Chpt23_Digestive PDF

Summary

This document covers an overview of the digestive system, including the alimentary canal and accessory organs, with details on histology, mucosa, submucosa, muscularis, and innervation of the GI tract. It also discusses blood supply, the peritoneum, and digestive processes like ingestion, mechanical and chemical digestion, propulsion, absorption, and defecation.

Full Transcript

CHAPTER TWENTY-THREE
The Digestive System

23.1 Overview of the Digestive System
A. The digestive system consists of a muscular tube called the alimentary canal or gastrointestinal
tract (GI) tract and a variety of accessory organs.
1. Alimentary tract – the muscular tube, also known as the GI tract, which begins with the
mouth and continues through the oral cavity, pharynx, esophagus, stomach, small
intestine, and large intestine which opens to the exterior through the anus.
2. Accessory organs – organs that include the salivary glands, liver, gallbladder, and
pancreas, situated along the GI tract that produce secretions to assist in digesting and
absorbing nutrients.
3. The digestive system works with other systems to support tissues that have no direct
connection to the outside environment and no other means to obtain nutrients.
B. Histology - the organs of the GI tract have distinctive structural and functional characteristics,
but all share an underlying pattern of histological organization, though variation does exist
within some organs.
1. Mucosa – the innermost lining containing the mucous membrane of epithelial tissue
supported by a basement membrane and thin layer of muscle tissue.
a. Epithelium - varies according to location within the GI tract.
I. (Non-keratinized) stratified squamous epithelium is found in the oral
cavity, pharynx, the upper portions of the esophagus, and rectum.
II. Simple columnar epithelium is found within the lower portions of the
esophagus, the stomach, small intestine, and most of the large intestine.
i. Specialized mucus producing cells types vary too.
ii. Enteroendocrine cells for hormone release vary also.
b. Lamina propria – a basement membrane composed of areolar connective tissue
containg blood vessels, sensory nerve endings, lymphatic system structures, and
mucous glands.
c. Muscularis mucosae – smooth muscle that creates various folds on the epithelial
surface of the GI tract such as rugae, plicae circularis, and villi to increase surface
area.
2. Submucosa – a layer of dense irregular connective tissue that contains large blood
vessels, lymphatic vessels, the submucosal plexus, and in some regions, exocrine glands
that secrete enzymes and buffers into the lumen of the GI tract.
3. Muscularis – essential in the mechanical processing and propulsion of food through the
GI tract, but the muscle tissue type and structure will vary according to location within
the GI tract.

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 a. Predominately composed of two layers of smooth muscle, an inner circular layer
and an outer longitudinal layer, for involuntary control.
b. The mouth, pharynx, anterior esophagus and external anal sphincter are made
up of skeletal muscle for voluntary control of ingestion and defecation.
c. The stomach has a third oblique layer to aid in churning while the colon has the
outer longitudinal layer modified into a band of muscle known as tenia coli.
4. Serosa – the double layer serous membrane covering many of the organs in the
abdominal cavity; those outside have a dense layer of collagen called the adventitia.
C. Innervation.
1. Intrinsic innervation of much of the alimentary canal is provided by the enteric nervous
system, which are grouped into two plexuses.
a. The myenteric plexus (plexus of Auerbach) lies in the muscularis layer of the and
is responsible for motility, especially the rhythm and force of the contractions.
b. The submucosal plexus (plexus of Meissner) lies in the submucosal layer and is
responsible for regulating digestive secretions and reacting to the presence of
food.
2. Extrinsic innervation is also provided by the autonomic nervous system, with the
sympathetic nervous system restricts activity while the parasympathetic system
stimulates it.
D. Blood supply.
1. The arterial supply has two functions.
a. Transport absorbed nutrients to the liver.
b. Supply the organs of the alimentary canal with the nutrients and oxygen needed
to drive their cellular processes.
2. The venous supply transports absorbed nutrients via the hepatic portal vein to the liver
before returning to systemic circulation.
E. The Peritoneum.
1. A double layer serosal membrane that holds abdominal organs in place.
2. In certain areas the serosa pulls away from the surface of the organs to create five
major peritoneal folds.
a. Greater omentum – apron-like structure that lies superficial to the small
intestine and transverse colon; a site of fat deposition in people who are
overweight.
b. Falciform ligament – anchors the liver to the anterior abdominal wall and
inferior border of the diaphragm.
c. Lesser omentum – suspends the stomach from the inferior border of the liver;
provides a pathway for structures connecting to the liver.
d. Mesentery – vertical band of tissue anterior to the lumbar vertebrae and
anchoring all of the small intestine except the initial portion (the duodenum).
e. Mesocolon – attaches two portions of the large intestine (the transverse and
sigmoid colon) to the posterior abdominal wall.
