1. © 2014 Pearson Education, Inc.
Figure Neural and hormonal mechanisms that regulate release of gastric juice.
Stimulatory events
Inhibitory events
Cephalic
phase
Sight and thought
of food 1
Cerebral cortex
Lack of
stimulatory
impulses to
parasym-
pathetic
center
Cerebral
cortex
Loss of
appetite,
depression 1
Conditioned reflex
Stimulation of
taste and smell
receptors 2
Hypothalamus
and medulla
oblongata
Vagus
nerve
Stomach
distension
activates
stretch
receptors 1
Vagovagal
reflexes
Medulla
Vagus
nerve
Gastrin
secretion
declines
G cells
Excessive
acidity
(pH < 2)
in stomach 1
Gastric
phase
Local
reflexes
Overrides
parasym-
pathetic
controls
Sympathetic
nervous
system
activation
Emotional
stress 2
Food chemicals
(especially peptides and
caffeine) and rising pH
activate chemoreceptors 2
G cells
Gastrin
release
to blood
Stomach
secretory
activity
Entero-
gastric
reflex
Local
reflexes
Distension
of duodenum;
presence of
fatty, acidic, or
hypertonic
chyme; and/or
irritants in
the duodenum 1
Presence of
partially digested
foods in duodenum
or distension of the
duodenum when
stomach begins to
empty 1
Intestinal
(enteric)
gastrin
release
to blood
Vagal
nuclei
in medulla
Brief
effect
Intestinal
phase
Pyloric
sphincter
Release of
enterogastrones
(secretin, cholecystokinin,
vasoactive intestinal
peptide)
Distension;
presence of
fatty, acidic,
partially
digested food
in the
duodenum 2
Stimulate
Inhibit
© 2014 Pearson Education, Inc.

4. © 2014 Pearson Education, Inc.
Figure Neural and hormonal mechanisms that regulate release of gastric juice.
Stimulatory events
Inhibitory events
Cephalic
phase
Sight and thought
of food 1
Cerebral cortex
Lack of
stimulatory
impulses to
parasym-
pathetic
center
Cerebral
cortex
Loss of
appetite,
depression 1
Conditioned reflex
Stimulation of
taste and smell
receptors 2
Hypothalamus
and medulla
oblongata
Vagus
nerve
Stomach
distension
activates
stretch
receptors 1
Vagovagal
reflexes
Medulla
Vagus
nerve
Gastrin
secretion
declines
G cells
Excessive
acidity
(pH < 2)
in stomach 1
Gastric
phase
Local
reflexes
Overrides
parasym-
pathetic
controls
Sympathetic
nervous
system
activation
Emotional
stress 2
Food chemicals
(especially peptides and
caffeine) and rising pH
activate chemoreceptors 2
G cells
Gastrin
release
to blood
Stomach
secretory
activity
Entero-
gastric
reflex
Local
reflexes
Distension
of duodenum;
presence of
fatty, acidic, or
hypertonic
chyme; and/or
irritants in
the duodenum 1
Presence of
partially digested
foods in duodenum
or distension of the
duodenum when
stomach begins to
empty 1
Intestinal
(enteric)
gastrin
release
to blood
Vagal
nuclei
in medulla
Brief
effect
Intestinal
phase
Pyloric
sphincter
Release of
enterogastrones
(secretin, cholecystokinin,
vasoactive intestinal
peptide)
Distension;
presence of
fatty, acidic,
partially
digested food
in the
duodenum 2
Stimulate
Inhibit
© 2014 Pearson Education, Inc.

5. Figure 22.15b Microscopic anatomy of the stomach.
Gastric pits
Surface epithelium
(mucous cells)
Gastric
pit
Mucous neck cells
Parietal cell
Gastric
gland
Chief cell
Enteroendocrine cell
Enlarged view of gastric pits and
gastric glands
© 2014 Pearson Education, Inc.

