GIT Physiology PDF

Summary

These are lecture notes on GIT physiology, focusing on the regulatory mechanisms of the gastrointestinal tract. The notes cover intrinsic and extrinsic nervous system involvement, as well as discussing the different phases of gastric function (cephalic, gastric, and intestinal phases). The content also includes mechanisms of digestion and absorption of carbohydrates, proteins, and lipids.

Full Transcript

Faculty of
Physical Therapy

GIT Physiology
Regulatory mechanisms in the GIT

Neural Regulation
The gut is innervated by two sets of nerves:
I- The intrinsic nervous system, (enteric nervous
system, ENS), has cell bodies that are located
within the wall of the gut (submucosal and
myenteric plexuses).
II- The extrinsic nervous system is defined as
nerves that innervate the gut, with cell bodies
located outside the gut wall; these extrinsic nerves
are part of the autonomic nervous system (ANS).
Regulatory mechanisms in the GIT
I- The intrinsic nervous system
The gastrointestinal tract has a nervous system all its
own called the enteric nervous system (ENS).
It lies entirely in the wall of the gut, beginning in the
esophagus and extending to the anus.
The enteric nervous system is composed mainly of two
plexuses:
(1) an outer plexus called the myenteric or Auerbach's
plexus, and
(2) an inner plexus, called the submucosal or
Meissner's plexus.
Regulatory mechanisms in the GIT

I- The intrinsic nervous system
(1) an outer plexus lying between the longitudinal
and circular muscle layers, called the myenteric or
Auerbach's plexus, and control the motility
function.
(2) an inner plexus, called the submucosal or
Meissner's plexus, that lies in the submucosa and
control the secretory function, absorbtion, and
contraction of submucosal muscles that affect the
degree of infolding of GIT epithelium.
Regulatory mechanisms in the GIT

I- The intrinsic nervous system
Stimuli in the wall of the gut are detected by
afferent neurons, which activate interneurons
and then efferent neurons to alter function.
In this way the ENS can act autonomously from
extrinsic innervation.
However, neurons in the ENS, are innervated by
extrinsic neurons.
Regulatory mechanisms in the GIT
Regulatory mechanisms in the GIT
II- The extrinsic nervous system
via the two major subdivisions of the ANS,
1- Parasympathetic innervation
The vagus nerve, innervates the esophagus,
stomach, gallbladder, pancreas, small intestine,
cecum, and the proximal part of the colon.
The pelvic nerves (S2,3,4) innervate the distal
part of the colon and the anorectal region.
These nerves results mainly in stimulation of
GIT motility and secretion.
Regulatory mechanisms in the GIT
2- Sympathetic innervation
Sympathetic innervation to GIT arise from T6- L2
segments.
These nerves results mainly in inhibition of GIT
motility and secretion.
Also, it innervates the smooth muscle cells of
blood vessels, leading to vasoconstriction
Sensory nerve endings that arise from GIT epithelium
and relay in cell bodies of enteric nervous system, in
prevertebral ganglia of sympathetic, in vagus nerve or
the spinal cord causes local reflexes.
Regulatory mechanisms in the GIT
 Stomach
The stomach is the most distensible part of the GI
tract.
Its functions are:
to store food,
to initiate the digestion of proteins,
to kill bacteria with the strong acidity of gastric
juice,
to move the food into the small intestine as a
pasty material called chyme.
Stomach
Gastric glands
Gastric glands contain several
types of cells that secrete
different products:

1. goblet cells, secrete mucus;

2. parietal (or oxyntic) cells,
secrete HCl; and intrinsic factor

3. chief (or zymogenic) cells,
secrete pepsinogen,

4. enterochromaffin-like (ECL)
cells, secrete histamine
Pyloric glands
contain several types of cells:

❑ goblet cells, secrete mucus;

❑ G cells, secrete the hormone gastrin into the blood;

❑ D cells, secrete the hormone somatostatin.
Hydrochloric Acid
The high concentration of HCl makes gastric juice
very acidic,

