GI-Introd-Motility.pdf

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University of Jordan
Department of Physiology and Biochemistry
Dental students, Academic year 2023/2024.
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Gastrointestinal physiology
Textbook of Medical Physiology, by GUYTON and HALL, Jordan
th
th
Edition: 797-842, 887-897. 13 ed: pp: 797-847, 887-907, 12 Ed: pp:
753-803, 843-863.
Objectives: After studying, the student should be able to:
1. Relate anatomical structures of GI tract to their functions.
2. Relate electrical activity and smooth muscle cells responses to
their functions in the GI tract.
3. describe motor activities along GI tract, and organ variations of
these activities.
4. Describe secretions along GI tract, their function and
mechanisms involved in regulation.
5. Describe digestion and absorptive mechanisms and their
regulation.
6. Describe dietary balance, regulation of food intake and feeding
abnormalities (obesity and starvations) that may accompany
dietary balance disorders.
7. Describe energetics in human body and measurements of Basal
Metabolic Rates (BMR).

Introduction
Four physiological processes are taking place along the
gastrointestinal (GI) tract. These include:
1. Motility.
2. Secretion.
3. Digestion.
4. Absorption.
Related to these processes:
Control systems of GI functions.
- Neural control
- Hormonal control

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- Blood flow to the GI.
Functional structures in the gastrointestinal tract:
Smooth muscle cells:
2 main layers are generally forming Gastro-intestinal tract with
some variations according to organ. These layers are clearly seen in small
intestine:
- Longitudinal layer: outer layer of smooth muscle cells
arranged longitudinally along the digestive tract.
- Circular layer: extend circumferentially around the gut.
Located beneath longitudinal layer.
Each layer is forming a bundle like structure. Cells in each bundle are
connected together by gap junctions with permit these cells to function as
syncytium. Therefore, by this organization, a group of cells is functioning
together to an effective contraction along gastro-intestinal tract.
In addition to these two main layers, a third thin layer of smooth
muscle cells is also described at the junction between the mucosa and
submucosa which is known as Muscularis mucosa. This layer is involved
in the secretion from tubular glands and movements of mucosal folds.
Characteristics of smooth muscle cells:
* Electrical activity of smooth muscle:
Smooth muscle cells are characterized by the presence
of slow waves (undulating changes in membrane potential
known as basic electrical rhythm (BER)) and spike
potentials. The spike potentials are the true action potentials
that appear at the peak of slow waves.
* Ca++ in smooth muscle cells contractions: The role of
calcium in smooth muscle contraction is known. The source
of Ca++ for contraction is either from extracellular fluid or
sarcoplasmic reticulum.
The entry of Ca++ from the interstitial fluid appears
by activation of Ca++ channels. This activation is generated
by spike potentials that occur at the peak of slow waves
which represents the true action potentials at smooth muscle
cells.
The release of Ca++ from sarcoplasmic reticulum
occurs by formation of IP3 that results during signal
transduction mechanisms by activation of phospholipase C

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in response to binding of ligand (hormone or
neurotransmitter) to its receptor.
Ca++ acts via calmodulin to activate myosin filaments
which results in developing of attractive forces between
actin and myosin.
* Chemical control of smooth muscle cells activity:
Smooth muscle cells respond to a wide range of
stimuli caused by neurotransmitter or hormones. This
activity appears by activation of receptors on smooth muscle
cells. These transmitters may induce relaxation or
contraction of smooth muscle cells.
Note:

the response is according to the type of transmitter, type of receptor and the
transduction mechanism involved in receptor activation.