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 3. Some posterior abdominal organs are outside of the peritoneum and thus referred to as
retroperitoneal.

23.2 Digestive System Processes and Regulation
A. Digestive Processes
1. Ingestion – occurs when foods and beverages enter the alimentary canal via the mouth.
2. Mechanical digestion – physical breakdown of food into smaller pieces, increasing
surface area without changing the chemical nature of the food. Examples include
mastication or chewing in the mouth, churning of food into chyme in the stomach, and
segmentation in the small intestine.
3. Propulsion – movement of food through the alimentary canal by swallowing and
peristalsis, alternating waves of contraction and relaxation.
4. Chemical digestion – the chemical and enzymatic breakdown of foods into small organic
molecules that can be absorbed such as carbohydrates, proteins and lipids.
5. Absorption – movement of small organic molecules and other nutrients from the lumen
of the GI tract into the interstitial fluids, blood, or lymph.
6. Defecation – removal of undigested and unabsorbed materials from the body as feces.
B. Regulation
1. A variety of sensors, including mechanoreceptors, chemoreceptors, and osmoreceptors,
help regulate digestive functioning along with the enteric nervous system’s myenteric and
submucosal plexuses discussed in section 23.1.
2. A variety of hormones are involved and are further discussed with their respective organs;
gastrin from the stomach in section 23.4, as well as secretin, cholecystokinin, and gastric
inhibitory peptide from the small intestine in section 23.5.
23.3 The Mouth, Pharynx, and Esophagus (Upper GI tract)
A. Mouth – also known as the oral cavity is lined with non-keratinized stratified squamous.
1. The anterior and lateral borders of the oral cavity
a. Labia – also known as lips, are thin layers of skin that overlay the orbicularis oris
muscle and can be distinguished by their reddish color. A superior and inferior
labial frenulum attaches the lips to the gums.
b. Cheeks – formed by the buccinator muscles.
c. Oral vestibule - area bounded by the lips and cheeks externally and internally by
the gums and teeth.
2. The superior boundary of the oral cavity (or roof)
a. Hard palate - composed of the palatine process of the maxilla and the palatine
bones.
b. Soft palate - composed of skeletal muscle tissue.
3. The posterior boundary of the oral cavity
a. Uvula – the flap of tissue that drops from the soft palate and helps to prevent
food from entering the oropharynx prematurely.
b. Palatine tonsils – lie on either side of the oral cavity in the palatoglossal and
palatopharyngeal arches called the fauces.
B. Tongue – composed of skeletal muscle, covered in stratified squamous epithelia, and anchored
in the oral cavity by the lingual frenulum; it functions to manipulate food into a bolus, helps
form words, and serve as a sensory organ for gustation.
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 1. The superior surface of the tongue is covered in four types of epithelial projections
called papillae.
2. Three of the four, fungiform, foliate, and circumvallate contain taste buds while filiform
papillae provide texture and tactile sensation.
3. Lingual lipase is secreted by lingual glands to aid in triglyceride digestion, but is only
activated upon entry into the stomach.
C. Salivary glands – exocrine glands that produce and secrete saliva, a mixture of water, mucus,
buffers, lysozymes, and enzymes.
1. Functions
a. Moistens and lubricates the mouth and food.
b. Inhibits microbial entry.
c. Dissolves food chemicals for taste receptor cells.
d. Initiates chemical digestion of complex carbohydrates by salivary amylase.
2. The Major Salivary glands
a. Submandibular glands - releases a thicker mixture of both salivary amylase and
mucin via submandibular ducts.
b. Parotid glands – releases a watery solution rich in salivary amylase via parotid
ducts.
c. Sublingual glands – releases the thickest saliva, primarily mucus and a little
salivary amylase via the sublingual ducts.
3. Salivation or the production of saliva is regulated by the autonomic nervous system;
under parasympathetic stimuli it continually flows, but under sympathetic stimuli it’s
reduced.
D. Teeth – or dentes break food into smaller pieces.
1. Types of teeth
a. Your first dentition or set of teeth are the 20 deciduous or baby teeth that start
to erupt through the gums during the first few months of life.
b. Your second dentition are your 32 permanent or adult teeth (32), classified into
4 different types.