6. Figure 22.15c Microscopic anatomy of the stomach.
Pepsinogen
Pepsin
HCI
Mitochondria
Parietal cell
Chief cell
Enteroendocrine
cell
Location of the HCl-producing parietal cells
and pepsin-secreting chief cells in a gastric
gland
© 2014 Pearson Education, Inc.

7. Figure 22.18 Mechanism of HCl secretion by parietal cells.
Gastric gland
Blood
capillary
Chief cell
Stomach lumen
CO2
CO2 +
H2O
H+-K+
ATPase
Carbonic
anhydrase
H2CO3 H+ H+ K+ K+
HCO3−
HCI
Alkaline
tide
Parietal cell
HCO3−
Cl−
Cl−
Cl−
HCO3−- Cl−
antiporter
Interstitial
fluid
© 2014 Pearson Education, Inc.

8. Figure 22.15c Microscopic anatomy of the stomach.
Pepsinogen
Pepsin
HCI
Mitochondria
Parietal cell
Chief cell
Enteroendocrine
cell
Location of the HCl-producing parietal cells
and pepsin-secreting chief cells in a gastric
gland
© 2014 Pearson Education, Inc.

10. Bacteria Mucosa layer of stomach A gastric ulcer lesion
Figure Photographs of a gastric ulcer and the H. pylori bacteria that most commonly cause it.
Bacteria
Mucosa
layer of
stomach
A gastric ulcer lesion
H. pylori bacteria
© 2014 Pearson Education, Inc.

11. © 2014 Pearson Education, Inc.
Figure Neural and hormonal mechanisms that regulate release of gastric juice.
Stimulatory events
Inhibitory events
Cephalic
phase
Sight and thought
of food 1
Cerebral cortex
Lack of
stimulatory
impulses to
parasym-
pathetic
center
Cerebral
cortex
Loss of
appetite,
depression 1
Conditioned reflex
Stimulation of
taste and smell
receptors 2
Hypothalamus
and medulla
oblongata
Vagus
nerve
Stomach
distension
activates
stretch
receptors 1
Vagovagal
reflexes
Medulla
Vagus
nerve
Gastrin
secretion
declines
G cells
Excessive
acidity
(pH < 2)
in stomach 1
Gastric
phase
Local
reflexes
Overrides
parasym-
pathetic
controls
Sympathetic
nervous
system
activation
Emotional
stress 2
Food chemicals
(especially peptides and
caffeine) and rising pH
activate chemoreceptors 2
G cells
Gastrin
release
to blood
Stomach
secretory
activity
Entero-
gastric
reflex
Local
reflexes
Distension
of duodenum;
presence of
fatty, acidic, or
hypertonic
chyme; and/or
irritants in
the duodenum 1
Presence of
partially digested
foods in duodenum
or distension of the
duodenum when
stomach begins to
empty 1
Intestinal
(enteric)
gastrin
release
to blood
Vagal
nuclei
in medulla
Brief
effect
Intestinal
phase
Pyloric
sphincter
Release of
enterogastrones
(secretin, cholecystokinin,
vasoactive intestinal
peptide)
Distension;
presence of
fatty, acidic,
partially
digested food
in the
duodenum 2
Stimulate
Inhibit
© 2014 Pearson Education, Inc.

12. Figure 22.14a Anatomy of the stomach.
Cardia
Fundus
Esophagus
Muscularis
externa
Serosa
Longitudinal layer
Circular layer
Oblique layer
Body
Lumen
Lesser
curvature
Rugae of
mucosa
Greater
curvature
Pyloric sphincter
(valve) at pylorus
Pyloric
canal
Pyloric
antrum
Duodenum
© 2014 Pearson Education, Inc.

13. Figure 22.19 Peristaltic waves in the stomach.
Pyloric
valve
slightly
opened
Pyloric
valve
closed
Pyloric
valve
closed
Propulsion: Peristaltic waves move from the fundus toward the pylorus. 1
Grinding: The most vigorous peristalsis and mixing action occur close to the pylorus. 2
Retropulsion: The pyloric end of the stomach acts as a pump that delivers small amounts of chyme into the duodenum, simultaneously forcing most of its contained material backward into the stomach. 3
© 2014 Pearson Education, Inc.