Finally, integration of responses by smooth muscle cells by binding
of ligands to their receptor will result in exhibition of tonic contraction.
Variations in the tonic contractions by increase or decrease in intensity is
seen along gastro-intestinal smooth muscle. In addition to these, also
rhythmic contractions have also been described along gastro-intestinal
tract (known also as phasic or rhythmic contractions). In the later type, a
group of smooth muscle cells are exhibiting a rhythmical contractions and
relaxations as we will see in small intestinal motilities. These contractile
activities are controlled mainly by the electrical rhythm that smooth
muscle cells of the GI tract are displaying.
Summary of control for GI smooth muscle cells activity:
Smooth muscle cells activity is controlled by
Electrical activity of smooth muscle cells: (slow waves and
spike potentials).
Neurochemical control: represented by the response of
smooth muscle cells of the GI to a large number of
transmitters that are released by many types of neurons in
the ENS.
To have an effective activity by smooth muscle cells of the GI
tract, cells are functioning in syncytium (the activity is very well
synchronized by organized contraction and relaxation at the segmental
level which promote an efficient motility of the GI tract). The
synchronization in part is provided by the ENS. In addition to these, the

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cells of Cajal play also an important role in the synchronization of this
activity.
Interstitial Cells of Cajal (ICCs):
Interstitial cells are widely spread all over the gastrointestinal tract.
These cells have certain characteristics. They have large number of
processes. Also, these cells communicate through these processes by gap
junction with other ICCs as well as smooth muscle. In addition, these
cells eliciting by themselves electrical activity as action potentials. All
these have supported the theory of considering these cells as pacemaker
cells of the gastro-intestinal tract.
Characteristics of ICCs:
* ICCs communications:
The ICCs-ICCs and ICCs-smooth muscle cells
communication (by a gap junction) provide the basis for the
synchronization of the electrical activity of smooth muscle cells as
a group and consequently the harmony of contractile responses of
smooth muscle cells. This will result in the functional syncytium
of gastro-intestinal smooth muscle cells.
*ICCs generate slow wave:
ICCs are excitable cells and elicit an electrical activity.
These electrical activities have a sudden and periodical appearance
of an upstroke from a constant resting potential of about –70mV.
The initiation of these activities is believed to be metabolic
dependent.
The appearance of the upstroke is believed to cause the slow
waves in smooth muscle cells that are in junction with ICCs or to
regulate the rhythm of slow waves in smooth muscle cells.

*ICCs also receive inputs from the ENS:
In addition to their communication with smooth muscle
cells, ICCs also receive inputs from the ENS. These inputs may
give these cells an important role in mediating the activity to
smooth muscle cells which promote a regulatory role of smooth
muscle cells activity.

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Secretory cells:
These are represented as solitary cells that line the digestive tube or
grouped in functional structures (known as glands). These cells are
specialized in synthesis and secretion of organic substances that function
as enzymes, hormones, factors or mucus. Some of these structures are
secreting only water and electrolytes (this type is known as serous
secretions). More details about secretory cells, their functions and
regulation will be given with gastro-intestinal secretion.
Enteric nervous system: (ENS)
Beginning from the esophagus and extending along the entire GI
tract, there is a neural network known as Enteric Nervous System.
Neurons in this system are grouped into two main plexuses. One is
located between longitudinal and circular smooth muscle layers known as
myenteric plexus or Auerbach’s plexus. The second plexus lies in
submucosa and known as submucosal or Meissner’s plexus. Neurons
within each plexus are connected by nerve fibers that are projecting
orally, caudally and circumferentially. Some neural fibers connect
neurons from the two plexuses together.
Neurons from myenteric plexus usually control the activity smooth
muscle cells from longitudinal and circular layer, and consequently,
gastrointestinal movements. Submucosal plexus usually controls
gastrointestinal secretion and local blood flow. Some neurons are
considered sensory neurons that transmit signals from gastrointestinal
epithelium to both enteric plexuses, prevertebral ganglia of sympathetic,
spinal cord, and to brain stems through vagus nerve. These fibers are
stimulated by excessive distension of the gut, irritation of the mucosa, or
by specific chemical substances in the lumen.
Enteric neurons that control gastrointestinal functions contain
transmitters that could have inhibitory or excitatory effects on motility,
secretion, or vascular blood flow. Many types of transmitters have been
identified in ENS, such as, Ach, SP (substance P), VIP (vasoactive
intestinal peptide), CGRP (Calcitonin Gene Related Peptide), GRP
(Gastrin Releasing Peptide), and many others.