I. Incisors – the 8 (4 on top/4 on bottom) at the front of the mouth are for
biting.
II. Cuspids – the 4 (4 on top/4 on bottom) on either side of the incisors with
a pointed cusp to tear and pierce are commonly called canines.
III. Premolars – 8 (4 on top/4 on bottom) on either side of the cuspids with
rounded cusps for mashing and crushing can also be called bicuspids or
as 1st and 2nd premolars.
IV. Molars – 12 (6 on top/6 on bottom) have several pointed cusps for
crushing with the 3rd set referred to as wisdom teeth.
2. Anatomy of a Tooth
a. Composed of highly mineralized, bone-like material called dentin with a pulp
cavity inside and enamel, the hardest material in the body, covering the crown
or exposed surface.
b. Below the gingivae or gums is the root of the tooth, bound in the alveolar
processes of the jaw bones by a hardened substance known as cementum and
attached to a periodontal ligament.
E. Pharynx – more commonly called the throat is composed on skeletal muscle for swallowing and
can be divided into three regions
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 1. Nasopharynx – the superior portion of the pharynx, located between the internal nares
of the nasal cavity and the soft palate, is lined with pseudostratified columnar
epithelium is involved in breathing and speech only; the uvula serves to block it off with
swallowing.
2. Oropharynx – extends between the soft palate to the level of the hyoid bone and is
composed of stratified squamous epithelium to accommodate the movement of food
and protect against abrasion.
3. Laryngopharynx – includes the portion of the pharynx between the hyoid bone and the
entrance to the larynx and esophagus and is lined with stratified squamous epithelium
to accommodate the movement of food; the epiglottis serves to block of the larynx with
swallowing.
F. Esophagus – a hollow muscular tube that runs from the pharynx to the stomach, passing
through the esophageal hiatus in the diaphragm.
1. The upper esophageal sphincter prevents backflow of food into the oral cavity while the
lower esophageal sphincter, also known as the gastroesophageal or even cardiac sphincter,
prevents backflow of stomach contents into the esophagus.
a. The muscularis layer which changes from purely skeletal muscle in the upper
portion, to a mix of skeletal and smooth in the middle, to purely smooth by the
bottom portion uses peristalsis to propel the bolus into the stomach.
b. The mucosa is composed of (non-keratinized) stratified squamous with mucus
secreting goblet cells to further protect against abrasion and aid in swallowing.
2. Failure of the lower esophageal sphincter to close can cause reflux, also known as heartburn
or gastroesophageal reflux disease (GERD).
G. Deglutition – also known as swallowing is a 3-phase process that moves the bolus from the oral
cavity into the pharynx and then into the esophagus
1. Voluntary phase – also known as buccal or oral phase is the voluntary push by the
tongue into the oropharynx once chewing has ceased.
2. Pharyngeal phase – when the uvula moves up to close the nasopharynx while the
epiglottis seals off the larynx, a momentary apnea or cessation of breathing, and the
upper esophageal sphincter relaxes.
3. Esophageal phase – peristaltic contractions propel the bolus toward the stomach,
stimulating the mucus glands in the esophagus and relaxing the lower esophageal
sphincter.
23.4 The Stomach (Lower GI tract)
A. Stomach – a muscular, expandable, J-shaped organ that converts the bolus into chyme.
1. Structurally it can be divided into four distinct regions.
a. Cardia – also known as the cardiac region is the area where the esophagus
empties into the stomach.
Fundus – the dome-shaped portion at the top of the stomach that lies superior
to the cardia.
b. Body – the largest region of the stomach, it functions as a mixing bowl for
ingested food and gastric secretions.
c. Pylorus – the funnel-shape region that has a large pyloric antrum tapering to the
pyloric canal which uses the pyloric sphincter to regulate the flow of chyme out
of the stomach and into the duodenum.

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 2. Rugae or folds in the mucosa allow for distension and stretch by flattening out with
filling.
B. Histology
1. Resembles the majority of the alimentary canal with simple columnar epithelia forming
the mucus cell rich mucosa layer, but it adds a third layer of smooth muscle to the
innermost muscularis layer, known as the oblique layer to aid in churning and mixing
the chyme with enzymes.
2. Gastric pits – shallow depressions that cover the mucosal lining to allow secretions for
the gastric glands to reach the lumen.
