HAP Chapter 23(2) copy1 PDF

Summary

This document is a chapter on the digestive system from the twelfth edition of Marieb's Human Anatomy & Physiology textbook. It provides an overview of the digestive system, including its major processes and the structure of the gastrointestinal tract. The chapter also explains the importance of the peritoneum in digestive function.

Full Transcript

Marieb Human Anatomy & Physiology
Twelfth Edition

Chapter 23
The Digestive System

PowerPoint® Lecture Slides
prepared by Justin A. Moore,
American River College

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Function of Digestive System
A healthy digestive system is essential to life
– Converts foods into raw materials that build and fuel
our body’s cells
– Ingests (takes in) food and digests it (breaks it down)
into nutrient molecules that can be absorbed into
bloodstream
▪ Indigestible residues excreted

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Part 1: Overview of the Digestive
System
Two main groups of organs:
– Organs forming alimentary canal, also called gastrointestinal (GI) tract or gut
▪ Continuous muscular tube running from mouth to anus ( 30 ft in cadaver,
shorter in living body)
▪ Digests food into small fragments and absorbs them through mucosal
lining into blood
▪ Organs: mouth, pharynx, esophagus, stomach, small and large intestine,
anus
– Accessory digestive organs
▪ Teeth, tongue, gallbladder
▪ Salivary glands, liver, pancreas
– Use ducts to secrete digestive fluids into G I tract

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23.1 What Major Processes Occur
During Digestive System Activity?
Processing of food involves six essential activities:
– Ingestion: eating
– Propulsion: movement of food through the alimentary canal, includes:
▪ Swallowing: initiated voluntarily
▪ Peristalsis: primary means of propulsion, involves alternating (involuntary)
waves of contraction and relaxation
– Mechanical breakdown (formerly mechanical digestion): increases surface area
of nutrients, prepares food for chemical digestion by enzymes; includes:
▪ Chewing, mixing food with saliva (via tongue), churning food in stomach, and
segmentation (local contractions of S I that mix food with digestive fluids)
– Digestion (formerly chemical digestion): catabolism via enzymes, breaking down
large food molecules into absorbable chemical building blocks
– Absorption: passage of nutrients from lumen of GI tract through mucosal
epithelium into blood or lymph
– Defecation: elimination of indigestible substances in the form of feces

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23.2 The GI Tract Has Four Layers
and Is Usually Surrounded by
Peritoneum

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Relationship of the Digestive Organs to
the Peritoneum
Peritoneum: serous membranes of abdominopelvic cavity that consist of:
– Visceral peritoneum: covers external surface of most digestive organs
– Parietal peritoneum: lines body wall; continuous with visceral layer

Peritoneal cavity: (slit-like) space between two membranes containing serous fluid,
which lubricates mobile organs as they change shape and move against each other
Mesentery: double layer of peritoneum (layers fused back-to-back), extends from body
wall to digestive organ (holding it in place)
– Stores fat; provides route for blood vessels, lymphatics, nerves to reach organ
– Most are dorsal (attach to posterior body wall), some have names (e.g., omenta)

Intraperitoneal (peritoneal) organs: surrounded by peritoneum; anchored to body wall
by mesentery
Retroperitoneal organs: lie posterior to peritoneum; include:
– Most of pancreas and duodenum (of small intestine), and parts of large intestine

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The Peritoneum
and the Peritoneal
Cavity

Figure 23.4 The peritoneum and mesenteries.
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Clinical—Homeostatic Imbalance 23.1
Peritonitis (inflammation of peritoneum) usually caused by
ruptured appendix
– Also be caused by:
▪ Piercing abdominal wound
▪ Perforating ulcer
▪ Poor sterile technique during surgery
– Peritoneal coverings tend to stick together, helps
localize infection
– Dangerous and lethal if it becomes widespread
– Treatment: infectious debris removal and megadoses of
antibiotics
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Histology of the Alimentary Canal
Walls of alimentary canal have the same four basic layers, or tunics:
– Mucosa, submucosa, muscularis externa, and serosa
Mucosa (mucous membrane)
– Innermost layer, in contact with luminal contents
– Depending on organ, major functions include:
▪ Secrete mucus, digestive enzymes, and hormones
▪ Absorb end products of digestion
▪ Protect against infectious disease
– Consists of three sublayers:
▪ Epithelium
▪ Lamina propria
▪ Muscularis mucosae

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Histology of the Alimentary Canal
– Epithelium
▪ Simple columnar epithelium with mucus-secreting cells in most of tract
– Stratified squamous in mouth, part of pharynx, esophagus, and anus
▪ Secretes mucus that protects digestive organs from enzymes and lubricates
canal to ease passage of food
▪ May secrete enzymes and hormones (e.g., in stomach and small intestine)
– Lamina propria consists of areolar connective tissue
▪ Capillaries nourish epithelium and absorb digested nutrients
▪ Scattered lymphoid follicles, part of MALT (mucosa-associated lymphoid
tissue), defend against pathogens
– Muscularis mucosae
▪ Thin layer of smooth muscle that produces local movements of mucosa

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Histology of the Alimentary Canal

Submucosa also consists of areolar connective tissue
– Rich supply of blood and lymphatic vessels, lymphoid follicles, and nerve
fibers (submucosal nerve plexus) serve surrounding tissues
– Abundant elastic fibers allow organs to stretch as a large volume of
foodstuff enters them, and then regain their normal shape after it passes
through
Muscularis externa (muscularis)
– Responsible for segmentation and peristalsis
– Contains an inner circular layer and an outer longitudinal layer of smooth
muscle
▪ Circular layer thickens to form sphincters that act as valves to regulate
movement of foodstuff from organ to organ

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Histology of the Alimentary Canal
Serosa is the visceral peritoneum
– Outermost layer of intraperitoneal organs
– Areolar connective tissue covered with mesothelium
(simple squamous epithelium)
Serosa replaced by adventitia (dense connective tissue)
in organs outside of the abdominopelvic cavity (e.g.,
esophagus)
– Binds organ wall to surrounding structures
Retroperitoneal organs have both an adventitia (side facing
body wall) and a serosa (side facing peritoneal cavity)

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Basic Structure of the Alimentary Canal

Figure 23.5 Basic structure of the alimentary canal.
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Blood Supply: The Splanchnic
Circulation
Splanchnic circulation includes:
– Arteries that branch off aorta to serve digestive organs
▪ Normally receive 25% of cardiac output, more after a meal
▪ Include:
– Celiac trunk (branches), which serves spleen, liver, and
stomach
– Superior and inferior mesenteric arteries, which serve
intestines
– Hepatic portal circulation
▪ Delivers nutrient-rich venous blood from digestive organs to
liver

