
– such as muscle stretch and chemical nature of
contents

Motor neurons control motility and secretions
– acts on smooth muscle and endocrine/exocrine
cells

Inter-neurons relay information from sensory to
motor neurons
 Enteric Nervous System (ENS)
The ENS is arranged in two plexuses along the
length of the digestive tract
– they are innervated by ANS and sensory
fibres

The Plexus of Auerbach lying between the
longitudinal and circular smooth muscle controls
motor function
– also called the myenteric plexus

Meissner’s Plexus controls secretion of the mucosa
– also called the submucosal plexus

Some fibres are excitatory (ACh) while others are
inhibitory (releasing NO / VIP)
FIGURE 63-2 Typical cross section of the
gut [From: Ganong’s review of medical
physiology]
Extrinsic control by the ANS
Fig. 2.1 Extrinsic branches of the
autonomic nervous system.

(A)Parasympathetic. Dashed
lines indicate the cholinergic
innervation of striated muscle in the
esophagus and external anal
sphincter. Solid lines indicate the
afferent and preganglionic efferent
innervation of the rest of the
gastrointestinal tract.

(B) Sympathetic. Solid lines denote
the afferent and preganglionic
efferent connections between the
spinal cord and the prevertebral
ganglia. Dashed lines indicate the
afferent and postganglionic efferent
innervation. CG , Celiac
ganglion; IMG , inferior mesenteric
7
 Extrinsic Control of GI Tract
Extrinsic control via the autonomic nervous system
Sympathetic Nervous System
– arises from the prevertebral ganglion
– post-ganglionic efferent fibres synapses with both
plexuses, also direct innervation of GIT smooth
muscle/glands
– primarily noradrenaline, decrease motility & secretions
Parasympathetic Nervous System
– vagus (CN X, upper GI) and pelvic nerve (lower GI)
– sensory afferents & pre-ganglionic efferents innervate
plexuses
– acetylcholine (ACh) increases contractions and
secretions
– physiological antagonism of NA - “rest and digest”

Fig. 2.2. Gastrointestinal
Physiology. Johnson, L.R.
Outline of Lecture
1) Control of the GI Tract
a. intrinsic and extrinsic control

2) Motor function
a. proximal and distal stomach

3) Secretary function
a. gastric juice and gastric glands
b. oxyntic or parietal cell
c. dysregulation of acid secretion

4) Absorption from the stomach
a. structural problems to absorption
Smooth Muscle Slow Waves
Waves of smooth muscle contraction are triggered by the Interstitial
Cells of Cajal
– between the circular and longitudinal smooth muscle

Cycles of depolarisation that do not reach threshold
– pass to the smooth muscle via gap junctions
– require additional stimulation

Occurs along the length of digestive tract
– different frequencies at different points
– duodenum fastest at about every 4-5 secs
– ileum every 6-7 secs, stomach and colon every 20 secs
Smooth Muscle Slow Waves
Stimulated
(via ACh etc)
30 depolarisation
Me m b r ane Po t e nt ial (m V)

0

-3 0
AP ≈ -40 mV

-6 0

-9 0
At rest Stimulated by SNS
hyperpolarisation
-12 0
5 10 15 20 25 30 35 40

(s)
 4. Gastrin and motilin

FIGURE 63-3 Membrane potentials in intestinal smooth muscle. Note the slow
waves, the spike potentials (= true APs -40mV), total depolarization, and
hyperpolarization, all of which occur under different physiological conditions of
the intestine. [From: Guyton and Hall. Textbook of Medical Physiology]
The Stomach - Regions
Motility
Oesophagus Proximal stomach
or orad

Pyloric
sphincter

Distal stomach
or caudad
Gastric Motor Function
The stomach performs three mechanical functions:

1. The (short term) storage of ingested food
– the reservoir function

2. The mixing of contents

3. The emptying into intestines
Receptive Relaxation
Swallowing relaxes the lower oesophagus and proximal stomach
– receptive relaxation

This is a vagovagal reflex*, relaxing the stomach so (intraluminal) pressure remains
stable despite the increased volume
– may involve the release of NO

Gastric accommodation and dilation of the proximal stomach also allows for an
increased volume without increase in pressure
– controlled by enteric nervous system
– beyond certain volumes is a markedly increase pressure

(*refers to gastrointestinal tract reflex circuits where afferent and efferent fibers of the vagus nerve coordinate
responses to gut stimuli via the dorsal vagal complex in the brain. Not to be confused with vasovagal)
 Volume vs. Pressure If the vagus
nerve is
transected,
receptive
relaxation is
80 absence of vagal nerve impaired, and
the stomach
Pressure (cmH2O)

becomes less
60 distendible.