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Autonomic nervous system..
Parasympathetic nervous system:
According to the location of neural cell bodies, it is divided into:
- Cranial division:
provides innervations through vagus nerve to
esophagus, stomach, pancreas, small intestine and first half
of large intestine.
- Sacral division:
Provides innervations through pelvic nerves to distal
half of the colon, sigmoidal, rectum and anal region. Fibers
in this division have importance in executing defecation
reflex.
Generally, stimulation of parasympathetic system causes an
increase in the activity of enteric nervous system and consequently,
enhances the activity of the gastrointestinal functions. These
include motility, secretion and blood flow.
Sympathetic nervous system:
Sympathetic fibers that innervate gastro-intestinal tract
originate in the spinal cord (segments T5-L2). These fibers pass through
paravertebral ganglia and synapse with the second neuron in celiac,
superior mesenteric or inferior mesenteric ganglia.
Generally, stimulation of sympathetic system causes a
decrease in the activity of enteric nervous system and GI smooth
muscle cells.

Endocrine cells and Hormones in the GI.
Many hormones have been identified at the level of GI tract. Many
of these have their function unidentified yet. These hormones include:
Gastrin:
Cholecystokinin (CCK).
Secretin.
GIP (Gastric Inhibitory Peptide) other name is (Glucosedependent Insulino-tropic Polypeptide).

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Others hormones are also secreted along Gastro-intestinal tract,
including: Glucagon-like peptide-1(GLP-1), Motilin, Ghrelin, Amylin,
Enterostatin, Neuropeptide Y (NPY), Pancreatic polypeptide which is
closely related to polypeptide YY and NPY. In addition, scattered
endocrine cells releasing Somatostatin, Neurotensin, Thyrotropin
releasing hormone (TRH), Adrenocorticotropic hormone (ACTH) have
been described along the GI tract.
Blood Flow and Local activities in the GI:
The blood flow to the gut is very well related to local activities.
After meal the increase in absorption, secretion and motor activities is
accompanied by an increase in blood flow. This increase continues during
the next few hours after meal and return back over the next 2-4 hours.

Regulation of gastro-intestinal blood flow:
Possible factors that cause an increase in blood flow:
- The release of vasodilator substances after mucosal
stimulation caused by meals. Such as, CCK, VIP, Gastrin
and Secretin. These factors are also important in
controlling smooth muscle cells activities.
- some glands release kinins (kallidin and bradykinin)
into the lumen and the gut wall.
- Decreased oxygen concentration  increase blood flow
possibly by the release of adenosine.
Like muscle activity, vascular flow is also under the control of
enteric nervous system. Many transmitters are known to affect the
vascular flow of the gastrointestinal tract, such as SP, VIP, CGRP, and
others. These transmitters are released by neurons of the ENS.
The autonomic nervous system has also effects on the blood flow
to the gut. Sympathetic stimulation causes vasoconstriction, which results
in decreased blood flow, while parasympathetic system causes an
increase in blood flow. Although, parasympathetic system has no direct
effect on vessels, the effect of this system appears to be indirect by
increasing glandular activity, which results in secretion of vasodilator
mediators (such as kinins).

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Gastro-intestinal Motilities
Mixing and movements of food along the GI tract:
Mastication (chewing):
Chewing results in grinding action on food to get smaller particles.
This occurs by activation of chewing reflex (centers in hypothalamus and
cerebral cortex are stimulated by smell and taste to cause chewing of food
in the mouth). The initiation of chewing reflex appears by muscle
stretching caused by drop of the lower jaw (due to the presence of food
bolus in the mouth). This will result in a rebound of the lower jaw by
activation of stretch reflex.
In mouth, in addition to grinding by chewing, mixing is also promoted by
the movements of the tongue.
Deglutition (Swallowing):
Two stages of deglutition:
- Voluntary stage: in which tongue is pressing food by upward
and backward movement against soft palate, which results in
squeezing food bolus into pharynx.
- Involuntary stages: reflexes initiated by introducing food into
pharynx will result in contraction of pharynx and then
esophageal peristalsis that induce movement of bolus along
esophagus. In these reflexes, swallowing receptors at the
pharyngeal mucosa and swallowing centers in the brain are
involved.
The involuntary stage is subdivided into:
- Pharyngeal stage: duration is about 2 sec. In this stage
respiration is interrupted, soft palate is pulled upward to
close posterior nares and larynx is pulled upward and
anteriorly which results in closure of epiglottis. In addition
to these complex events, the upper esophageal sphincter
(pharyngo-esophageal sphincter) is relaxed and esophageal
opening is enlarged. This will end in enforcing bolus to
move into esophagus.

