Gastrointestinal Motility Notes PDF

Summary

These lecture notes cover gastrointestinal motility, discussing the organization of smooth muscle in the alimentary canal, the role of slow waves, chewing, swallowing, gastric motility, small and large intestinal motility, and the process of vomiting. The document includes learning objectives and an outline of the topics.

Full Transcript

Gastrointestinal Motility: Dr. Komnenov Page 1 of 16

Gastrointestinal Motility

Learning Objectives:

1. Review the organization of smooth muscle in the alimentary canal.
2. Describe the role of slow waves in the alimentary canal.
a. Describe the mechanism of slow wave production.
b. Describe the frequency of slow waves.
3. Describe the processes of chewing, swallowing and esophageal peristalsis.
4. Describe the process of gastric motility.
a. Distinguish between the two functional divisions of the stomach.
b. Describe the two types of motor activity in the proximal, orad region of the stomach.
c. Describe the two types of motor activity in the distal, caudad region of the stomach.
d. Describe the process of gastric emptying.
5. Describe the process of small intestinal motility.
a. Describe the nature and function of segmentation contractions.
b. Describe the nature and function of peristaltic contractions.
c. Describe the gastroileal reflex.
6. Describe the process of large intestinal motility.
a. Describe the nature and function of contractions that occur in the cecum and proximal
colon.
b. Describe the nature and function of contractions that occur in the distal colon.
c. Describe the nature and function of contractions that occur in the rectum and anal canal
and relate them to the process of defecation.
d. Describe the gastrocolic reflex.
e. Describe the following disorders of large intestinal motility: irritable bowel syndrome
and Hirschsprung’s disease.
7. Describe the process of vomiting.
Gastrointestinal Motility: Dr. Komnenov Page 2 of 16

Outline:

(1) Smooth muscle in the alimentary canal – A review
(2) Slow waves
(a) Mechanism of slow wave production
(b) Frequency of slow waves
(3) Chewing, swallowing and esophageal peristalsis
(a) Chewing
(b) Swallowing
(c) Esophageal motility
(4) Gastric motility
(a) Orad region
(b) Caudad region
(c) Gastric emptying
(5) Small intestinal motility
(a) Segmentation contractions
(b) Peristaltic contractions
(c) Gastroileal reflex
(6) Large intestinal motility
(a) Cecum and proximal colon
(b) Distal colon
(c) Rectum, anal canal, and defecation
(d) Gastrocolic reflex
(e) Disorders of large intestinal motility
(7) Vomiting
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Gastrointtestinal M
Motility
(1) Cell
C types fou
und in the GI tract

(aa) Epitheliall cells- Invollved in secreetion and abssorption in ddifferent partts of the GI ttract

(b
b) Muscularis mucosa-co ontractile prroperties cauuse a change in the surfacce area for
secretion and absorptiion

(cc) Circular muscle-
m resp
ponsible for
decrease in
i the diameeter of the
lumen of the GI tract

(d
d) Longitudiinal muscle-responsible
for shorteening of a secction of the
GI tract

(ee) Submucosal plexus (M Meissner
plexus) an
nd myentericc plexus -
together comprise
c thee enteric Fig. 1 - Structuree of the GI trract
nervous system
s of thee GI tract.
Major role in integrattion and
coordination of the motility,
m secreetory and en docrine funcctions of the GI tract.

Clinical
C signnificance: AAchalasia. C Characterizedd by
impairedd peristalsis in the distall two-thirds oof the esophhagus
and failu
ure of the low
wer esophaggeal sphincteer to relax duuring
swallow
wing.

Clinical
C sign
nificance: G GERD. Occuurs when low wer
esophag
geal sphincteer loses its toone and fails to prevent
movemeent of acid coontent into tthe lower esoophagus.
Fig. 2- Essophageal sttricture (A)
showing obstruction
o of
o food boluss Clinical
C sign
nificance: Paralytic Ileu us. Paralysiis of
with correesponding barium the intestine, which iis a commonn side effect of certain tyypes
swallow (B)
( of surgerries.

