Week 7 Gastrointestinal Physiology P1 PDF

Summary

These are notes for a week 7 gastrointestinal physiology class at Geisinger Commonwealth School of Medicine. It details the learning objectives, topics covered, and relevant readings.

Full Transcript

Gastrointestinal
Physiology_P1
May-17-2021

Copyright
Notice

• All materials found on Geisinger
Commonwealth School of Medicine’s course
and project sites may be subjecttocopyright
protection,and mayberestricted from further
dissemination, retention orcopying.
• Disclosure
• I have no financial relationship with a commercial
entity producing health-care related products
and/orservices.

• Class material and recording will be
posted every Monday by 9.00 AM.

House Keeping

• Office hours are Tuesdays 8-9 PM. I
will be meeting you individually by
appointment to answer any questions
you may have
• I will be holding live case study
sessions on Tuesdays and Thursdays 78 PM. Attendance is not mandatory,
but highly recommended. These
sessions will be recorded.

Learning Objectives
1. Describe the structure of the GI wall; relate each layer to GI functions
2. Contrast the functional roles of sympathetic, parasympathetic, and the
enteric nervous systems in regulating gut motility and peristalsis
3. Describe the storage, digestion, and motility roles of the stomach.
4. Distinguish proteins secreted into the gastric lumen by chief cells,
parietal cells, and mucous cells. Contrast the functions and regulation
of these secretions.
5. Explain factors that stimulate/inhibit hydrochloric acid secretion;
relate to the causes of peptic ulcer including Helicobacter pylori and
aspirin
6. Identify the major components secreted by the exocrine pancreas and
the principal cell types involved in this secretion.

Readings for this session:

1. Text Book; Chapter 8 (Pages; 339 - 366)
2. Class notes

Gastrointestinal System
• Integrated function of GI system:
▪ Coordinated movement of the food
through the GI tract; mastication,
swallowing, peristalsis, segmentation,
contraction, and relaxation of
sphincters.

▪ Secretion of enzymes, mucus,
electrolytes and acid to aid digestion
▪ Absorption of water, ions, vitamins
and nutrients

▪ Elimination of waste products

• Integrated regulation by local,
nervous, and hormonal systems.
• GI system starts at the mouth → esophagus → stomach → small intestine
(duodenum, jejunum, and ilium) → large intestine → anus. It also includes
salivary glands, pancreas, liver and gall bladder that serve excretory
functions.

Cross-Section of Gastrointestinal Tract
The “functional” cross‐section of the wall –
ideal structure for:
1. Absorption of nutrients from lumen to blood
supply
2. Secretion of gut hormones, HCL and
enzymes for digestion

3. Conduit (ducts) for enzymes from the
exocrine salivary glands, pancreas and liver
4. Movement of ingested food through the GI
system;
• Circular smooth muscle contraction
decreases the diameter of the GI segment
• Longitudinal muscle contraction decreases
the length of the GI segment
• Together they are responsible for the characteristic motility;
peristalsis and segmentation
5. Master integrator - the enteric nervous system‐ receives sensory
inputs from the gut & effector inputs from the SNS and PNS

Longitudinal Section of Gastrointestinal Tract
• Serosa is continuous with the mesenteries
and consists of an enveloping layer of
connective tissue that is covered with
squamous epithelial cells.
• Muscularis includes two layers of smooth
muscles;
• The inner layer is circular,
• The outer layer is longitudinal,
• Enteric neurons are present between
these two muscle layers
• Submucosa consists of loose connective
tissue and larger blood vessels. Contains;
• Submucosal Glands
• Submucosal (Meissner’s) nerve plexus
• Mucosa consists of the epithelial layer, as well as an underlying layer of loose connective
tissue known as the lamina propria; contains capillaries, enteric neurons, and immune cells
(e.g., mast cells), as well as a thin layer of smooth muscle known as the lamina muscularis
mucosae (the muscle layer of the mucosa).

Gastrointestinal Tract Mucosa

• The surface area of the epithelial layer is amplified by several mechanisms;
▪
▪
▪

Most cells have microvilli on their apical surfaces,
The layer of epithelial cells is evaginated to form villi and crypts (or glands),
The mucosa is organized into large folds.

• The epithelial cells serve absorptive and excretory functions, the shape and
type of secretions differ according to the site of cells in the GI tract.