3. Gastric glands – composed of four special cell types, primarily located in the fundus and
body, that secrete most of the stomach juices used for gastric digestion.
a. Parietal cells – secrete hydrochloric acid (HCl) for activating the pepsinogen and
creating an inhospitable environment for bacteria as well as intrinsic factor
which is important in the absorption of vitamin B12.
b. Chief cells - secretes the inactive enzyme pepsinogen, which when activated by
HCl, forms pepsin that can then begin the process of protein digestion.
c. Mucus neck cells – distinct from the goblet cells on the mucosal surface, their
role is not currently known.
d. Enteroendocrine cells – produce a variety of regulatory digestive hormones into
the lamina propria.
I. Gastrin – released by G cells, increases stomach motility and churning.
II. Histamine – stimulates release of HCl from parietal cells
III. Somatostatin – inhibits stomach motility and emptying.
IV. Ghrelin – regulates food intake by stimulating hunger and satiety.
C. Gastric Secretion occurs in three phases, controlled by the coordination of both the autonomic
nervous system and hormones.
1. Cephalic phase – occurs before the bolus enters the stomach to prepare it for digestion
and can be initiated by taste, smell, sight and/or even thoughts and mention of food.
a. A conditioned reflex that can be enhanced by a preference or desire for food,
but also inhibited by depression or illness that results in the sensation of a lost
appetite.
b. It also plays a major role in all forms of food advertising.
2. Gastric phase – initiated by the entry of the bolus into the stomach and controlled
locally by gastric hormones and neural response
a. Distension triggers the parasympathetic nervous system to release gastric juices.
b. A raising pH and detection of proteins causes gastrin release that then triggers
HCl release to lower the pH back and enable pepsinogen activation.
c. Decreased pH on the other hand inhibits HCl release and increases mucus
secretion to protect the stomach from mucosal erosion that can lead to ulcers as
well as relaxation of the lower esophageal sphincter that can lead to
heartburn/GERD.
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 3. Intestinal phase – initiated as chyme is delivered into the duodenum and has both an
excitatory and inhibitory reaction
a. Detection of food stimulates intestinal gastrin secretion which stimulates
increased (stomach) gastrin release.
b. Distension from the food closes the pyloric sphincter to maintain small amounts
to enter the duodenum slowly.
D. Mucosal Barrier – protects the stomach from self-digestion by pepsin.
1. A bicarbonate-rich mucus secretion is produced by mucosal surface cells physically
separates the acidic chyme from the epithelial layer.
2. Tight junctions between the epithelial cells protect against chyme leakage into
surrounding tissues.
3. The epithelial cells undergo mitosis about every 3 – 6 days.
E. Digestive Functions
1. Mechanical digestion
a. Mixing waves utilize the third muscularis layer to toss food, with increasing
force, to better mix with the gastric juices and physically break against the
stomach walls.
b. Appropriately sized contents experience a rhythmic push to the pyloric
sphincter, a process known as gastric emptying, that is influenced by the
intestinal phase so that the chyme entering the duodenum is delivered in small
amounts only when the duodenum is ready to process it.
2. Chemical digestion
a. Focuses primarily on pepsin’s breakdown of protein, aided by the mechanical
activities of the stomach.
b. Food may reside in the fundus as it waits for its addition to the mixing action,
allowing salivary amylase activity to continue digesting carbohydrates.
c. Lingual lipase will be activated by the acidic conditions and can begin working on
triglycerides, but without an emulsifier there is minimal progress.
3. Additional roles
a. Minimal absorption by things like alcohol and aspirin does occur.
b. Production and secretion of intrinsic factor, essential for intestinal vitamin B 12
absorption that supports erythropoiesis and neuronal functioning.
23.5. The Small and Large Intestines (lower GI tract)
A. Small Intestine – primary digestive organ of the body that has a specifically modified mucosal
layer to maximize absorption.
1. Structurally it can be divided into three regions.
a. Duodenum is the first region
I. Receives chyme from the pyloric sphincter as well as accessory secretions
from the gallbladder, liver, and pancreas
II. The hepatopancreatic ampulla is where the common bile duct and main
pancreatic duct enter the duodenum through a structure known as the
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 major duodenal papilla, under the control of the heptopancreatic
sphincter, also known as the sphincter of Oddi).
b. Jejunum and ileum are the middle and last region respectively with the former
ending at the ileocecal sphincter (valve) to regulate release into the large
intestine.
c. The autonomic nervous system extrinsically regulate functioning, while the
superior mesenteric artery and vein handle blood supply, and the hepatic portal
vein transports all of the absorbed nutrients to the liver.