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Enteric Nervous System
Consists of more neurons than the spinal cord

Consists of enteric neurons
– Communicate with each other to regulate digestive activities
– Form two major intrinsic nerve plexuses that control GI tract motility
▪ Submucosal nerve plexus
▪ Myenteric nerve plexus (lies between layers of muscularis)

Enteric nervous system participates in both short and long reflex arcs
– Short reflexes: mediated by intrinsic nerve plexuses in response to
stimuli within GI tract
– Long reflexes: mediated by CNS and extrinsic autonomic nerves in
response to stimuli arising within or outside of tract
▪ Parasympathetic inputs stimulate digestive processes
▪ Sympathetic inhibits them

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Neural Reflex Pathways Initiated by Stimuli
Inside or Outside the Gastrointestinal Tract

Figure 23.7 Neural reflex pathways initiated by stimuli inside or outside the
gastrointestinal tract.
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Basic Concepts of Regulating Digestive Activity
Three key concepts regulate digestive activity
– Neurons (intrinsic and extrinsic) and hormones control
digestive activity
▪ Nervous system controls
– Intrinsic controls: involve short reflexes (enteric
nervous system only)
– Extrinsic controls: involve long reflexes
▪ Hormonal controls
– Hormones from stomach and small intestine stimulate
targets (muscles, glands) in same or different organs
to affect secretion or contraction

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Part 2: Functional Anatomy of the
Digestive System

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23.4 Ingestion Occurs Only at the
Mouth
Mouth (oral cavity or buccal cavity) is where food is
chewed and mixed with enzyme-containing saliva that
begins process of digestion; also initiates propulsive
process of swallowing
Associated organs include:
– Tongue
– Salivary glands
– Teeth

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The Tongue
The tongue occupies the mouth floor; composed of interlacing
bundles of skeletal muscle
Functions:
– Grip, reposition, mix food (with saliva) during chewing to form
bolus (compact mass)
– Initiate swallowing (push bolus posteriorly into pharynx)
– Speech and taste

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Dorsal Surface of the Tongue, and the Tonsils

Figure 23.9 Dorsal surface of the tongue, and the tonsils.
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The Salivary Glands
Salivary glands secrete saliva, a fluid that:
– Cleanses mouth; dissolves food chemicals for taste and moistens food to compact
it into a bolus; begins breakdown of starch via amylase
Most saliva secreted (when we eat or anticipate it) by major or extrinsic salivary
glands
– Located outside of oral cavity (develop from oral mucosa, remain connected by
ducts); these paired glands include:
▪ Parotid gland: anterior to ear. Duct opens into oral vestibule next to second
upper molar
▪ Submandibular gland: medial to body of mandible
– Duct opens at base of lingual frenulum
▪ Sublingual gland: anterior to submandibular gland under tongue
– 10–20 ducts open into floor of mouth

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The Salivary Glands

Figure 23.10a The salivary glands.
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The Salivary Glands
Composed of two types of secretory cells
– Serous cells produce watery secretion with enzymes, ions, tiny bit of mucin
– Mucous cells produce mucus

Parotid and submandibular glands contain mostly serous cells, sublingual gland contains
mostly mucous cells
Composition of saliva
– Mostly water (97–99.5%), therefore hypo-osmotic; slightly acidic (pH 6.75 to 7)

– Electrolytes: Na , K  , Cl , PO 43 , HCO3 
– Salivary amylase and lingual lipase
– Proteins: mucin, lysozyme, and IgA
– Metabolic wastes: urea and uric acid

Saliva protects against microorganisms because it contains: IgA, lysozyme, defensins

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The Salivary Glands
Control of salivation
– Average output 1500 ml/day (much higher when major glands stimulated)
– Salivation controlled primarily by parasympathetic division of A NS
▪ Ingested food stimulates chemoreceptors and mechanoreceptors in mouth,
which signal the salivatory nuclei in brain stem
▪ Causes increased parasympathetic impulses via facial (VII) and
glossopharyngeal (IX) nerves to glands
▪ Results in secretion of watery (serous), enzyme-rich saliva
– Stimuli: smell, sight, thought of food
▪ Also irritation of lower GI tract by bacterial toxins, spicy foods, or acidity
– Sympathetic division causes release of thick, mucin-rich saliva
▪ Strong sympathetic stimulation can inhibit salivation (as can dehydration via
low blood volume/pressure)

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The Teeth

Teeth

Masticate (chew): process that tears and grinds food into smaller fragments

Dentition and the dental formula
– Deciduous dentition: 20 deciduous teeth erupt over months 6–24; also called
primary, milk or baby teeth
– Permanent dentition: 32 deep-lying permanent teeth enlarge and develop while
milk teeth roots resorbed, causing them to fall out (at 6–12 yr)
▪ Usually, all but third molars (wisdom teeth) erupt by end of adolescence; third
molars may or may not emerge (at 17  25 yr)
Teeth classified according to shape and function:
– Incisors: chisel shaped for cutting or nipping off pieces of food
– Canines (cuspids or eyeteeth): fanglike teeth that tear or pierce
– Premolars (bicuspids) and molars: broad crowns with rounded cusps to grind or
crush; molars best grinders (upper/lower lock together, creating huge forces)

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Human Dentition

Figure 23.11 Human dentition.

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Clinical—Homeostatic Imbalance 23.4
Decaying deciduous teeth can be painful and may lead to
serious infection
Deciduous teeth serve as important “place holders” for
developing permanent teeth
– Can be kept healthy by brushing and limiting exposure
to sugary liquids, especially from prolonged bottle
feeding

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The Teeth
Tooth structure
– Two major regions:
▪ Crown: exposed part above gingiva (gum)
– Covered by enamel, the hardest substance in body
Heavily mineralized with calcium salts and hydroxyapatite
crystals
– Enamel-producing cells degenerate when tooth erupts, so no
healing if areas decay or crack; needs artificial filling
▪ Root: portion embedded in jaw-bone

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The Teeth

Root connected to crown at the neck (constricted region)

Cementum: calcified connective tissue; covers and attaches root to periodontal ligament
– Periodontal ligament anchors tooth in bony socket (alveolus).
– Gingival sulcus: groove where gingiva borders tooth

Dentin: bonelike material under enamel; maintained by odontoblasts of pulp cavity
– Bulk of tooth, acts as shock-absorber
– Surrounds pulp cavity
▪ Contains pulp (connective tissue with blood vessels and nerve fibers)
– Nourishes tooth, provides sensation