Contractioons of the GI
G muscle con motility. Conntractile tissuue of the GI tract
nstitute GI m
is almost exclusively unitary smo ooth musclee, except forr the pharynxx, upper one-
he esophaguss, and extern
third of th nal anal sphiincter, all of which are sttriated musscle.

GI smooth h muscle cellls are conneected via gapp junctions, aallowing com
mmunicationn
among theem through ion channelss. This enablles a large nunumber of cells to be
activated simultaneou
usly, contracting as a sinngle unit.
Gastrointestinal Motility: Dr. Komnenov Page 4 of 16

Depolarization of circular muscle leads to contraction of a ring of smooth muscle
and a decrease in diameter of that segment of the GI tract.

Depolarization of longitudinal muscle leads to contraction in the longitudinal
direction and a decrease in length as well as increase in diameter of that segment
of the GI tract.

(2) Slow waves

Occur spontaneously and are inherent to the smooth muscle cells of some parts of the
GI tract

Originate in the interstitial cells of Cajal, which serve as the pacemaker for GI
smooth muscle

They are not action potentials, although they determine the pattern of action
potentials and thus the pattern of contraction

(a) Mechanism of slow wave production

Consists of cyclic opening of Ca2+ channels (depolarization) followed by opening
of K+ channels (repolarization)

Depolarization during each slow wave brings the membrane potential of smooth
muscle cells closer to threshold and, therefore, increases the probability that
action potentials will occur

Action potentials, produced on top of the background of slow waves, then initiate
phasic contractions of the smooth muscle cells (Fig. 3)

Fig. 3- GI slow waves superimposed by action potentials. Action potentials
produce subsequent contraction.
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(b
b) Frequency
y of slow waaves

Variess along the GI
G tract, but are constantt and charactteristic for each part of tthe
GI traact

Is nott influenced by neural orr hormonal innput. Ratherr, the frequenncy of the acction
potenttials that occcur on top off the slow waaves is modiified by neurral and horm
monal
influences

Sets th
he maximum m frequency of contractioons for eachh part of the G
GI tract.
Frequuency is loweest in the sto
omach (3 slow
w waves/miin) and higheest in the
duodeenum (12 sloow waves/miin)

(3) Chewing,
C swaallowing and
d esophageal peristalsis

(aa) Chewing-- lubricates food
f to faciliitate
swallowin
ng and to beg gin the digesstive
process

(b
b) Swallowin ng
Swallowing is inittiated volunttarily in
the mo outh, but theereafter it is under
involuuntary or refflex control
The reeflex portion n is controlleed by the
swalloowing centerr, which is lo ocated in
the medulla
m
Senso ory informatiion (e.g., foo od in the
mouth h) is detected d by somatossensory
recepttors located near
n the phaarynx. Fig. 4- Struucture of the upper GI trract
This sensory,
s or afferent,
a info
ormation
is carrried to the medullary
m swwallowing cennter via the vvagus and gllossopharynngeal
nervess. The medu ulla coordinaates the sensoory informattion and direects the motoor, or
efferent, output to o the striated
d muscle of thhe pharynx aand upper essophagus
Three phases are involved
i in swallowing:
s oral, pharyyngeal, and esophageall.
The oral phase is voluntary,
v and the pharyyngeal and eesophageal pphases are
controolled by refleexes.

o Oral phase. The
T oral phasse is initiatedd when the ttongue forcees a bolus off food
baack toward th
he pharynx, which contaains a high ddensity of som matosensoryy
receptors. Acttivation of th
hese receptorrs then initiaates the involuntary
sw
wallowing reeflex in the medulla.
m
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o Phharyngeal phase.
p The purpose
p of thhe pharyngeaal phase is too propel the ffood
bo
olus from thee mouth thro ough the phaarynx to the eesophagus inn the followiing
steeps:
(1) The soft paalate is pulleed upward, ccreating a naarrow passagge for food too
move into the pharynx x so that foodd cannot refl flux into the nasopharynxx.
(2) The epigloottis moves to cover the oopening to thhe larynx, annd the larynxx
moves upw ward againstt the epiglotttis to prevennt food from entering thee
trachea.
(3) The upper esophageal sphincter reelaxes, allow wing food to ppass from thhe
pharynx to
o the esophag gus.
(4) A peristalttic wave of contraction
c iss initiated inn the pharynxx and propells
food throu
ugh the open n sphincter. B Breathing is inhibited duuring the
pharyngeaal phase of sw wallowing.