2. Histology has the same four basic layers, but the mucosa and submucosa layers have
additional adaptions suited to the primary role played by the small intestine in terms of
digestion and absorption.
a. 3 unique structural adaptations exponentially increase surface area.
I. Circular folds, also known as plicae circularis run the entire length of the
small intestine and involve projections of the submucosa, creating deep
folds in the mucosa.
II. Villi are an additional layer of projections along the circular folds surface,
each of which contains an artery, vein, and lacteal or specialized
lymphatic capillary.
III. Microvilli are finger-like extensions on the apical surface of the epithelial
cells themselves that are so tiny and numerous that they collectively look
like a bristle brush and earn the nickname brush border.
b. Intestinal glands, also called crypts of Lieberkuhn, found in-between the villi and
produce intestinal juice, a slightly alkaline, mucus solution.
c. The submucosa of the duodenum is rich in mucus secreting duodenal glands,
also known as Brunner’s glands, to help buffer against the acidic nature of
chyme.
d. Intestinal MALT is found throughout the lamina propia to prevent bacteria from
entering the blood supply, with large collections known as Peyer’s Patches in the
ileum.
3. Mechanical digestion in the Small Intestine
a. Segmentation moves chyme forward and back as it is propelled forward to
combine it with digestive juices while also pushing it against the mucosal walls at
the contracted segments.
b. Migrating motility complex systematically contracts regions of the small
intestine starting at the duodenum incrementally under the influence of motilin
until the ileum is reached at the process restarts at the duodenum again.
c. The gastroileal reflex utilizes input from stomach motility and gastrin to increase
segmentation and motility in the ileum while also relaxing the ileocecal
sphincter/valve to allow chyme to enter the large intestine.
4. Chemical digestion in the Small Intestine

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 a. Carbohydrates, initiated in the mouth and proteins, initiated in the stomach
complete digestion in the small intestine due to intestinal and pancreatic
secretions.
b. Lipid digestion begins as bile emulsifies the large molecule to enhance pancreatic
lipase activity.
c. Brush border enzymes on the mucosal surface of the lumen enable additional
digestion at the microvilli which distinguishes the absorptive ability of the small
intestine from the stomach.
d. The entire process requires slow, small amounts of chyme delivery to maintain
the osmotic gradient in the lumen as well as regulate the pH to a slightly alkaline
level.
B. Large Intestine – stores and concentrates fecal material by reabsorbing water as well as
absorbing any remaining nutrients and synthesized vitamins before eliminating the residual
contents as feces.
1. Structurally it can be divided into four distinct regions.
a. Cecum – dead-end sac inferior to the ileocecal sphincter/valve that houses many
residential bacteria and has the appendix projecting off medially.
I. The appendix is a collection of lymphatic tissue that secured in place by
the mesoappendix or mesentery of the ileum discussed in 23.1.
II. Considered to be vestigial or no longer serving a purpose, it is may also
be of benefit following intestinal illness as it serves as a reservoir for
residential bacteria that can repopulate the large intestine.
III. Bacterial infection can result in appendicitis or inflammation of the
appendix and almost always requires an appendectomy or surgical
removal of the organ.
b. Colon – subdivided into four regions.
I. From the ileocecal valve it turns superiorly as the ascending colon until
the right colic flexure at the base of the liver where it turns medially to
become the transverse colon until reaching the spleen at the left colic
flexure where it turns inferiorly to become the descending colon.
II. The descending colon turns medially as it enters the pelvic cavity to
become the sigmoid colon that makes a serpentine bend to the midline
where the rectum is located.
c. Rectum – expandable portion of the large intestine for temporary storage of
feces and has distal folds known as rectal valves that allow the release of gas
while retaining the feces.
d. Anal canal – opens to the outside of the body and regulated by an internal anal
sphincter of smooth muscle and an external anal sphincter of skeletal muscle.
2. Histology sees distinct variation from the small intestine to support its focus on water
absorption and fecal excretion.

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 a. Mucosal layer of simple columnar enterocytes, except for the stratified
squamous cells in the anus, that are specialized for absorption of water, salt, and
bacterially synthesized vitamins rather than enzyme secretion.
b. Numerous goblet cells secrete mucus to aid in fecal propulsion and protection
from acidic conditions created by the residential bacteria.
c. No circular folds or villi though the longitudinal muscle of colon’s muscularis
layer is modified as a three-banded strip of muscle known as the teniae coli that
pulls the colon into repeating pouches known as haustra to allow expansion and
elongation.