Root canal: narrow extension of pulp cavity through root

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Longitudinal
Section of a
Canine Tooth
Within Its Bony
Socket (Alveolus)

Figure 23.12 Longitudinal section of a canine tooth within its bony socket (alveolus).
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Tooth and Gum Disease
Dental caries (cavities): demineralization of enamel and dentin from
bacterial action
– Dental plaque (film of sugar, bacteria, and debris) adheres to teeth
– Bacteria break down sugars, producing acids that dissolve calcium
salts, exposing organic tooth matrix
▪ Tooth proteins digested by proteolytic enzymes released from
bacteria
– Prevention: daily brushing and flossing
Gingivitis: red, sore, swollen gums (may bleed) resulting from infection
– Plaque calcifies to form calculus (tartar)
– Calculus disrupts seal between gingivae and teeth, so anaerobic
bacteria infect gums
– Infection is reversible if calculus removed

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Digestive Processes of the Mouth

Mouth and its accessory organs are involved in (four of six) digestive
processes

1. Ingests
2. Begins mechanical breakdown (via mastication)
3. Initiates propulsion (swallowing)
4. Starts digestion of polysaccharides (via salivary amylase)

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23.5 The Pharynx and Esophagus
Move Food from the Mouth to the
Stomach

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The Pharynx
Food passes from mouth into oropharynx and then into
laryngopharynx
– Allows passage of food, fluids, and air
– Lined with stratified squamous epithelium and
mucus-producing glands
– External muscle layers consists of two skeletal
muscle layers
▪ Inner layer cells run longitudinally
▪ Outer layer cells encircle the wall, forming the
pharyngeal constrictor muscles

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The Esophagus

Muscular tube ( 10 in) that runs from laryngopharynx to stomach
– Collapsed when not propelling food
– Pierces diaphragm at esophageal hiatus to join stomach at cardial orifice, which
is surrounded by lower esophageal sphincter (also called gastroesophageal, or
cardiac, sphincter)
▪ Keep orifice closed (assisted by diaphragm) when not swallowing
▪ Mucus cells on both sides of sphincter protect esophagus from acid reflux

Esophagus has all four basic GI tract tunics; features of interest include:
– Mucosa: nonkeratinized stratified squamous epithelium; changes to simple
columnar at stomach
– Submucosa: esophageal glands secrete mucus (lubricant) to aid passage of bolus
– Muscularis externa: skeletal muscle superiorly, smooth muscle inferiorly, mixed in
the middle
– Adventitia (instead of serosa)

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Microscopic Structure of the Esophagus

Figure 23.13 Microscopic structure of the esophagus.
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Deglutition
(Swallowing)

Figure 23.14 Deglutition (swallowing).
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Deglutition
(Swallowing)

Figure 23.14 Deglutition (swallowing).
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Deglutition
(Swallowing)

Figure 23.14 Deglutition (swallowing).
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Deglutition (Swallowing)

Figure 23.14 Deglutition (swallowing).
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Deglutition (Swallowing)

Figure 23.14 Deglutition (swallowing).
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Deglutition (Swallowing)

Figure 23.14 Deglutition (swallowing).
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23.6 The Stomach Temporarily Stores
Food and Begins Protein Digestion
Stomach is temporary “storage tank” for ingested food
– Continues breaking down food both physically and
chemically
▪ Producing paste-like chyme, and delivering it to
small intestine

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Gross Anatomy of the Stomach
Empty stomach has 50 ml volume but can expand to 4 L when really distended
Major regions of stomach
– Cardia (cardial part): surrounds cardial orifice
– Fundus: dome-shaped region beneath diaphragm, superolateral to cardia
– Body: midportion
– Pyloric part: funnel-shaped region, continuation of body
▪ Pyloric antrum (wider and more superior) narrows into pyloric canal that
terminates at the pylorus
– Pyloric sphincter (or valve) which controls stomach emptying into
duodenum

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Gross Anatomy of the Stomach
Two curvatures:
– Greater curvature: convex lateral surface of stomach
– Lesser curvature: concave medial surface of stomach

– Lesser omentum: runs from lesser curvature to liver
– Greater omentum: drapes inferiorly from greater curvature over intestine, spleen,
and transverse colon
▪ Contains fat deposits and lymph nodes

ANS innervation: sympathetic via celiac plexus and parasympathetic via vagus nerve

Blood supply: celiac trunk (gastric and splenic branches), veins of hepatic portal system

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Anatomy of the Stomach (1 of 2)

Figure 23.15a Anatomy of the stomach.
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 Microscopic Anatomy of the Stomach
Stomach wall contains basic four tunics; however, muscularis and mucosa are
modified
Muscularis externa

Allow stomach not only to churn, mix, and move chyme, but also pummel it,
increasing physical breakdown and movement into small intestine
Mucosa also modified
– Consists of simple columnar epithelium entirely composed of mucous
cells
– Dotted with gastric pits, which lead into tubular gastric glands that
produce gastric juice
▪ Pits formed by mucous cells (like surface); gland cells vary based on
region:
– E.g., mostly mucous cells in cardia and pylorus, but many
hormone (e.g., gastrin) secreting cells in pyloric antrum

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Microscopic Anatomy of the Stomach

Figure 23.16a Microscopic anatomy of the stomach.
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Microscopic Anatomy of the Stomach
Types of gland cells
– Glands in fundus and body are larger and produce most gastric juice
– Secretory cells include mucous neck, parietal, chief, and enteroendocrine

Mucous neck cells
– Secrete thin, soluble, acidic mucus (function undetermined)

Parietal cells
– Secrete hydrochloric acid (HCl) and the glycoprotein intrinsic factor
▪ Acidity (p H 1.5–3.5) denatures proteins, activates pepsinogen, breaks
down plant cell walls, and kills many bacteria
▪ Intrinsic factor required for absorption of vitamin B12
in small intestine

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Microscopic Anatomy of the Stomach
Chief cells
– Secrete pepsinogen and gastric lipases
▪ Pepsinogen first activated by HCl, then newly formed pepsin activates other
molecules of pepsinogen (positive feedback mechanism)
▪ Gastric lipases account for 15% of overall GI lipolysis
Enteroendocrine cells
– Secrete variety of chemical messengers into IF of lamina propria, including:
▪ Locally acting paracrines (e.g., histamine and serotonin)
▪ Messengers acting both locally and as hormones (e.g., somatostatin)
▪ The hormone gastrin

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Microscopic Anatomy of the Stomach