This strong acidity serves some functions:
1. Activate pepsinogen into pepsin and provide
optimum pH for its action.
2. Killing most ingested bacteria.
3. Help absorption of iron and calcium.
4. Stimulate bile flow and pancreatic secretion.
Hydrochloric Acid Secretion
Regulation of Hcl Acid Secretion
Histamine, gastrin and ACh
are important in
stimulating acid
secretion.
They facilitate the second
messengers which help
the expression of H,K-
ATPase on the cell
surface.
While somatostatin inhibit
acid secretion.
Regulation of Gastric Function
The extrinsic control of gastric function is divided into three
phases:

(1) Cephalic phase;

(2) Gastric phase;

(3) Intestinal phase
(1) The cephalic phase: (30%)
Stimuli: Sight, Smell, Taste,
Chewing.

Pathways: Parasympathetic
nerves to ENS results in
the release of:
✓ ACh from the plexus
neurons,
✓ gastrin from the gastrin-
releasing cells, and
✓ histamine from ECL cells

Response: stimulation of
gastric acid secretion
2) The gastric phase (60%)
Stimuli: gastric distension by
the volume of ingested
material

Pathways:
Vagovagal reflex

Response: stimulation of
gastric acid secretion
(3) The intestinal phase
Stimuli: Acid, distension, hypertonic
solutions, and solutions containing
amino acids, and fatty acids in the
small intestine ( food in small
intestine)

Pathways:
Long and short neural reflexes;
Hormones released by the
intestinal tract: secretin,
cholecystokinine CCK, gastric
inhibitory peptide, vasoactive
intestinal polypeptide, and
somatostatin

Response: inhibition of gastric acid
secretion and motility.
Digestion and Absorption in the GIT
 Digestion and Absorption in the GIT
The major foods can be classified as carbohydrates, fats,
and proteins.
They generally cannot be absorbed in their natural forms.
Therefore, it needs to be digested into small enough
compounds for absorption:

carbohydrates monosacharrides
fats FA + monoglycerides
Proteins A.A.
 Digestion of Carbohydrates
In the mouth: the digestion of starch begins with the
action of salivary amylase.

In the duodenum: by the action of pancreatic amylase
to produce disaccharide maltose (2 molecules of glucose)
and trisaccharide maltriose (3 molecules of glucose) and
oligosaccharides (2 to 10 molecules of glucose).

In the small intestine: the brush border enzymes
hydrolyze maltose, maltriose and oligosaccharides to
their monosaccharides
 Absorption of Carbohydrates
In the small intestine
At intestinal brush border:
At low concentrations is transported through the
mucosal lining into the epithelial cells of the intestine
by secondary active transport, via a sodium
dependant transporter.
At higher concentrations, is transported facilitated
diffusion.
At basolateral border: is transported facilitated
diffusion.
Absorption of Carbohydrates
 Digestion of Protein
In the stomach: protein digestion begins with the action
of pepsin to produce short-chain polypeptides.

In the duodenum and jejunum:
most protein digestion occur by the action of trypsin,
chymotrypsin, elastase, carboxypeptidase (in pancreatic
juice) and aminopeptidase (in intestinal juice).

As a result of the action of these enzymes, polypeptide
chains are digested into free amino acids.
 Absorption of Protein
At intestinal brush border:
Amino acids is absorbed by secondary active transport.
At basolateral border:
is transported facilitated diffusion.
 Digestion of Lipids
In a process called emulsification, bile salt micelles
(spherical shape formed of 20 to 40 bile salts) are
secreted into the duodenum and act to break up the
fat droplets into tiny fat droplets of triglycerides.

Fat digestion occurs at the surface of the droplets
through the enzymatic action of pancreatic lipase,

Free fatty acids and monoglycerides quickly become
associated with micelles of bile salts to form “mixed
micelles” to be absorbed from brush border
membrane.
Digestion of Lipids
 Absorption of Lipids
At intestinal brush
border:
The micelles is absorbed by
simple diffusion.

At basolateral border:
Chylomicrons is
transported exocytosis to
enter the lymph vessels not
blood capillaries.
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