Fig. 5-
5 Pressure in
i esophaguss during swaallowing

o Essophageal phase.
p The esophageal phhase of swalllowing is coontrolled in ppart
byy the swallow wing reflex and
a in part bby the entericc nervous syystem. In thee
esophageal ph hase, food is propelled thhrough the essophagus to the stomachh.
On nce the bolu us has passed d through thee upper esopphageal sphinncter in the
phharyngeal ph hase, the swaallowing refllex closes thhe sphincter sso that food
caannot reflux into the pharrynx. A prim mary peristalltic wave, alsso coordinatted
byy the swallow wing reflex, travels downn the esophaagus (see disscussion of
peeristalsis), prropelling thee food along.. If the primaary peristaltiic wave doess not
cleear the esoph hagus of foo od, a secondaary peristaltiic wave is innitiated by thhe
co
ontinued disttention of thee esophagus. The seconddary wave, w which is
mediated by th he enteric neervous systemm, begins att the site of ddistention annd
traavels downw ward.
Gastrointestinal Motility: Dr. Komnenov Page 7 of 16

(c) Esophageal motility

The esophagus propels the swallowed food into the stomach.

Sphincters are located at either end (upper esophageal sphincter and lower
esophageal sphincter), preventing air from entering the upper esophagus and
gastric acid from entering the lower esophagus, respectively.

Since the esophagus is located in the thorax, intraesophageal pressure equals
thoracic pressure, which is lower than the atmospheric pressure. Therefore, a
balloon catheter placed in the esophagus can be used to measure intrathoracic
pressure.

This is particularly pertinent for cases of hiatal hernia, where the lower
esophageal sphincter slides into the thoracic cavity. Because it is surrounded by
negative pressures, it becomes subject to regurgitation.

Sequence of events as food moves into and down the esophagus:

1. The upper esophageal sphincter opens, mediated by the swallowing reflex,
allowing the bolus to move from the pharynx to the esophagus. Once the bolus
enters the esophagus, the upper esophageal sphincter closes, which prevents
reflux into the pharynx.

2. A primary peristaltic contraction, also mediated by the swallowing reflex,
involves a series of coordinated sequential contractions (Fig.5). As each
segment of esophagus contracts, it creates an area of high pressure just behind
the bolus, pushing it down the esophagus. Each sequential contraction pushes
the bolus further along. If the person is sitting or standing, this action is
accelerated by gravity.

3. As the peristaltic wave and the food bolus approach the lower esophageal
sphincter, the sphincter opens. Opening of the lower esophageal sphincter is
mediated by peptidergic fibers in the vagus nerve that release VIP as their
neurotransmitter. VIP produces relaxation in the smooth muscle of the lower
esophageal sphincter. At the same time that the lower esophageal sphincter
relaxes, the orad region of the stomach also relaxes, a phenomenon
called receptive relaxation. Receptive relaxation decreases pressure in the
orad stomach and facilitates movement of the bolus into the stomach. As soon
as the bolus enters the orad stomach, the lower esophageal sphincter contracts,
returning to its high resting tone. At this resting tone, the pressure at the
sphincter is higher than the pressure in the esophagus or in the orad stomach.
 Gastroin
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4. If the primary peristaltic contraction
c ddoes not cleaar the esophaagus of foodd,
a secondary
s peristaltic
p co
ontraction, mediated byy the enteric nervous sysstem,
cleears the esop
phagus of anny remainingg food. The ssecondary peeristaltic
co
ontraction beegins at the point
p of disteention and trravels downwward.

5. Ass the food bo
olus approacches the loweer end of thee esophagus,, the lower
esophageal sp phincter relaxes. This reelaxation is vagally meddiated, and thhe
neeurotransmittter is VIP an
nd/or nitric ooxide (NO).