Figure 23.16c Microscopic anatomy of the stomach.
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Microscopic Anatomy of the Stomach
The mucosal barrier
– Mucosal barrier protects stomach from own acid and
proteolytic enzymes
– Three factors create barrier:
▪ A thick coating of bicarbonate-rich mucus
▪ The epithelial cells of the mucosa are joined
together by tight junctions
▪ Damaged epithelial mucosal cells are shed and
quickly replaced
– Surface epithelium replaced every 3–6 days

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Clinical—Homeostatic Imbalance 23.7
Gastritis: inflammation caused by anything that breaches
stomach’s mucosal barrier
Can lead to erosion of GI tract wall (peptic ulcers), called
gastric ulcers in stomach
– Perforations in stomach wall can lead to peritonitis and
hemorrhage
Most ulcers caused by acid-resistant bacteria Helicobacter pylori
(H. pylori)
– Can destroy the mucosal barrier
– Treated with antibiotics and acid-reducing drugs
Ulcers can also be caused by long-term use of NSAIDs

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Photomicrograph of H. Pylori, the Bacteria
That Most Commonly Cause Gastric Ulcers

Figure 23.18 Photomicrograph of H. pylori, the bacteria that most commonly cause
gastric ulcers.
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Digestive Processes in the Stomach
Propulsion via peristalsis

Mechanical breakdown via churning action during peristalsis

Digestion of proteins
– HCl denatures proteins, enhancing enzymatic digestion by pepsin
– In infants, rennin breaks down milk protein (casein)

Absorption of lipid-soluble alcohol and aspirin (but not nutrients)

Yet, only function essential to life is secretion of intrinsic factor for vitamin B12
absorption
– B12 needed for red blood cells to mature
– Lack of intrinsic factor causes pernicious anemia
– Treated with B12 injections

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 Regulation of Gastric Secretion
Gastric mucosa secretes up to 3 L of gastric juice/day; regulated by:
– Neural mechanisms: long reflexes (via parasympathetic fibers of vagus nerve) and
short (intrinsic) reflexes both stimulate gastric secretion (via release of ACh)
▪ Sympathetic inputs inhibit secretion
– Hormonal mechanisms: gastrin stimulates gastric secretion of HCl and secretion of
small intestine hormones (mostly gastrin antagonists called enterogastrones)

▪ Drugs that block H2 (histamine) receptors effectively reduce HCl secretion
Control of gastric secretion divided into three phases (based on location of stimuli):
cephalic, gastric, and intestinal
Cephalic (reflex) phase occurs before food reaches stomach (minutes long)
– Stimuli associated with the head (smell, taste, sight, thought of food)

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Regulation of Gastric Secretion
Gastric phase begins once food enters stomach (lasts 3–4 hours), accounts
for about two-thirds of gastric juice released
– Stimulation
▪ Distension activates stretch receptors, initiating both long and short
reflexes
▪ Chemical stimuli (partially digested proteins, amino acids) directly
stimulate enteroendocrine G cells to secrete gastrin
– Gastrin directly (and indirectly via triggering histamine release)
stimulates parietal cells to secrete HCl
– Inhibition
▪ Low pH (< 2) inhibits gastrin secretion; common between meals
▪ Inhibitory action of sympathetic division overrides vagal
(parasympathetic) stimulation during times of fight-or-flight (stress,
fear, anxiety)

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Regulation of Gastric Secretion
Intestinal phase begins with a brief stimulatory component followed by inhibition
– Stimulation
▪ Partially digested food enters small intestine, causing brief release of
intestinal (enteric) gastrin, encouraging continued gastric secretion
– Brief, overridden by inhibitory stimuli as intestine fills
– Inhibition via four main factors in duodenum
▪ Distension of duodenum from physical presence of chyme
▪ Chemical presence of acidic, fatty, or hypertonic chyme
– Inhibitory effects protect intestine from excessive acidity or too much chyme
– Inhibition achieved in two ways: enterogastric reflex and enterogastrones
▪ Enterogastric reflex: duodenum inhibits gastric secretion via short and long
reflexes (involving sympathetic and vagus nerves)
▪ Enterogastrones: group of hormones secreted by duodenal enteroendocrine
cells, most important are secretin and cholecystokinin (CCK)

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Figure 23.19 Neural and Hormonal Mechanisms
That Regulate Release of Gastric Juice

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Mechanism of HCl Secretion
Parietal cells pump H (from carbonic acid) into stomach
lumen via H /K  ATPases (proton pumps)
– As H enters stomach, HCO3  is exported into blood
(called alkaline tide) in exchange for Cl (via Cl /HCO3 
antiporter)
▪ Cl diffuses into lumen to join H and form HCl

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Mechanism of HCl Secretion by Parietal Cells

Figure 23.20 Mechanism of HCl secretion by parietal cells.
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Regulation of Gastric Motility and
Emptying
Response of the stomach to filling
– Stretches to accommodate incoming food
– Two factors cause pressure to remain constant until
1.5 L of food is ingested
▪ Receptive relaxation
– Reflex-mediated relaxation of smooth muscle
coordinated by swallowing center of brain stem
▪ Gastric accommodation
– Intrinsic stress-relaxation response of visceral
smooth muscle, allows stomach to stretch
without greatly increasing tension
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Regulation of Gastric Motility and
Emptying
Gastric contractile activity
– Contractions most powerful in pyloric part (holds 30 ml of chyme)
▪ Each peristaltic wave reaching pylorus ( 3/min) pushes 3 ml chyme
into duodenum; rest returns to stomach for more processing
– Only liquids and small particles pass through pyloric valve
– Enteric pacemaker cells generate
subthreshold waves of depolarization ( 3/min)
▪ Called cyclic slow waves of stomach, or its basic electrical rhythm (BER)

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Peristaltic Waves in the Stomach

Figure 23.21 Peristaltic waves in the stomach.
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Regulation of Gastric Motility and
Emptying
Regulation of gastric emptying
– Usually empties in 4 hr, but increase in fatty chyme entering
duodenum can increase time to 6 hr or more
▪ Carbohydrate-rich chyme moves quickly through duodenum
– Duodenum prevents overfilling by controlling how much chyme
enters

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Clinical—Homeostatic Imbalance 23.8
Vomiting (emesis) is caused by:
– Extreme stretching of GI tract
– Irritants such as bacterial toxins, excessive alcohol,
spicy food, certain drugs
Chemicals in blood and sensory impulses stimulate
emetic center of medulla
Excessive vomiting can lead to dehydration and
electrolyte and acid-base imbalances (metabolic
alkalosis)