I. Hanging from the teniae coli are fat filled pouches of the peritoneum,
known as epiploic appendages.
II. Not to be confused with polyps or that are intestinal pouches bulging
inside the colon or diverticula that are intestinal pouches bulging outside
the colon.
3. Bacterial Flora are the normal intestinal bacteria that reside in the large intestine.
a. Most are nonpathogenic and serve either mutualistic and aid in processing of
nutrients or synthesis of vitamins or commensal and cause no harm so long as
they don’t migrate out.
b. Nonresidential bacteria obtained with ingestion is usually destroyed by multiple
physical barriers throughout the GI tract including lysozymes, defensins, acidic
conditions, and protein digesting enzymes.
I. Notable bacterial products include vitamin K synthesis which is necessary
for blood clotting.
II. Dendritic cells can penetrate the large intestines tight junctions, triggered
by bacterial cell walls, to sample the flagged bacteria and present them
to residential T-cells for assessment and trigger an IgA mediated response
if necessary.
4. Digestive Functions
a. Digestion of the nutrients is no longer necessary and so the focus is on
movement of the fecal matter.
I. Damage or disease may result in the need to temporarily or permanently
remove some or all of the large intestine, a procedure known as a
colectomy.
II. The remaining region can be sutured to the anus or else it can be brought
through the abdominal wall; a procedure known as a colostomy and have
the feces collect in a colostomy bag.
b. Mechanical digestion combines three types of movement.
I. Haustral contractions – slow moving process stimulated by the presence
of material in the colon to propel feces from one haustra to the next,
aided by the teniae coli, mixing the food residue and helping to absorb
water.
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 II. Peristalsis
III. Mass movement – push feces through the transverse colon, compacting
it in the rectum.
IV. Gastrocolic reflex – is stimulated by distension of the stomach and
digestion in the small intestine to increase motility, which is further aided
by fiber that traps water to keep feces softer and adds bulk for stronger
colonic contractions.
c. Chemical digestion
I. Solely the work of the bacterial flora as only mucus is secreted.
II. Bacteria due break down some remaining carbohydrates, known as
saccharolytic fermentation which produces multiple types of flatus or
gas, that when produced excessively can lead to flatulence.
5. Absorption, Feces Formation, and Defecation
a. The small intestine absorbs about 90% of the water secreted in the digestive
process with the large intestine responsible for the last 10%.
b. Undigested and unabsorbed semisolid material is known as feces and can
include sloughed off cells and bacteria.
c. Defecation begins with mass movements pressing feces into the rectum so that
it distends and relaxes the internal anal sphincter.
I. The brain voluntarily controls activity of the external anal sphincter to
defecate or not.
II. Valsalva’s maneuver occurs when you voluntarily contract your
diaphragm and abdominal muscles to assist the elimination process.
III. Delaying defecation leads to increased water absorption and further
compaction of the feces that can make it more difficult to pass,
potentially leading to constipation.
IV. Alternatively, feces that moves too quickly through the large intestines
has excess amounts of water that make the feces more watery, known as
diarrhea and can lead to dehydration.
23.6 Accessory Organs of the Digestive Tract
A. The Liver - largest internal organ in the body is a major metabolic organ, but is digestively
responsible for the production of bile, an important emulsifier.
1. Structure
a. Consists of a left lobe and a larger right lobe, divided by the falciform ligament
which is a remnant of the umbilical cord, and secured to the stomach by the
lessor omentum, both discussed in 23.1.
b. Some consider the right lobe to also be delineated inferiorly into the quadrate
and caudate lobe.
c. Hepatic circulation includes a hepatic artery and vein for delivering oxygen and
removing wastes and stored nutrients, but also a hepatic portal vein that brings
all absorbed nutrients as well as drugs and toxins to the liver for processing.
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 2. Histology
a. Hepatocytes or liver cells synthesize bile, process molecules delivered by the
hepatic portal vein.
I. Arranged as hepatic lobules, a hexagonal shape surrounding a central
vein that drains all secretions and products from the cells.
II. Hepatic sinusoids, fenestrated capillaries from the hepatic artery and
hepatic portal vein, running between the cells give easy access to the
delivered molecules.