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- Esophageal stage: conduct the bolus along esophagus to the
stomach.
Two types of contraction are taking place by esophageal
muscle:
- Primary peristaltic contractions: continuation of the
contractions initiated in the pharynx which conduct
bolus through the esophagus. The wave of
contractions passes along esophagus in about 8-10
second.
- Secondary peristalsis:
Represented by intrinsic (within myenteric plexus)
and extrinsic (through afferent and efferent vagus
fibers) reflexes promoted by the distension of the
esophagus by the retained food in esophagus or when
the primary reflex fails to move bolus of food along
esophagus.
Note: Pharynx and Upper third of the esophagus is striated muscle and
controlled by glossopharyngeal nerve. The lower third is smooth muscle and
controlled by the vagus nerve as extrinsic control.

Peristaltic wave of the esophagus ends with relaxation of
gastroesophageal sphincter (lower esophageal sphincter) and
receptive relaxation of the stomach. The relaxation is caused by the
activation of the inhibitory neurons from the lower part of the
esophagus. These neurons induce inhibition of the tonic contraction
of the sphincter and the relaxation of the stomach.
Failure of the sphincter to relax may result in a pathological condition
known as achalasia. In which the ability of myenteric plexus to cause
relaxation of the sphincter has failed.
Gastro-esophageal sphincter is equipped also by valve like closure
at the distal opening of the esophagus to prevent reflux of food from the
stomach. The failure of this system may result in esophageal reflux
(Return of gastric content toward esophagus).

The motor activities of the stomach:
- The most important function of the stomach is storage of food.
This organ can dilate from the capacity of 50ml up to 1000ml.
This dilation begins with receptive relaxation and the

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intervention of vago-vagal reflex that decreases the muscular
tone of the stomach upon the presence of food in the stomach.
- Stomach secretes large amount of secretions (2000ml/day). This
secretion when mixed with the ingested food in the stomach is
forming chyme. These secretions are mixed with food due to the
motor activities of the stomach which is known as peristaltic
constrictive waves or mixing waves. These activities appear in the
mid portion of the stomach at frequency of 3/min and move toward
the antrum. The frequency is determined by the frequency of basic
electrical rhythm (BER) of gastric smooth muscle. These
contractions are very intense as they approach the antrum and they
are forming constrictive rings. At the antrum, when the peristaltic
constrictive wave reaches the pylorus, it causes constriction of the
pyloric sphincter which impedes emptying of chyme into the
duodenum. The result of these contractions not only mixes food,
they also grind food and toss the content of the antrum back toward
the body and forth. The process of tossing back the antral content is
known as retropulsion. Very small amount of chyme with fluid
consistency can pass into the duodenum because of the small
opening of the pylorus and the constriction of pyloric sphincter.
For about 20% of time these peristaltic contractions become very
intense and cause an increase in the pressure in the antrum. This
action forces several ml of chyme to pass into the duodenum. The
process that results in passage of chyme into duodenum is known
as gastric emptying. The whole activity that results in gastric
emptying is known as pyloric pump.
Note: Gastric movements result in grinding food particles and mixing them
with secretion.

Pylorus as functional structure:
Pylorus is a small opening between stomach and duodenum
guarded by smooth muscle cells that form the pyloric sphincter. The
muscle cells of this sphincter are in tonic contractions. This structure
gives access only to fluids to pass into duodenum and prevents the
passage of food particles until they are grind and mixed well with
secretions by forming chyme with fluid consistency.
Hunger contractions: This type of intense
contractions in the stomach appears when the stomach is
empty and lasts for several hours. These contractions are

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rhythmical peristaltic contractions with duration of 2-3
minutes for each. It seems that these contractions are in
relation with glucose concentration in the blood (They are
increased by decreasing glucose level in blood).