6. Thhe orad regiion of the sttomach relaxxes (“recepttive relaxatiion”) to allow
the food boluss to enter thee stomach.

Lower esoophageal sph
hincter (LES in Fig. 6) - has a high toone for two
reasons:

1. Myogeenic mechan nisms (intrinssic ability off musculaturre of the
sphinccter to resist distension)

2. Excitattory vagal to
one
Lower esophag geal sphincteer relaxes byy 2 mechanissms:
Reduction in n excitatory vagal tone
Activation of o inhibitoryy enteric (myyenteric plexxus) nervous
system

Fig. 6- Exccitatory and inhibitory pa
athways to open
o and cloose lower esoophageal sphhincter, resppectively
(LES-lowerr esophageal sphincter; ENS-entericc nervous sysstem)
Gastroin
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Cliniical significa
ance: Achallasia. Characcterized by iimpaired perristalsis in thhe distal two-
thirdss of the esop
phagus and failure
fa of the lower esophhageal sphinncter to relaxx during
swalllowing. Wheen lower esophageal sph hincter is commpletely dennervated (succh as occurs in
advannced achalassia), it remaiins contracteed due to its m
myogenic prroperty.

Cliniical significaance: GERD D. Occurs when
w lower essophageal spphincter losees its tone annd
fails to
t prevent movement
m off acid conten
nt into the low
wer esophaggus. Can be a consequennce of
hiatall hernia. Alsso diagnosed
d radiographiically.

(4) Gastric
G motiliity

The stomaach has threee
layers of smooth
s muscle:
1. Longiitudinal
2. Circullar
3. Obliqu ue layer

The stomaach has threee
anatomic divisions:
1. Funduus
2. Body
3. Antru
um

The stomaach has two
functional divisions: Figg. 7- Schemaatic drawingg showing thrree major diivisions of
thee stomach: fuundus, body and antrum
1. The proximal, ora ad
regionn of the stom
mach includees the funduss and the prooximal bodyy. This regionn
contaiins oxyntic (fundic
( or gaastric) glandss and is respponsible for rreceiving thee
ingestted meal.

2. The distal,
d caudad d region of the stomachh includes the antrum andd the distal bbody.
This region
r is resp
ponsible for the contracttions that miix food and ppropel it intoo the
duodeenum.

(aa) Orad region

The prroximal, ora
ad region has two types oof motor acttivity
1. Reelaxation
2. Toonic contracttions but no slow wave activity

(1) Relax
xation
Reeceptive relaxation refeers to the oraad stomach bbeing able too accommoddate
larrge increases in volume with only smmall increasees in intra-gaastric pressuure.
Gastrointestinal Motility: Dr. Komnenov Page 10 of 16

Receptive relaxation is a vagovagal reflex that is initiated by distension of the
stomach and is abolished by vagotomy.

CCK also participates in receptive relaxation by increasing the distensibility
of the orad stomach.

The neurotransmitter involved in the vagal path is non-cholinergic and non-
adrenergic, and NO and VIP have been implicated.

(2) Adaptive relaxation

Mechanoreceptors in stomach are stimulated as stomach fills with food.

This elicits another vagovagal reflex.

The release of CCK also activates a vagovagal reflex.

Contractile activity of the proximal stomach also consists of low amplitude
tonic contractions which “gently” propel chyme toward the distal stomach.

Slow waves do not mediate low amplitude tonic contractions.

(b) Caudad region

The distal, caudad region has two types of motor activity:
1. Peristaltic Contractions
2. Migrating motor complex AND slow wave activity

(1) Peristaltic contractions for mixing and digestion

The caudad region of the stomach contracts to mix the food with gastric
secretions and begins the process of digestion.

Slow waves in the caudad stomach occur at a frequency of 3-5 waves/min.

They depolarize the smooth muscle cells.

If threshold is reached during the slow waves, action potentials are fired,
followed by contraction.

Thus, the frequency of slow waves sets the maximal frequency of contraction.

A wave of contraction closes the distal antrum.
Gastrointestinal Motility: Dr. Komnenov Page 11 of 16

Thus, as the caudad stomach contracts, food is propelled back into the
stomach to be mixed (retropulsion).

Gastric contractions are increased by vagal stimulation and decreased by
sympathetic stimulation.