Gastrointestinal Muscles
• All of GI tract has smooth muscles, except;
▪

Pharynx

▪

Upper 1/3 of esophagus

▪

External anal sphincter

• GI smooth muscles are of the visceral “unitary”
type; where gap junctions ensure smooth and
coordinated contraction
• In comparison with skeletal muscle:
Energy

Low (up to 300x less)

Force

High

Shortening

High

Time

Long (tonic)

Speed

Slow

• Many ways of stimulation; self excitatory, activated
by stretch, hormones, local tissue factors
• Nicotine, alcohol and caffeine can affect GI smooth
muscle

Membrane Potential in Intestinal Smooth Muscle

Slow Waves:
• Rhythmic changes in membrane potential initiated by interstitial cells of Cajal (pacemaker cells).
• Specific frequency in each segment;
3/ min in stomach, 12/ min in small intestine, 8/ min in ilium, 11/ min in colon, 17/ min in rectum
• → this determines the maximal possible frequency of contraction
Spike Potentials:
• Develop on top of slow waves when they reach threshold potential (~ -40 mV).
• The higher the amplitude → the more spike potentials → the stronger the gut motility.
At rest, sphincters maintain a positive pressure that is higher than the pressures in the adjacent organs;
preventing both anterograde (forward) and retrograde (backward) flow.

Enteric Nervous System (intrinsic): Think locally, act locally
• Sensory information from GI system is
received, integrated and responded to by ENS
independently
• Short reflexes that regulates GI:
▪

Secretion

▪

Motility (peristalsis, mixing contractions)

▪

Local inhibitory effects

▪

Growth

• Myenteric plexus and Submucosal plexus are
located in the gut wall and receive sensory
signals from the gut lumen or the CNS
• Although the enteric nervous system can
function independently of extrinsic nerves,
stimulation by the parasympathetic (PNS) and
sympathetic (SNS) systems can greatly
enhance or inhibit gastrointestinal functions

Black Fibers - myenteric and submucosal plexuses.
Red Fibers - extrinsic Control – SNS and PNS
Green Fibers - afferent sensory fibers pass from
luminal epithelium to the enteric plexuses:
• Irritation of gut mucosa
• Excessive gut distension
• Presence of peptides, H+

Extrinsic Nervous System: Parasympathetic, Sympathetic
Parasympathetic:
• Vagus N: upper GI
through ascending
colon (including
striated muscle of
esophagus)
• Both afferent and
efferent limbs are
contained in the
Vagus nerve, and
are called vagovagal
reflexes

Sympathetic:
• Preganglionic fibers
synapse outside GI tract.
• Four sympathetic
ganglia
▪

Celiac

▪

Superior and inferior
mesenteric

▪

hypogastric

• Post-ganglionic neurons
are adrenergic (NE)

• Pelvic N: Lower GI (colon and anal striated ms) • Adrenergic fibers may synapse with enteric
plexuses or directly with smooth muscles,
• Preganglionic fibers synapse in the walls of GI
within the myenteric and submucosal plexuses. and mucosa (secretory and endocrine cells)
• Post-ganglionic neurons are either cholinergic • NE causes relaxation of smooth muscles,
contraction of sphincters and ↑ salivary
(Ach), or peptidergic (VIP)
secretion.
• Information from PNS are coordinated in the
enteric plexuses and relayed to smooth ms,
endocrine and secretory cells.

Reflex Control of the GI Tract

Gastrointestinal Regulatory Substances
Endocrine (Hormones):
• Cells of the GI mucosa that are not concentrated in glands
but are single cells or groups of cells dispersed over large
areas, they pass through the portal circulation to the
systemic circulation
• Travel long way to act locally;
▪ Gastrin – causes acid secretion

▪ Gastric Inhibitory Peptide (GIP) “aka glucose-dependent
insulinotropic peptide” → release insulin from ß cells of
the Pancreas
▪ Cholecystokinin (CCK)
▪ Secretin

Paracrines:
• Act locally within the same tissue;
▪ Somatostatin – secreted by D cells of GI mucosa (in response to low PH) → inhibits H+ secretion
▪ Histamine (not a peptide) → stimulates H+ secretion

Neurocrines:
• Synthesized in neurons of the GI tract and released following stimulation
• Released by either PNS (Ach and GRP), SNS (NE) or enteric plexuses (VIP, NO, & Enkephalins “opiates”)

Gastric Motility
Gastric motility aims at mixing and fragmenting food
and mixing it with digestive enzymes, to be digested
and absorbed. Two types of movements:
Peristalsis:
• Food bolus distends the gut wall, triggering a reflex
contraction proximal to the food, and relaxation
distal to the food; moving the food in the caudal
direction
Mixing of food:
• Circular and longitudinal muscles alternate
contraction and relaxation causing segmentation
and pendular movements.
• Mixing of food ensures:
▪ Chyme and digestive enzymes maintain uniform
composition and texture
▪ Nutrients are in contact with epithelial cells for
proper absorption