40

normal
20

200 400 600 800 1000
volume (ml)
Mixing & Emptying
The distal stomach is similar to small intestine and show spontaneous or
basal electrical rhythm

Contractions start mid-stomach and spread distally

The force and speed of contractions increase as they reaches the pyloric
sphincter/gastroduodenal junction

The effect of this is contractions overtake contents
– small amount of food emptied due to narrow pyloric sphincter
– most is pushed back for the next wave (i.e. mixing)
 Mixing & Emptying
Motility
1
Oesophagus Proximal stomach
or orad

2

Pacemaker 3
region
1

Pyloric
sphincter 2
4
3
Spread of contraction
4
5

5
Distal stomach
or caudad
Factors Affect Contractions
In the fasted state, stomach is quiescent
– although depends on the phase (e.g. cephalic phase - Pavlov)

In the fed state contractions are fairly continuous

These are controlled by various neurohumoral and mechanical stimuli
– mechanical stimuli such as distension
– ACh (vagus) increases the number and force of contractions
– hormones such as gastrin increase contractions
– hormones such as secretin decrease contraction
Emptying
Emptying is due to coordinated contraction
– peristalic contractions in the stomach, relaxed pylorus and lack of contraction in
duodenum

Time spent in the stomach is dependent on composition
– liquid empties quickly
– solids have to be reduced in size so take longer in the stomach

Composition of food entering the duodenum activates intestinal receptors
leading to hormone release that alter gastric motility and emptying
– properties such as acidic, lipid, osmotic pressure
Outline of Lecture
1) Control of the GI Tract
a. intrinsic and extrinsic control

2) Motor function
a. proximal and distal stomach

3) Secretary function
a. gastric juice and gastric glands
b. oxyntic or parietal cell
c. dysregulation of acid secretion

4) Absorption from the stomach
a. structural problems to absorption
 The Stomach - Regions
Secretory

Oesophagus Fundus

Pyloric
sphincter

Body

Antrum
Gastric Juice
The stomach secretes ~1,500 ml/day of gastric juice

This is predominantly water but also includes
– HCl, HCO3-, other ions (Na+, K+), mucous and pepsin (enzyme)

This also includes swallowed saliva and reflux duodenal fluids such as
bile and pancreatic juice

It is the gastric juice that mediates what digestion occurs in the stomach
Gastric Digestion
All digestion is the breaking of large macromolecule into smaller parts that
are easier to absorb

Carbohydrate digestion starts in the mouth with salivary amylase
– which is largely inactivated by the acidic stomach

Lipid digestion starts in the stomach by gastric lipase
– activated by the low stomach pH

Protein/peptide digestion also starts in the stomach by the enzyme pepsin
– also activated by the low pH from inactive precursor (pepsinogen)
Gastric Glands (pyloric & oxyntic)
Surface epithelial cells throughout stomach
– secrete thick mucous with mucin and HCO3-
– lubricates and protects against low pH and
enzymes

Pyloric Glands in the antrum of the stomach
– mostly mucous cells
– Gastrin or G cells secrete gastrin
peptide hormone released into the blood
(endocrine)
– Delta or D-cells release somatostatin
peptide hormone that has endocrine and
paracrine actions

www.epomedicine.com
 Gastric Glands (pyloric & oxyntic)
Oxyntic Glands are located in the fundus and
body

Oxyntic or Parietal Cells
– secrete HCl (kills bacteria, lower pH for
digestion)
– also secrete Intrinsic Factor (Vitamin B12
absorption).
Peptic or Chief Cells
– secrete pepsinogen, the inactive precursor of
pepsin
Enterochromaffin-like Cells (ECL cells) (similar to
mast cells)
– secrete local hormone histamine (paracrine)
Also mucous neck cells and D cells
– secrete a thin mucus and somatostatin
respectively
Regulation of Gastric Secretion
Vagal stimulation via ACh
– release of all gastric secretions from the various cell types
– acid, pepsinogen, water, mucus, gastrin, histamine
– also increases gastric motility (see above)

Gastrin release from G cells stimulated by Vagus Nerve via gastrin releasing hormone (GRP)
– also stimulated by amino acids and inhibited by low pH (