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23.7 The Liver Secretes Bile; the
Pancreas Secretes Digestive Enzymes
Liver, gallbladder, and pancreas are accessory organs
associated with small intestine
– Liver: produces bile (fat emulsifier)
– Gallbladder: stores and concentrates bile
– Pancreas: supplies most enzymes for digestion, as
well as HCO3  to neutralize stomach acid

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The Liver

Gross anatomy of the liver
– Largest gland in body; weighs 3 lbs
– Consists of four primary lobes: right, left, caudate, and quadrate
▪ Gallbladder rests in recess on inferior surface of right lobe
– Falciform ligament
▪ Suspends liver from diaphragm and anterior abdominal wall
– Lesser omentum anchors liver to lesser curvature of stomach
– Hepatic artery proper and hepatic portal vein enter liver at porta hepatis
– Bile leaves liver via left and right hepatic ducts; fuse to form common hepatic duct
▪ Cystic duct fills/drains gallbladder
▪ Bile duct formed by union of common hepatic and cystic ducts

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Gross Anatomy of the Human Liver

Figure 23.23a Gross anatomy of the human liver.
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Gross Anatomy of the Human Liver

Figure 23.23b Gross anatomy of the human liver.
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Gross Anatomy of the Human Liver

Figure 23.23c Gross anatomy of the human liver.
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Microscopic Anatomy of the Liver

Figure 23.24a Microscopic anatomy of the liver.
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Microscopic Anatomy of the Liver

Figure 23.24b Microscopic anatomy of the liver.

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Microscopic Anatomy of the Liver

Figure 23.24c Microscopic anatomy of the liver.
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The Liver

Microscopic anatomy of the liver
– Hepatocytes have large amounts of both rough and smooth
ER, Golgi apparatus, peroxisomes, and mitochondria,
allowing them to:
▪ Produce 900 ml bile per day
▪ Process bloodborne nutrients
– E.g., store glucose as glycogen and use amino acids
to make plasma proteins
▪ Store fat-soluble vitamins
▪ Perform detoxification
– E.g., converting ammonia to urea

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 The Liver

Bile: Composition and enterohepatic circulation
– Yellow-green, alkaline solution containing bile salts, bile pigments, cholesterol,
triglycerides, phospholipids, and electrolytes
▪ Only bile salts (cholesterol derivatives) and phospholipids aid digestive
processes
▪ Bilirubin: main bile pigment, product of heme (hemoglobin) metabolism
– Intestinal bacteria metabolize into stercobilin; gives feces brown color
– Enterohepatic circulation: recycling mechanism that conserves bile salts
▪ Reabsorbed in ileum (the last part of small intestine) and returned to liver via
hepatic portal vein
▪ 95% of secreted bile salts recycled (only 5% newly synthesized each
time)

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The Enterohepatic Circulation

Figure 23.25 The enterohepatic circulation.
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The Liver
Homeostatic imbalances of the liver
– Hepatitis: inflammation of the liver
▪ Causes: viruses; toxic effects of alcohol, drugs, and wild mushrooms
▪ Five viruses that cause hepatitis identified and named: H AV to HEV
– HBV and HCV linked to chronic hepatitis, cirrhosis, and liver cancer
HCV treated with 12-week combination drug therapy
– Non-alcoholic fatty liver disease (NAFLD) most common liver disease in North
America; caused by abnormal lipid metabolism and liver inflammation
▪ Both associated with obesity and insulin resistance; predisposes patient to
develop cirrhosis or even cancer of the liver
– Cirrhosis: last stage of progressive chronic inflammation of liver; usually result of
alcohol use disorder, NAFLD, or viral hepatitis
▪ Fibrous (scar) tissue can obstruct blood flow and cause portal hypertension
– Liver transplants only effective treatment for end-stage liver disease
▪ Liver can regenerate to its full size in 6–12 months after 80% removal

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The Gallbladder
Thin-walled muscular sac on inferior surface of liver
(covered by visceral peritoneum)
Functions: store and concentrate bile (by absorbing
water and ions)
Contains many honeycomb folds that allow it to expand
as it fills
Muscular contractions release bile via cystic duct, which
leads into the bile duct

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Clinical—Homeostatic Imbalance 23.9

Gallstones: crystallized cholesterol, caused by too much
cholesterol or too few bile salts
– Can obstruct flow of bile from gallbladder (cholelithiasis)
– Painful when gallbladder contracts against sharp crystals
– Treatment: crystal-dissolving drugs, ultrasound vibrations
(lithotripsy), laser vaporization, or surgery (cholecystectomy)
Obstructive jaundice: bile duct blockage can cause bile salts
and pigments to build up in blood, resulting in jaundiced (yellow)
skin
– Jaundice can also reflect liver disease

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The Pancreas
Location: mostly retroperitoneal, deep to greater curvature of stomach
– Head is encircled by duodenum; tail next to spleen

Contains endocrine and exocrine parts:
– Exocrine function: produce pancreatic juice
▪ Acini: clusters of secretory acinar cells that produce zymogen
granules containing inactive digestive enzymes (proenzymes)
▪ Ducts: transport secretions of acinar cells from pancreas to
duodenum
– Small duct cells secrete water (bulk of pancreatic juice) with
HCO3 
– Endocrine function: secretion of insulin and glucagon by pancreatic islets

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Structure of the Enzyme-Producing
Tissue of the Pancreas

Figure 23.26a Structure of the enzyme-producing tissue of the pancreas.
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Structure of the Enzyme-Producing
Tissue of the Pancreas

Figure 23.26b Structure of the enzyme-producing tissue of the pancreas.
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The Pancreas

– Composition of pancreatic juice ( 1200  1500 ml/day)
– Watery, alkaline solution (pH 8) to neutralize acidic chyme from stomach
– Contains electrolytes (primarily HCO3  ) and digestive enzymes:
▪ Proteases (for proteins), made/secreted inactive to prevent self-digestion
▪ Amylase (for carbohydrates)
▪ Lipases (for lipids)
▪ Nucleases (for nucleic acids)
– Proteases activated in duodenum, where they work
▪ Enteropeptidase (formerly called enterokinase): enzyme bound to apical
membrane of duodenal epithelial cells, activates trypsinogen to trypsin
▪ Trypsin in turn can then activate:
– More trypsinogen to trypsin
– Procarboxypeptidase to carboxypeptidase
– Chymotrypsinogen to chymotrypsin

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Activation of
Pancreatic Proteases
in the Small Intestine