Food Journey
• Digestive System has four
processes:
1. Ingestion and Swallowing:
2. Digestion and Secretion: is the
chemical and mechanical
breakdown of foods into
smaller units that can be taken
across the intestinal epithelium
into the body
3. Absorption:
4. Motility and Defecation:
• To maintain homeostasis, the
volume of fluid entering the GI
tract by intake or secretion must
equal the volume leaving the
lumen by absorption or excretion

Chewing and Swallowing

• Mastication, or chewing, mixes food with salivary mucus to lubricate it and facilitate swallowing,
reduces the size of food parts, and mixes carbohydrates with salivary amylase to begin their digestion.

• Swallowing has three phases:
A. Oral Phase (voluntary): tongue positions food against hard palate. Entrance of the food initiates a
swallowing reflex.
B. Pharyngeal Phase (involuntary):
1.
2.
3.
4.

Soft palate retract to close the nasopharynx
Vocal cords are pulled together and the larynx is moved forward and upward against the epiglottis
Upper Esophageal Sphincter (UES) relaxes to receive food bolus
Superior constrictor muscles of the pharynx contract to force the bolus into the pharynx and through UES

C. Esophageal Phase: is partly controlled by the swallowing reflex and partly by the enteric nervous
system. Once food bolus passes UES, the reflex closes the sphincter to prevent reflux, and a primary
peristaltic wave begins.

Saliva
• Three main groups of salivary glands:
₋ Parotids: produce water or serous saliva rich in
enzymes
₋ Submandibular: serous and mucus elements
₋ Sublingual: produce mucus saliva
In addition to Small Buccal Glands: antibacterial
function

• Salivary glands have unique high blood flow, that
further increases with salivary glands stimulation
• Saliva is composed of:
₋ Mucin, and water; moisturizes and lubricates
the mouth and food, and aids tasting function and swallowing and speaking functions.
₋ Electrolytes help maintain calcium phosphate matrix of teeth (critical pH that favors tooth
destruction is 5.5 and below)
₋ Thiocyanates, lysozymes; wash away bacteria and enzymatic bacterial attacks

₋ IgA antibodies; destroys bacteria (defensive system)
₋ α-amylase; early digestion of carbohydrates
₋ Lingual lipase; early digestion of fat
₋ Kallikrein; an enzyme that produces bradykinin (vasodilator) → causes vasodilation with salivary gl
stimulation

Formation and Regulation of Saliva
• Acinar cells produce isotonic “plasma-like” saliva
• Ductal cells modulate the initial secretion through

₋ Absorption of Na+ and Cl₋ Secretion of K+ and HCO3₋ Ductal cells are impermeable to water
The resulting fluid is hypotonic (net absorption of solute)

• At highest flow rate (4 mL/ min), saliva composition most closely
resembles plasma and the initial saliva produced by the acinar
cells.
Regulation:
• Salivary secretion is exclusively under neural control by the
autonomic nervous system.
• Salivary acinar cells and ductal cells have both parasympathetic
and sympathetic innervation, both stimulating saliva
production (parasympathetic control is dominant).
• Stimulation of salivary cells results in increased saliva
production, increased HCO3-, increased enzyme secretions, and
contraction of myoepithelial cells to release saliva.

Esophageal Motility
• Primary peristalsis mediated by the swallowing reflex

• If primary peristalsis does not clear the esophagus of
food, a secondary peristaltic contraction, mediated
by the enteric nervous system, is initiated (activated
by mechanoreceptors)
• Relaxation of Lower Esophageal Sphincter is mediated
by Vagus nerve (VIP) and enteric nervous system
• Simultaneously, orad stomach relaxes to receive the
food bolus (receptive relaxation)

• As soon as the bolus enters the orad stomach, the
lower esophageal sphincter contracts, returning to its
high-resting tone (preventing food from returning to
esophagus)

Disorders of Esophagus
Achalasia is a motility disorder which is caused by spasm or
failure to relax the lower esophageal sphincter (LOS) . This
results in impaired flow of ingested food into the stomach
and subsequent stasis of food and secretions in the
esophagus. Results from the degeneration of the myenteric
neurons that coordinate esophageal peristalsis and LES
relaxation.
Causes: Idiopathic, infection, syndromic

Symptoms: dysphagia, regurgitation of undigested food, respiratory symptoms
(nocturnal cough, recurrent aspiration, and pneumonia), chest pain, and weight loss