(2) The migrating motor complex

In fasting humans, a different pattern of antral contractions occurs.

Migrating motor complex is a wave of intense propulsive motor activity that
sweeps the length of the gut, from stomach to ileo-cecal junction, at about 90-
minute intervals during the inter-digestive (fasting) phase of GI activity.

It serves a housekeeping function by sweeping the stomach and intestine clean
of residual contents and returning to the colon bacteria that may have migrated
across the ileo-cecal junction.

Likely mediated by the candidate hormone motilin.

(c) Gastric emptying

The physical state of the gastric contents is a major determinant of the rate at
which the stomach empties.

Controlled by negative-feedback mechanisms (neural and hormonal).

Liquids empty faster than solids and their rate of emptying is related to the
volume ingested.

Solids empty more slowly and must first be reduced to small particle size by the
retropulsive mechanism in the distal stomach.

The rate of emptying also depends on the chemical composition of the gastric
contents.

The rate of gastric emptying is fastest when the stomach contents are isotonic.

If the stomach contents are hypertonic or hypotonic, gastric emptying is slowed.

Fat inhibits gastric emptying (i.e., increases gastric emptying time) by stimulating
the release of CCK.

H+ in the duodenum inhibits gastric emptying via direct neural reflexes as well as
via secretin. H+ receptors in the duodenum relay information to the gastric smooth
muscle via interneurons in the GI plexuses.
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(5) Small intestin
nal motility
The smalll intestine fu unctions in th
he digestion and absorpttion of nutrieents. Mixes
nutrients with
w digestiv ve enzymes, exposes thee digested nuutrients to thhe absorptivee
mucosa, anda then prop pels any nonn-absorbed mmaterial to thhe large intestine.

Slow wav
ves set the baasic electricaal rhythm, w
which occurs at a frequenncy of 12
waves/min. Action pootentials occu ur on top off the slow waaves and leadd to contracttions.

Parasympathetic stimmulation increases intesstinal smooth
th muscle contraction;
sympatheetic stimulation decreasses it.

a) Segmenta
(a ation contracctions (Fig. 8 A)

Mix th
he intestinal contents

Consiist of a sectioon of the small
intestiine contractiing, sending the
intestiinal contentss (chyme) in
n both
orad and
a caudad directions.
d This
section of small inntestine then
n
relaxees, and the coontents move
back into
i the segm
ment.

This back-and-for
b rth movemennt
produ
uced by segm mentation
contraactions causees mixing
withouut any net fo
orward
movem ment of chym me.

(b
b) Peristalticc contraction
ns (Fig. 8 B))
Fig. 8- Comparisonn of segmenttation contraaction
Highly y coordinateed, main (A) to tthe peristaltiic contractioon (B)
functiion to propell chyme
througgh the small intestine tow
ward the largge intestine. Ideally, peristalsis occuurs
after digestion
d andd absorption
n have taken place.

Contractions behind the boluss and, simulttaneously, reelaxation in ffront of the bbolus
cause the chyme to
t be propellled caudally..
Gastrointestinal Motility: Dr. Komnenov Page 13 of 16

The peristaltic reflex is coordinated by the enteric nervous system:

(i) Food in the intestinal lumen is sensed by enterochromaffin cells, which
release serotonin (5-hydroxytriptamine (5-HT)).

(ii) 5-HT binds to receptors on intrinsic primary afferent neurons (IPANs), which
initiate the peristaltic reflex.

(iii) Behind the food bolus, excitatory transmitters cause contraction of circular
muscle and inhibitory transmitters cause relaxation of longitudinal muscle. In
front of the bolus, inhibitory transmitters cause relaxation of circular muscle
and excitatory transmitters cause contraction of longitudinal muscle.

(c) Gastroileal reflex

Mediated by extrinsic autonomic nervous system and possibly gastrin

The presence of food in the stomach triggers increased peristalsis in the ileum and
relaxation of the ileocecal sphincter. As a result, the intestinal contents are
delivered to the large intestine.

(6) Large intestinal motility

The large intestine absorbs water and
electrolytes from the chyme and stores fecal
matter until it is expelled.