Neural and hormonal control of gastric emptying:
Stimulation of gastric emptying:
- Filling of the stomach: initiates myenteric reflexes that causes
an increase in the activity of pyloric pump and inhibits the tone
of pyloric sphincter.
- Gastrin: secreted by the antral mucosa. This hormone has mild
stimulatory effect on the peristaltic activities of the stomach,
which result in enhanced pyloric pump.
Inhibition of gastric emptying:
- Entero-gastric reflex: The passage of chyme to the duodenum
causes decrease pH (in duodenum). This initiates intrinsic and
extrinsic reflexes to decrease gastric emptying.
3 levels of inhibition induced by entero-gastric
reflexes:
- Through ENS.
- Through prevertebral ganglia.
- Through signals via the vagus nerve to inhibit the
excitatory signals of vagus nerve to the stomach.
The effects of these reflexes decrease the antral propulsive
contractions and increase the tone of the pyloric sphincter.
- Hormonal feedback from the duodenum:
- CCK cholecystokinin: (secreted by jejunum) the release is
stimulated by fat in chyme.
- GIP: Gastric Inhibitory Peptide: released from upper small
intestinal specialized cells and stimulated by fat and
carbohydrates in chyme.
- Secretin: stimulated by acid in duodenum.

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Intestinal movements:
1. Propulsive Movement: ensures the movement of
chyme analward at an appropriate rate.
2. Mixing Movements: which result in mixing food with
GI secretion.
Propulsive movements
Movements of food along the GI tube are caused by peristaltic
contractions that appear at the GI tract. These contractions are described
as a contractile ring of the circular muscle layer up to the distension and
relaxation down to the distension of segment, which move forward along
the GI tract. Other component of the contraction is rhythmic shortening of
longitudinal layer. The peristalsis can initiated usually by local reflexes
caused by distention of the gut which induce contractile ring 2-3 cm
above the distended part and relaxation of the part of the GI tube down to
the distention which is called receptive relaxation.
These changes that appear in the motor activity of the smooth
muscle cells of the GI describe complex patterns of activities that are
known as peristaltic reflex. After the initiation of this reflex by the
formation of the contractile ring and the distention of the segment down
to stimulated part of the intestine, and shortening and elongation of
longitudinal layer results in chyme movements downward along the GI
(in analward direction). These changes with the peristaltic wave and
including the analward movement of peristalsis are known as the “law of
the gut”.
Although, the main effect of this type of contraction is to propel
chyme in caudal direction, they also have some effects on mixing food
and spreading chyme along the intestine which help in the absorption of
food.
Rhythmic contractions of longitudinal layer are controlled by
electrical activities of smooth muscle cells.
Neural control:
*The role of the ENS:
The complex structures of the enteric nervous system provides a
neural network connection that controls many of the GI functions
including the movements and the rate of chyme movements. The orad (up
direction) extension of the excitatory neurons and the caudad (down
direction) extension of the inhibitory neurons provide a great networking
which play a big role in peristaltic reflex. The congenital absence or the

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decreased activity of the enteric nervous system may depress or weaken
the peristaltic reflexes and decrease the effectiveness of peristalsis to
move the chyme in analward direction.
As a result an effective peristaltic activity to cause a propulsive
movement of chyme requires an intact and active ENS.
The peristaltic contractions can also be initiated by mucosal stimulation
(as in peristaltic rush: rapid and powerful peristaltic contractions).
Other factors can also interfere with the peristaltic activities:
*Parasympathetic nervous system: this system can modulate the
peristaltic activities by changing the activity of neural network or by
changing the activity of smooth muscle cells.
Hormonal control:
Many hormones have shown to affect the gastrointestinal motility
After meals many hormones are secreted during phases of food
processing. For some of these hormones, the effect on intestinal motility
is known. As example:
- Gastrin, CCK, serotonin enhance intestinal motility.
- Secretin and glucagon inhibit intestinal motility.