Treatment – Block smooth muscle activation (L‐type Ca2+ channel blockers), Botulinum
toxin (blocks Ach release from nerve terminals) is directly injected into the LES through
a sclerotherapy needle; endoscopic –dilatation with air‐filled balloons

Disorders of Esophagus
Chronic gastric reflux (GERD) is the recurrent acid reflux into
the esophagus.
Causes: obesity/ overweight, iatrogenic (asthma, Ca2+
channel blockers), pregnancy or Hiatal hernia

Symptoms: the most significant and frequent symptom is
heartburn. May also include nausea, bad breath, decay and
difficulty swallowing.
Complications: caused by the long-term inflammation of the esophagus; esophageal
stricture, Barrett’s esophagus “cells lining the esophagus can change into cells similar to
the lining of the intestine” which may develop into cancer.
Treatment – Antacids, proton-pump inhibitors, surgical corrections, life-style
modifications (smoking, healthy diet, weight loss).

Gastric Motility
1. Fill: LES and orad stomach relax (receptive
relaxation), a Vagovagal event;
mechanoreceptors detect distention →
Vagal sensory afferent to CNS → Vagal
efferent → post-synaptic neurons release
VIP → relaxation
2. Churn: Gastric slow waves (3-5 per min),
starting in the middle of the body causing
strong peristaltic contractions to mix food.
Food is not propelled as pylorus is closed.
• Ach, gastrin → ↑ AP frequency and force of contraction
• NE, secretin, GIP → ↓ AP frequency and force of contraction

3. Gastric Emptying: (~ 3 hrs) closely regulated to allow time for neutralization of gastric H+ in
duodenum, digestion and absorption of nutrients.
• Liquids empty more rapidly than solids. Retropulsion in the stomach continues until solid food
particles are reduced to 1 mm3 or less.
• Two major factors slow gastric emptying (i.e., increase gastric emptying time): (1) the presence of
fat and (2) the presence of H+ ions in the duodenum.

Gastric Secretions
•

Mucous Cells: secrete mucin
and HCO3- to protect gastric
mucosal lining from acid or
irritants

•

Parietal Cells: Secrete;
• HCl (H+): denatures proteins
and activates pepsinogen to
pepsin
• Intrinsic Factor (IF): binds
vitamin B12 to be absorbed in
the terminal ilium

•

Chief Cells: Secrete pepsinogen
• H+ activates it to Pepsin → digests proteins → Peptide fragments (oligopeptides) & amino acids i.e.
Protein digestion starts in stomach. Pepsin also destroys bacteria or viruses in the food.

•

G Cells (endocrine cells): secrete Gastrin; gastric mucosa stretch by food/ proteins → activates G
cells → Gastrin secretion into the blood

HCl Secretion

Cellular Mechanism:
1. CO2 + H2O → H2CO3 (carbonic anhydrase) easily dissociates into H+ and HCO32. At apical membrane, H+ is secreted into the lumen of the stomach via H+ - K+
ATPase. Cl- diffuses through Cl- channels.
3. At Basolateral membrane, HCO3- is absorbed in blood by the Cl- - HCO3- exchanger
(responsible for alkaline tide)
Net secretion of HCl and net absorption of HCO3-

Regulation of HCl Secretion
Rate of H+ secretion is regulated by either
action of a single agent, or through interaction
of more than one agent (potentiation). This
interaction could be in the form of:
• Distinct receptors/ second messenger
• One stimulus (e.g. Ach) stimulates the
release of another (e.g. histamine)

Regulation during a single meal:
• Vagus nerve action is facilitated through both
Ach and Gastrin Releasing Peptide (GRP)
• Alcohol and Caffeine → ↑ HCl secretion
• NSAIDs block prostaglandin synthesis;
• ↑ HCl secretion
• ↓ mucus

Peptic Ulcer
Gastric (peptic) ulcer is erosion of the mucosal barrier
by H+ and pepsin;
• Most common: H Pylori
• Excess stress
• NSAIDs
• Rarely: Zollinger-Ellison Syndrome

Zollinger-Ellison Syndrome
• Gastrinoma (Gastrin-releasing tumor)
• ↑↑ Gastrin → ↑↑ HCl production and increased
parietal cell mass
Normally, Gastrin secretion by G cells is inhibited by ↑ H+, but
the tumor secretes Gastrin autonomously

• Ulcer may also be found in the duodenum as the excess H+ production exceeds buffering capacity,
inactivates pancreatic lipase and may result in steatorrhea
• Treatment:
• Cimetidine
• Omeprazole
• Surgical removal of the tumor

Helicobacter Pylori

•

bacteria

•
•

Gram negative H. Pylori colonize antrum. H. Pylori produce urease which
converts urea to CO2 and NH3.
Ammonia neutralizes gastric acid and generates favorable environment to grow.
H. Pylori then binds to gastric epithelium and damage them.