III. Portal triads consisting of a bile duct, hepatic artery, and hepatic portal
vein are situated at the corners of each lobule.
b. Reticuloendothelial cells or Kupffer cells are fixed macrophages that remove
debris such as dead blood cells, liver cells, and bacteria.
3. Bile – enables emulsification or disruption of the lipid molecules in chyme as it enters
the small intestine.
a. A slightly alkaline mixture of water, bile sales, bile pigments, and phospholipids.
I. Bile salts are actually reclaimed by the enterohepatic circulation system
in the ileum by the hepatic portal vein to be recycled.
II. One of the main pigments is bilirubin, a waste product of red blood cell
breakdown by the spleen that give bile its greenish-yellow color.
III. The amphipathic phospholipids interact with the lipid molecules as well
as the water molecules in chyme to break large molecules up and
increase surface area for lipases to work.
b. Collected into bile canaliculi between hepatocytes, the eventually converge into
left and right hepatic ducts from their respective lobes to leave the liver together
as the common hepatic duct.
I. The common hepatic duct will merge with the cystic duct from the
gallbladder to form the common bile duct that enters the duodenum.
II. Bile production never stops and follows a similar path to access the
gallbladder for storage, however, under secretin signaling from the
duodenum, production will increase.
B. The Pancreas – organ with both exocrine and endocrine function tucked into the duodenum.
1. Clusters of acini cells surround pancreatic ducts that collect enzyme-rich pancreatic
juice into the main pancreatic duct and smaller accessory duct (duct of Santorini) for
convergence with the common bile duct.
2. Small collections of endocrine cells form the islets of Langerhans and produce the
hormones pancreatic polypeptide, insulin, glucagon, and somatostatin.
3. Pancreatic Juice
a. Mostly water, digestive enzymes, and bicarbonate.
b. Buffers acidic chyme and inactivates pepsin so that pancreatic enzymes can
begin digesting fats, as well as continue digestion of carbohydrates and proteins.

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 c. Protein digesting enzymes are released in an inactive form that utilize a
cascading activation that starts with enteropeptidase to protect the pancreas,
whereas the other enzymes are secreted as is.
4. Pancreatic secretion is under the control of hormones and the parasympathetic nervous
system.
a. Duodenal entry of acidic chyme stimulates secretin release to trigger
bicarbonate release.
b. Presence of fats and proteins stimulate CCK release to trigger pancreatic enzyme
release and enhance secretin.
c. Vagal nerve signaling via the parasympathetic nervous system also triggers
pancreatic secretion.
C. The Gallbladder – stores and concentrates bile for release into the duodenum.
1. Divided into three regions, the wide fundus, the medial body, and the narrowed neck.
2. CCK controls the release into the cystic duct that can flow into the common hepatic
duct.
23.7 Chemical Digestion and Absorption: A Closer Look
A. Chemical Digestion – is the breakdown of large food molecules into small enough units to be
absorbed by the intestinal villi without destroying their chemical makeup (table 23.8).
1. Carbohydrate digestion
a. Should be 40 – 60% of your caloric intake.
b. Starts in the mouth with salivary amylase, is halted in the stomach, and restarts
to finish in the small intestine with pancreatic amylase for large polysaccharides.
c. Brush border enzymes like sucrase, maltase, and lactase in the mucosal cells of
the small intestine finish off small disaccharides and monosaccharides.
2. Protein digestion
a. Should be 15 – 20% of your caloric intake.
b. Starts in the stomach with pepsin and finishes in the small intestines with
chymotrypsin and trypsin for large proteins and polypeptides.
c. Brush border enzymes in the mucosal cells of the small intestine finish off amino
acids and dipeptides with amino peptidase and dipeptidase respectively.
3. Lipid digestion
a. Should be about 35% of your caloric intake
b. Essentially only occurs in the stomach due to the presence of pancreatic lipase
that splits triglycerides into fatty acids and glycerol.
c. Lingual and gastric lipase are secreted in their respective organs, but without the
assistance of bile the functionality is limited.
4. Nucleic Acid digestion
a. Present in all foods.
b. Pancreatic nucleases deoxyribonuclease and ribonuclease breakdown DNA and
RNA respectively, in the small intestine

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 c. Brush border mucosal cells also secrete nucleosidase and phosphatase to
further digest nucleotides.
B. Absorption – the movement of molecules from the GI tract into the intestinal mucosal cells for
transport into the capillary blood or lacteals in the villi (table 23.10)
1. May use active transport, passive diffusion, facilitated diffusion, co-transport, or
endocytosis.