Mixing movements:
The mixing of food with secretions in the GI tract is provided by
the activity of circular smooth muscle cells. The contractions that appear
along the intestine which are inter-spaced by the relaxation of adjacent
smooth muscle cells up and down to the contracted segment cause spaced
segmentations of the intestine which are known as segmentation
contractions.
The rate of contractile activity is determined by the rate of slow
waves (the electrical activity of smooth muscle cells or BER) in that
segment of the intestine. The maximum frequency of contractions is
about 12/minute in the upper part of intestine (duodenum and jejunum)
and 8/minute in the terminal ileum (the same as the rate of slow waves or Basic
Electrical Rhythm (BER)).
Although these types of contraction have mainly mixing effect on
chyme, they also have some propulsive effects which cause movement in
analward direction.
Other types of contractions in intestine:

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Peristaltic rush: Powerful and rapid peristalses that occur along
small intestine caused by mucosal irritation and/or intestinal distension.
Migrating Motor Complex (MMC):
MMC is other type of motor activity that begins in the stomach in
the inter-digestive periods. The activity begins in the distal part of the
stomach and continues along the entire small intestine. The contractions
that forming MMC appear in 3 phases:
In the first phase: slow waves (as electrical activity) without
contraction are present.
In the second phase: not all slow waves are followed by
contractions (one slow wave is followed by contraction and 1-5 slow
waves are not followed).
In the third phase lasts for 5-15 minutes all slow waves are
followed by contractions.
The function of these contractions is to sweep the intestinal content
in the time between meals.
These movements are controlled by hormonal (Motulin is believed
to be involved) and neural mechanisms.
Movements caused by the activity of muscularis mucosa:
The activity of muscularis mucosa is responsible for the shortening
and elongating mucosal folds. This activity helps more in the absorptive
process by intestinal mucosa.
The contractions caused by muscularis mucosa are also affected by the
activity of enteric nervous system.

Movements of the colon:
Haustration contractions: the appearance is similar with
segmentation contractions of the small intestine. The activity is
represented as rhythmic contraction and relaxation of circular layer of
colonic smooth muscle cells at a length of about 2.5cm. Each contraction
lasts for 30-60 sec. In addition to the activity of circular layer,
longitudinal muscle strips (known as teniae coli) are also involved to
cause haustral appearance in the colon.
The role of these contractions is helping in absorption of water and
electrolytes by spreading the colonic content over the mucosa. In
addition, these contractions have also propulsive effect. Although, they

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have slow effect on the content of cecum and ascending colon, they are
the main responsible in moving fecal materials into the transverse colon.
Propulsive movements (mass contractions): are series of contractions
that appear 1-3 times/day and last each time about 10-30minutes. These
contractions appear mainly in the first hour after breakfast. They are the
main responsible in moving fecal materials from the beginning of
transverse colon to the sigmoid.
Mass contractions are described as constrictive rings that usually
begin at the transverse colon followed by the contraction of about 20cm
or more of the colon distal to the constrictive ring. Each contraction lasts
for 30 sec, then, followed by 2-3 minutes relaxation and then another
contraction wave begins.
Mass contractions are facilitated by gastrocolic and duodenocolic
reflexes. These reflexes are conducted through the autonomic nervous
system.
These contractions can also be initiated by the irritation of the colon.
As example, in ulcerative colitis that results in mucosal irritation, causes
an increase in mass movements of the colon.
The effect of these contractions: feces will be forced to move into the
rectum which may result in the initiation of defecation reflex.

Defecation:
Two types of reflexes are preceding defecation act. These include:
Intrinsic reflexes: in which, distention of the rectum initiates signals
through myenteric plexus (ENS) to cause more contractions in
descendent colon, sigmoid and rectum. This will force feces to move
toward the anus. This reflex is weak and will not cause defecation.
Extrinsic reflexes (parasympathetic defecation reflex): distension
of rectum and sigmoid will result in:
Increased parasympathetic signals which fortify
contractions that appear in the descendent colon, sigmoid and rectum.
Signals to the internal sphincter to cause relaxation.
Note: all these reflexes are involuntary.
After all these reflexes, the defecation in normal people occurs
only as a voluntary act by relaxing external sphincter (which is under
voluntary control) and increasing abdominal pressure by closure of glottis

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and contractions of the abdominal wall which cause the pelvic floor to be
pulled downward on the anal ring and relax to evacuate feces.