•

Local immune system fights infection → leaving further damage → overtime, mucus secreting epithelia diminish

•

Diagnosis: through symptoms (sharp stomach pain, bloating, burping,
not feeling hungry, nausea and vomiting, dark blood in stool) and:
•
•
•

•

Blood Tests: detection of anti-H. Pylori antibodies
Blood in stool test
Breath Tests: detecting 13CO2 in breath using 13C-urea

Treatment:
• Symptomatic: reduce acid effect on damaged mucosa
• Curative: antibiotic therapy specific to the organism

Delayed Gastric Emptying
• Causes:
• Idiopathic
• Surgical (iatrogenic)
• Neuropathy: 20-30% of diabetic patients develop
delayed gastric emptying, mainly due to autonomic
neuropathy
• Symptoms:
• Pain
• Belching
• Vomiting
• Bloating
• Treatment:
• Drugs; antiemetics, prokinetics
• Pyloric injection of botulinum toxin
• Pyloroplasty
• Gastric electrical stimulation

Increased Gastric Emptying (Dumping Syndrome)
Fluid and gastric content shift fast to small intestine, especially when ingesting high
osmolarity of simple carbs in the duodenum (after both table sugar or fruit sugar)
• Causes:
• Bariatric Surgery
• Gastric Surgery for peptic ulcers

• Symptoms: ~ 30 minutes after food intake;
• Abdominal cramping
• Diarrhea
• Flushing and sweating
• Dizziness and lightheadedness
• Tachycardia
• Nausea
• Treatment:
• Dietary changes after surgery (eating smaller meals and limiting high-sugar foods)
• Drinking fluids only between meals
• If these dietary modifications fail to solve the problem, medications may be needed

Vomiting Reflex (1)
Vomiting is the oral expulsion of gastric (and sometimes duodenal) contents. Vomiting is usually a
serious of events;
(1) Nausea is typically associated with decreased gastric motility and increased tone in the small
intestine, with reverse peristalsis in the proximal small intestine.
(2) Retching ("dry heaves") refers to spasmodic respiratory movements conducted with a closed glottis.
Gastric contents are forced into the esophagus but not the pharynx (as UES is closed). When retch is
over, gastric contents may return to the stomach because LES is open.
(3) Emesis is when gastric and often small intestinal contents are propelled up to and out of the mouth.
• Causes:
Vomiting is sometimes a protective reflex,
and in many cases is caused by diseases
outside GI tract
• Somatic
• Psychogenic (odors, fear)
• A Vomiting Center in the Medulla coordinates
the Vomiting Reflex

Vomiting Reflex (2)
• Afferent:
• The back of the throat
• GI tract, through SNS and PNS; sending information about the GI tract status, e.g. GI distention (a
strong stimulus) or mucosal irritation. It also includes information from the heart (ischemia) or bile
duct (stone)
• Chemoreceptor trigger zone lying under the floor of the fourth ventricle (in brainstem). chemical
abnormalities in the body (e.g. emetic drugs, uremia, hypoxia and diabetic ketoacidosis) are sensed by
these centers, which then send excitatory signs to the vomiting center. Many of the antiemetic drugs
act at the level of the chemoreceptor trigger zone.
• Extramedullary centers in the brain could also sense certain psychic stimuli (odors, fear), vestibular
disturbances (motion sickness) and cerebral trauma and could result in vomiting.
• Efferent:
• Reverse peristalsis that begins in the small intestine
• Relaxation of the stomach and pylorus
• Forced inspiration and contractions of abdominal muscles to increase abdominal pressure
• Movement of the larynx upward and forward and relaxation of LES
• Closure of the glottis (to prevent chyme from entering airways)
• Forceful expulsion of gastric contents
• Simple vomiting is usually self-limited and causes no problems

Vomiting Reflex (3)
• Excessive vomiting:
• Aspiration pneumonia
• Dehydration
• Hypovolemia
• Electrolyte imbalance “Hypokalemia”
• Disturbance of acid-bas balance’ Loss of H+ and Cl → hypochloremic metabolic alkalosis
• Projectile vomiting:
• More sever than usual vomiting
• Not preceded by nausea
• Forceful
• Travels few feet away from the body
• May lead to dehydration if not properly treated