Figure 23.27 Activation of pancreatic proteases in the small intestine.
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Bile and Pancreatic Secretion Into the
Small Intestine
Anatomy of duct systems
– Bile duct and pancreatic duct (main pancreatic duct)
unite in wall of duodenum at bulblike structure called
hepatopancreatic ampulla
▪ Opens into duodenum via major duodenal papilla
▪ Hepatopancreatic sphincter controls entry of bile
and pancreatic juice into duodenum
– Accessory pancreatic duct: smaller, proximal duct that
empties directly into duodenum

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Relationship of the Liver, Gallbladder
and Pancreas to the Duodenum

Figure 23.28 Relationship of the liver, gallbladder, and pancreas to the duodenum.
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Mechanisms Promoting Secretion and
Release of Bile and Pancreatic Juice

Figure 23.29 Mechanisms promoting secretion and release of bile and pancreatic juice.
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23.8 The Small Intestine Is the Major Site
for Digestion and Absorption
Small intestine is the body’s major digestive organ
– Digestion is completed (with the help of bile and
pancreatic enzymes) and virtually all absorption

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Gross Anatomy

Small intestine: 6  7 m long ( 20 ft) in cadaver, from pyloric sphincter to ileocecal
valve; 2  4 m long (7  13 ft) in living person via muscle tone
– Diameter about 2.5  4 cm long (1  1.6 in), about half that of large intestine
Three subdivisions
– Duodenum: 25 cm (10 in) long
▪ Mostly retroperitoneal, curves around head of pancreas
– Jejunum: 2.5 m (8 ft) long, and ileum: 3.6 m (12 ft) long
▪ Attached to posterior abdominal wall by a mesentery (or mesentery proper)
▪ Terminal ileum joins large intestine at ileocecal valve

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The Small Intestine

Figure 23.30 The small intestine.
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Gross Anatomy

Blood supply:
– Superior mesenteric artery (oxygenated arterial
blood)
– Veins (nutrient-rich venous blood) empty into superior
mesenteric vein, which drains into hepatic portal vein
(to liver)
Nerve supply
– Parasympathetic innervation via vagus nerve
– Sympathetic innervation via thoracic splanchnic
nerves

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Microscopic Anatomy

Modifications of small intestine for absorption
– Small intestine’s length and three structural modifications provide huge surface
area for nutrient absorption
▪ Modifications – circular folds, villi, and microvilli—increase surface area
600 to 200 m2 (size of a tennis court)
– Circular folds: permanent folds of mucosa and submucosa ( 1 cm tall)
▪ Force chyme to slowly spiral through lumen, increasing surface area and time
for absorption
– Villi: fingerlike projections of mucosa ( 1 mm tall)
▪ Each villus contains a lacteal (lymphatic capillary for lipid absorption) and a
dense capillary bed
– Microvilli: cytoplasmic extensions of apical surface of enterocytes that create
fuzzy appearance called brush border
▪ Membrane-bound brush border enzymes complete carbohydrate and protein
digestion

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Structural Modifications of the Small Intestine That Increase
Its Surface Area for Digestion and Absorption

Figure 23.31a,b Structural modifications of the small intestine that increase its surface
area for digestion and absorption.
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Microscopic Anatomy
Histology of the small intestine wall
– Modifications of its mucosa and submucosa reflect its function in digestion
– Epithelium of villi and the tubular intestinal crypts (intestinal glands) between villi
consists of five main cell types:
▪ Enterocytes: simple columnar absorptive cells with dense microvilli, bound by
tight junctions; form bulk of epithelium
▪ Goblet cells: mucus-secreting cells
▪ Enteroendocrine cells: secrete enterogastrones, including CCK and secretin;
mostly in crypts, some in villi
▪ Paneth cells: deep in crypts, secrete antimicrobial agents (defensins,
lysozyme) that destroy certain bacteria
▪ Stem cells: deep in crypts, continuously divide and differentiate to produce
other cell types; cells at tips of villi undergo apoptosis and shed
– Renewing villus epithelium every 2–4 days

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Clinical—Homeostatic Imbalance 23.10
Chemotherapy targets rapidly dividing cells
– Destroying cancer cells, but also rapidly dividing GI
tract epithelial cells
▪ Explains resulting nausea, vomiting, and diarrhea
after treatment

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Microscopic Anatomy
Histology of the small intestine wall (cont.)inued

– MALT (mucosa-associated lymphoid tissue) protects intestine against
microorganisms; includes:
▪ Individual lymphoid follicles
▪ Peyer’s patches (aggregated lymphoid nodules): located in lamina
propria, but can protrude into submucosa
– Found in increasing numbers in distal ileum (lots of bacteria
there)
– Lamina propria also contains abundant plasma cells that secrete IgA
(antibodies)
– Submucosa of duodenum contains elaborate duodenal glands that
secrete alkaline (bicarbonate-rich) mucus to neutralize acidic chyme

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Digestive Processes in the Small
Intestine
Chyme entering the small intestine contains partially digested carbohydrates and
proteins, and largely undigested fats
– 3–6 hours to pass through small intestine as nutrients and most water
absorbed
Sources of enzymes for digestion
– Bile, HCO3  , enzymes are imported from liver and pancreas
– Membrane-bound brush border enzymes perform final steps of digestion
Regulating chyme entry
– Chyme entering duodenum usually hypertonic, so its delivery must be slow to
prevent osmotic loss of water from blood
– Low pH of chyme must be raised, and it must be mixed with bile and pancreatic
juice to continue digestion
– Feedback via enterogastric reflex and enterogastrones carefully control movement
of food into duodenum to avoid overwhelming it

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Digestive Processes in the Small
Intestine
Motility of the small intestine
– Two motility patterns:
▪ Segmentation: principal form of motility after meal, for mixing
▪ Migrating motor complex: form of peristalsis, primary pattern between meals
– After a meal
▪ Initiated by intrinsic pacemaker cells, alternately contracting/relaxing rings of
smooth muscle move chyme back-and-forth (also slowly moving it toward
cecum)
▪ Intensity controlled by long and short reflexes and hormones
– Parasympathetic increases motility; sympathetic decreases it
– Between meals
▪ True peristalsis, initiated by rise in hormone motilin, every 90–120 min
▪ Each wave starts distal to previous; called migrating motor complex (MMC)
▪ Complete trip from duodenum to ileum takes 2 hr

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Digestive Processes in the Small
Intestine
Ileocecal valve control
– Ileocecal valve relaxes to admit chyme into cecum
(of large intestine) via:
▪ Gastroileal reflex
– Also increases force of segmentation
▪ Gastrin
– Also increases motility of ileum
– Ileocecal valve flaps close when chyme exerts
backward pressure
▪ Prevents regurgitation into ileum