The colonic movements are slow and
sluggish, but segmentation and propulsive
movements are nevertheless evident.
Haustra, or sac-like segments, appear after
contractions of the large intestine (Fig. 9).

(a) Cecum and proximal colon
When the proximal colon is distended
with fecal material, the ileocecal sphincter
contracts to prevent reflux into the ileum.
Fig. 9- Structure of colon
2 types of contractions occur in the colon:

1) Segmentation contractions in the proximal colon mix the contents and are
responsible for the appearance of haustra.
Gastrointestinal Motility: Dr. Komnenov Page 14 of 16

2) Mass movements occur 1 to 3 times/day and cause the colonic contents to
move distally for long distances (i.e. from the transverse colon to the sigmoid
colon).

(b) Distal colon

Since most of the colonic water absorption occurs in the proximal colon, fecal
material in the distal colon becomes semisolid and moves slowly. Mass
movements propel it into the rectum.

Fig. 10 - Microscopic view of the colon

(c) Rectum, anal canal, and defecation

(i) As the fecal material populates the rectum, it contracts and the internal anal
sphincter relaxes (rectosphincteric reflex).

(ii) Once the rectum is filled about 25% of its capacity, there is an urge to defecate.
However, defecation is prevented because the external anal sphincter is tonically
contracted.

(iii) When it is convenient to defecate, the external anal sphincter is relaxed
voluntarily. Contraction of the smooth muscle in the rectum forces the feces out
of the body.

The defecation reflex can be augmented by contraction of the abdominal
muscles to force fecal contents from the sigmoid colon into the rectum
Gastrointestinal Motility: Dr. Komnenov Page 15 of 16

Intra-abdominal pressure is increased by expiring against a closed glottis
(Valsalva maneuver)

(d) Gastrocolic reflex

The presence of food in the stomach increases the motility of the colon and
increases the frequency of mass movements.

The gastrocolic reflex has a rapid parasympathetic component that is initiated
when the stomach is stretched by the food.

A slower, hormonal component is mediated by CCK and gastrin.

(e) Disorders of large intestinal motility

Extrinsic ANS has a strong influence on large intestinal motility. Irritable bowel
syndrome (IBS) may occur during periods of stress and may result in
constipation (increased segmentation contractions) or diarrhea (decreased
segmentation contractions).

Hirschprung diseases (as discussed earlier).

(7) Vomiting

Vomiting is a reflex controlled by a center in the medulla that receives afferent input
from the:

1. GI tract
2. The labyrinth receptors of the inner ear
3. Gag receptors in the throat
4. Pain receptors

It also receives afferents from a medullary chemoreceptor trigger zone that responds
to certain circulating chemicals, such as apomorphine

The most common stimulus for vomiting is irritation of the upper GI tract, but it can
also be induced by motion sickness, olfactory, visual, and painful stimuli.

The act of vomiting is usually preceded by the sensation of nausea.

Initially there is a diffuse sympathetic discharge with tachycardia, tachypnea,
sweating, and inhibited gastric motility.
Gastrointestinal Motility: Dr. Komnenov Page 16 of 16

This is followed by parasympathetic activation with relaxation of upper and lower
esophageal sphincters (although not always simultaneously), increased salivation, and
a transient increase in gastric motility.

Parasympathetic stimulation also causes reverse peristalsis.

A deep inspiration that follows moves the stomach and diaphragm down into the
abdomen.

The anterior abdominal muscles then contract forcefully, compressing the flaccid
stomach (along with reverse peristalsis) and expelling the gastric contents into the
esophagus.

If the upper esophageal sphincter is not relaxed, secondary peristalsis returns the
contents to the stomach. This phase of the process is termed retching and may be
repeated many times.

If the upper esophageal sphincter is relaxed, the act of vomiting is completed with the
expulsion of the gastric contents through the mouth.

The consequences of vomiting relate to the composition of gastric juice, which is
characteristically acidic, high in chloride, and relatively high in potassium. The
major effects of vomiting are dehydration (due to volume loss), hypokalemia (due to
potassium loss), and hypochloremic metabolic alkalosis due to loss of hydrogen ion
and chloride.