2. Water-soluble nutrients will be transported directly into the blood for transport to the
liver via the hepatic portal vein.
a. All carbohydrates are absorbed as monosaccharides except for the undigestible
polysaccharides commonly referred to as fiber which will be excreted as feces.
b. Proteins are mostly absorbed as amino acids, those that are absorbed as
dipeptides and tripeptides are quickly broken down into amino acids in the
mucosal cells.
c. All components of a nucleotide are absorbed.
d. All minerals, whether from food or GI secretions are absorbed regardless of need
except for iron and calcium which depends on individual physiology.
I. Since iron is toxic in large amounts to cells, it must be bound to proteins
for storage as well as transport
II. Calcium self-regulates is absorption, in conjunction with parathyroid
hormone and vitamin D.
e. All of the B vitamins as well as vitamin C are water-soluble and absorbed, with
unnecessary amounts secreted for release in urine.
f. Most of the water is reabsorbed, with the majority occurring in the small
intestine though the speed at which the GI tract processes all of the digestive
processed can cause that to vary.
3. Lipid-soluble nutrients will be packaged as chylomicrons before moving into the lacteals
for transport by lymphatic vessels into venous circulation.
a. Bile’s presence speeds up absorption while also
I. Small fatty acids can actually follow the route of monosaccharides and
proteins.
II. Larger fatty acids and monoglycerides are initially incased in a micelle or
water-soluble pouch for absorption into the mucosal cells.
III. Once inside they are reassembled into triglycerides for packaging into a
chylomicron whose large size permits them into the lacteals only.
IV. Once in the blood supply, lipoprotein lipase will slowly breakdown
triglycerides within the chylomicrons into free fatty acids that can enter
the cells.
b. Vitamins A, D, E, and K are all lipid-soluble and can only be absorbed with dietary
lipids that they are packaged into the micelles with.
C. Disorders of the Digestive System
1. Mouth related
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 a. Loss of appetite – may be due to diminished receptivity of taste buds.
b. Dental caries – also known as cavities are due to erosion in the enamel, often
resulting from the action of residential bacteria in the mouth; dental plaques are
usually the first sign but can be minimized with regular brushing and flossing.
c. Gingivitis – inflammation of the gums usually caused by plaque buildup that left
untreated can cause erosion and separation of the gums from the teeth and lead
to periodontal disease where the root becomes damaged and eventual tooth
loss can occur.
2. Digestive organs
a. Peritonitis – inflammation of the peritoneum usually coinciding with any other
disorder that causes GI contents, bacteria, and/or blood to fill the peritoneum.
b. Acid reflux – failure of the lower esophageal sphincter to prevent the backflow
of chyme into the esophagus; also called heart burn or gastroesophageal reflux
disorder (GERD) if it is s a chronic condition.
c. Hernia – occurs when an abdominal organ protrudes through the abdominal
wall; hiatal hernias specifically refer to protrusion through the esophageal hiatus.
d. Ulcers – deterioration in the wall of digestive organs, typically caused by
Helicobacter pylori infection.
e. Lactose intolerance – insufficient levels of lactase enzyme necessary to digest
lactose lead to digestion in the large intestine by bacteria that results in
increased gas production and bloating and cramping as a result.
f. Appendicitis – inflammation of the appendix as a result of a blockage trapping
infectious bacteria within the lumen.
g. Colorectal cancer – often resulting from mucosal growths known as polyps;
regular colonoscopies, recommended over the age of 50 are best preventative
measure to identify and remove.
h. Hemorrhoids – varicose veins of the rectum and anus
i. Diverticulitis – inflamed herniation in the wall of the large intestines.
j. Constipation – hard and difficult to pass stool typically due to slow movement
through the digestive tract or not enough fiber.
3. Accessory organs
a. Mumps – swollen parotid glands as a result of a virus (myxovirus) that cause
swelling of the neck and jaw; generally rare due to vaccine efforts
b. Pancreatitis – inflammation of the pancreas from either drugs, toxins, bacterial
or viral infections, or blockages.
c. Hepatitis – inflammation of the liver as a result of alcohol consumption, viral
infection (hepatitis A, B, and C are most common), or drugs.
d. Cirrhosis – chronic inflammation of the liver leading to scarring of the liver.
e. Gallstones – concentrated collections of cholesterol and bile salts.
f. Jaundice – accumulation of bilirubin (yellow) in the skin as a result of a blockage
or liver disease.

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