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23.9 The Large Intestine Absorbs Water
and Eliminates Feces
Large intestine extends from ileocecal valve to anus
– Much shorter than small intestine (1.5 m v s 6 m), but ersu

about twice the diameter (7 cm)
– Major digestive functions:
▪ Absorb most of the remaining water from
indigestible food residues
– Also absorb metabolites produced by resident
bacteria
▪ Store residues temporarily, then eliminate them as
semisolid feces (or stool)

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Gross Anatomy
Subdivisions of large intestine: cecum, appendix, colon, rectum, and anal
canal
– Cecum: saclike, first part of large intestine
– Appendix: contains masses of lymphoid tissue (part of MALT)
▪ Bacterial storehouse capable of recolonizing gut when necessary
▪ Twisted shape of appendix makes it susceptible to blockage

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Clinical—Homeostatic Imbalance 23.11
Appendicitis: acute inflammation of appendix
– Usually results from a blockage (often by feces) that traps infectious
bacteria
– Most common in adolescence when entrance to appendix is at its widest

Symptoms: pain in umbilical region, moving to lower right abdominal quadrant
– loss of appetite, nausea, and vomiting are also seen

Venous drainage can be impaired, leading to ischemia and necrosis (tissue
death)
– Ruptured appendix can cause peritonitis as bacteria leak out into
peritoneal cavity
Treatment: surgical removal (appendectomy), or in select cases, with
antibiotics

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Gross Anatomy

Subdivisions of large intestine (cont.)
inued

– Colon has four main regions
▪ Ascending colon: travels up right side of abdominal cavity to liver
– Ends in right-angle turn called right colic (hepatic) flexure
▪ Transverse colon: travels across abdominal cavity to spleen
– Ends in another right-angle turn, left colic (splenic) flexure
▪ Descending colon: travels down left side of abdominal cavity
▪ Sigmoid colon: S-shaped portion that travels through pelvis to join rectum
– Rectum: runs just in front of sacrum; three transverse folds (rectal valves) stop
feces from being passed with gas
– Anal canal: last segment of large intestine, external to abdominopelvic cavity
▪ Open to exterior at anus; two sphincters close anus except during defecation
– Internal anal sphincter (smooth muscle)
– External anal sphincter (skeletal muscle)

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Gross Anatomy of the Large Intestine

Figure 23.33a Gross anatomy of the large intestine.
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Gross Anatomy of the Large Intestine

Figure 23.33b Gross anatomy of the large intestine.
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Gross Anatomy
Relationship of the large intestine to the peritoneum
– Colon is retroperitoneal, except for transverse and
sigmoid colon
▪ These intraperitoneal regions (transverse and
sigmoid) anchored to posterior abdominal wall by
mesenteries called mesocolons
– Rectum also retroperitoneal

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Mesenteries of the Abdominal Digestive
Organs

Figure 23.34a Mesenteries of the abdominal digestive organs.
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Mesenteries of the Abdominal Digestive
Organs

Figure 23.34d Mesenteries of the abdominal digestive organs.
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Microscopic Anatomy
Like the small intestine, the large intestine is lined with simple columnar epithelium
(except anal canal has stratified squamous to withstand abrasion)
Large intestine (in contrast to the small):
– Does not contain circular folds, villi, or a brush border
– Contains thicker mucosa with deeper crypts that have more goblet cells
▪ Mucus lubricates passageway (to move feces) and protects wall from irritation
– Anal sinuses, recesses between anal columns, release mucus when compressed
by feces (aids in emptying anal canal)
– Inferior margins of anal sinuses form wavy line

Two superficial venous plexuses of anal canal form hemorrhoids if dilated and inflamed

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Clinical—Homeostatic Imbalance 23.12
Clostridium difficile, an anaerobic bacterium, is most common cause of
antibiotic-associated diarrhea (accounts for 14,000 deaths per year)
In some, C. difficile makes up tiny fraction of their bacterial flora; in others it
enters via fecal-oral route (poor handwashing)
When other bacteria destroyed by antibiotics, C. difficile may flourish and
cause colon inflammation (pseudomembranous colitis) that leads to bowel
perforation and sepsis
– C. difficile infections are resistant to antibiotics and difficult to treat
(often reoccur)
– Fecal transplant: restores competitive bacteria by transferring fecal
bacteria from uninfected donor to patient
▪ Cures C. difficile infections 90–100% of the time

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Digestive Processes in the Large
Intestine
Food residue remains in large intestine 12–24 hours
– No further digestion (except for bacterial)
– Salts (e.g., NaCl, NaHCO3 ) and water, and vitamins released from bacterial
metabolism, are absorbed
Major function of large intestine is propulsion of feces to anus for defecation

Motility of the large intestine
– Haustral contractions: slow segmenting movements, mostly in ascending and
transverse colon; last 1 min and occur every 30 min
▪ Distension of haustrum triggers its contraction (to mix contents)
– Mass movements (mass peristalsis): long, slow-moving, powerful contractile
waves that move feces toward rectum; occur about 3– 4 per day
▪ Descending colon and sigmoid colon store feces (and finish dehydrating it)
until moved into rectum by mass movements
▪ Usually occur during/after eating (via gastrocolic reflex)

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Clinical—Homeostatic Imbalance 23.13
Large intestine is important for our comfort, but is not
essential for life
If colon removed, terminal ileum can be brought to
abdominal wall in a procedure called an ileostomy
– Food residues eliminated into sac attached to stoma in
abdominal wall

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Clinical—Homeostatic Imbalance 23.14
Low-fiber diet leads to narrowing of colon and stronger contractions that
increase pressure on walls
– Can result in diverticulosis, a condition where diverticula (herniations of
mucosa through intestinal wall) develops in colon, usually sigmoid colon
▪ Affects > 50% of people over 70

Sometimes, diverticulosis progresses to diverticulitis (inflamed diverticula)
– May rupture and leak into peritoneal cavity (potentially life threatening)

Irritable bowel syndrome (IBS): recurring abdominal pain relieved by
defecation; functional disorder not explained by anatomical or biochemical
abnormalities
– May have changes in consistency and frequency of stools, bloating,
flatulence, nausea, depression
– Stress is a precipitating factor, so stress management is important in
treatment

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Digestive Processes in the Large
Intestine
Defecation
– Mass movements force feces into rectum
– Distension initiates defecation reflex (parasympathetic spinal reflex)
▪ Triggers contraction of sigmoid colon and rectum
▪ Relaxes internal anal sphincter
▪ Voluntary control allows contraction/relaxation of external anal sphincter
– During reflex, rectal muscles contract to expel feces, which is assisted by:
▪ Valsalva’s maneuver—closing of glottis and contraction of diaphragm
and abdominal wall muscles to increase intra-abdominal pressure
▪ Contract levator ani muscle, causing anal canal to be lifted superiorly

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Defecation
Reflex (3 of 3)

Figure 23.35 Defecation reflex.
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Clinical—Homeostatic Imbalance 23.15
Diarrhea, or watery stools, results when large intestine does not
have sufficient time to absorb remaining water
– Causes include irritation of colon by bacteria or jostling of
digestive viscera (occurs in marathon runners)
– Prolonged diarrhea may result in dehydration and
electrolyte imbalance (acidosis and loss of potassium)
Constipation occurs when residue remains in colon too long
and too much water is absorbed, so stool becomes difficult to
pass
– May result from insufficient fiber or fluid intake, repeatedly
delaying defecation, lack of exercise, or laxative abuse

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Part 3—Physiology of Digestion
and Absorption

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23.10 Digestion Hydrolyzes Food into Nutrients
That Are Absorbed Across the Gut Epithelium
Digestion breaks down ingested foods into their chemical
building blocks, molecules that are small enough to be
absorbed across the small intestine wall

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Mechanism of Digestion: Enzymatic
Hydrolysis
Digestion: catabolic process that breaks macromolecules
(polymers) down into molecular building blocks (monomers)
small enough for absorption; mostly in small intestine
– Via enzymes secreted into GI tract from intrinsic and
accessory glands, and intestinal brush border enzymes
– Enzymes carry out hydrolysis, whereby water is added to
break chemical bonds
In general, pancreatic (also salivary and gastric) enzymes break
down larger polymers into smaller polymers that are eventually
broken down into absorbable monomers by (intestinal) brush
border enzymes

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 Mechanisms of Absorption
Absorption is process of moving substances from lumen of gut into body

Tight junctions force most substances to pass through epithelial cells (rather
than between them)
– Enter through apical membrane (lumen side) and exit through
basolateral membrane (interstitial fluid side)
– Once in IF, substances (except lipids) diffuse into capillaries (lipids enter
lacteals)
Small nonpolar lipid (lipophilic) molecules absorbed passively via simple
diffusion
All other substances need a membrane transport mechanism (mostly active
transport)
Most nutrients are absorbed before chyme reaches ileum

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Mechanisms of Absorption

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23.11 How Is Each Type of Nutrient
Processed?

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Carbohydrate Digestion and Absorption in
the Small Intestine (4 of 4)

Figure 23.37 Carbohydrate digestion and absorption in the small intestine.
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Protein Digestion and
Absorption in the
Small Intestine (4 of 4)

Figure 23.38 Protein digestion and absorption in the small intestine.
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Lipids
Steps of lipid (triglyceride) digestion and absorption in small intestine

1. Emulsification: breaking up large fat globules into tiny droplets (via bile salts) that
remain suspended in chyme, increasing surface area for digestion of lipids
▪ Bile salts have nonpolar and polar regions to interact with both lipids and water

2. Digestion: pancreatic lipase breaks down triglyceride into monoglyceride and two
free fatty acids
3. Micelle formation: end products of digestion become associated with bile salts
and lecithin (phospholipid), forming micelles
4. Diffusion: lipids leave micelles and cross apical membrane via simple diffusion
5. Chylomicron formation: lipids converted back into triglycerides and packaged
with phospholipids, cholesterol, proteins; forming lipoprotein called chylomicron
6. Chylomicron transport: chylomicrons exit basolateral membrane via exocytosis;
once in the IF they diffuse into lacteals (lymphatic vessels) (too large for capillary)
▪ Eventually emptied into venous blood at thoracic duct
Short-chain fatty acids can diffuse directly into blood

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Emulsification,
Digestion, and
Absorption of
Fats (6 of 6)

Figure 23.39 Emulsification, digestion, and absorption of
fats.
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Flowchart of Digestion and Absorption
of Nucleic Acids

Figure 23.36 Flowchart of digestion and absorption of foodstuffs.

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Absorption of Vitamins, Electrolytes,
and Water
Vitamin absorption
– Small intestine absorbs dietary vitamins
▪ Fat-soluble vitamins (A, D, E, and K) are incorporated into micelles with other
lipophilic solutes; diffuse into absorptive cells by simple diffusion
▪ Most water-soluble (B and C) vitamins are absorbed by passive or active
transporters
– Vitamin B12 (large, charged molecule) binds with intrinsic factor and
is absorbed by endocytosis
– Large intestine absorbs vitamin K and B vitamins from bacterial metabolism

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Absorption of Vitamins, Electrolytes,
and Water
Electrolyte absorption
– Most ions are transported actively along length of small intestine; iron and
calcium absorbed in duodenum (amount depends on needs)
– Sodium, chloride, and bicarbonate
▪ Na absorption is active (Na  K  pumps), creating electrical
gradient for anions (e.g., Cl ) to passively follow
– Potassium
▪ K  transported by facilitated diffusion; gradient created as water
absorbed
▪ Lack of water absorption (e.g., diarrhea) reduces K 
absorption, and can even “pull” K  out of IF into gut lumen

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Absorption of Vitamins, Electrolytes,
and Water
– Iron
▪ Ionic iron actively transported into mucosal cells
where most binds to ferritin until needed, then
transported in blood by transferrin
– Calcium
▪ Calcium absorption is regulated (increased) by
active vitamin D (calcitriol) and parathyroid
hormone (PTH)

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Absorption of Vitamins, Electrolytes,
and Water
Water absorption
– 9L water (mostly from secretions) enters small intestine daily
▪ 95% absorbed by osmosis
▪ More absorbed in large intestine, leaving 100 ml in feces
– Concentration gradients established by active transport of solutes (mostly Na )
provide net osmosis out of lumen

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IP Animation: Enzymatic Digestion and
Absorption

Click here to view ADA compliant Animation:
IP Animation: Enzymatic Digestion and
Absorption

https://mediaplayer.pearsoncmg.com/assets/secs-enzymatic-digestion-and-absorption

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Developmental Aspects of the Digestive
System
Primitive gut: epithelial lining is formed from endoderm;
rest of GI tract from mesoderm
Oral membrane: becomes mouth; formed when foregut
fuses with stomodeum
Cloacal membrane: becomes anus; formed when hindgut
fuses with proctodeum
By week 5, alimentary canal is a continuous tube from
mouth to anus
Shortly after, accessory organs bud from mucosa

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Embryonic Development of the
Digestive System

Figure 23.40 Embryonic development of the digestive system.

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