14. Figure 22.30c Mesenteries of the abdominal digestive organs.
Greater omentum
Transverse colon
Transverse
mesocolon
Descending colon
Jejunum
Mesentery
Sigmoid
mesocolon
Sigmoid colon
Ileum
© 2014 Pearson Education, Inc.

15. Vein carrying blood to hepatic portal vessel Muscle layers Lumen
Figure 22.22a Structural modifications of the small intestine that increase its surface area for digestion and absorption.
Vein carrying
blood to
hepatic portal
vessel
Muscle
layers
Lumen
Circular
folds
Villi
© 2014 Pearson Education, Inc.

16. Microvilli (brush border) Absorptive cells Lacteal Villus Goblet cell
Figure 22.22b Structural modifications of the small intestine that increase its surface area for digestion and absorption.
Microvilli
(brush border)
Absorptive
cells
Lacteal
Villus
Goblet
cell
Blood
capillaries
Mucosa-
associated
lymphoid
tissue
Intestinal
crypt
Enteroendocrine
cells
Venule
Muscularis
mucosae
Lymphatic vessel
Duodenal
gland
Submucosa
© 2014 Pearson Education, Inc.

17. Absorptive cells Goblet cells Villi Intestinal crypt
Figure 22.22c Structural modifications of the small intestine that increase its surface area for digestion and absorption.
Absorptive cells
Goblet
cells
Villi
© 2014 Pearson Education, Inc.
Intestinal crypt

18. Figure 22.21 The duodenum of the small intestine, and related organs.
Right and left
hepatic ducts
of liver
Cystic duct
Common hepatic duct
Bile duct and sphincter
Accessory pancreatic duct
Mucosa
with folds
Tail of pancreas
Pancreas
Gallbladder
Jejunum
Major duodenal
papilla
Main pancreatic duct and sphincter
Hepatopancreatic
ampulla and sphincter
Duodenum
Head of pancreas
© 2014 Pearson Education, Inc.

19. Chyme enter -ing duodenum causes duodenal
Figure Mechanisms promoting secretion and release of bile and pancreatic juice.
Chyme enter -ing duodenum causes duodenal
enteroendocrine cells to release cholecystokinin
(CCK) and secretin. 1 4
Bile salts and, to a lesser extent, secretin
transported via
bloodstream stimulate Liver to produce bile more rapidly. 5
CCK (via blood stream) causes gallbladder to contract and Hepatopancreatic
Sphincter to relax. Bile Enters duodenum.
CCK (red dots) and secretin (yellow dots) enter the bloodstream. 2
CCK induces
secretion of enzyme-rich
pancreatic juice. Secretin causes secretion of HCO3− -rich pancreatic juice. 3
During cephalic and gastric phases, vagal Nerve stimu- lates gallbladder to
contract weakly. 6
CCK secretion
Secretin secretion
© 2014 Pearson Education, Inc.

20. Figure 22.29a Gross anatomy of the large intestine.
Left colic
(splenic) flexure
Transverse
mesocolon
Right colic
(hepatic) flexure
Epiploic
appendages
Transverse colon
Superior
mesenteric artery
Descending colon
Haustrum
Ascending colon
IIeum
Cut edge of
mesentery
IIeocecal valve
Tenia coli
Sigmoid colon
Cecum
Appendix
Rectum
Anal canal
External anal sphincter
© 2014 Pearson Education, Inc.

21. Figure 22.29b Gross anatomy of the large intestine.
Rectal valve
Rectum
Hemorrhoidal
veins
Levator ani muscle
Anal canal
External anal
sphincter
Internal anal
sphincter
Anal columns
Pectinate line
Anal sinuses
Anus
© 2014 Pearson Education, Inc.

22. Figure 22.31 Defecation reflex.
Impulses from
cerebral cortex
(conscious
control)
Sensory
nerve fibers
Feces move into and
distend the rectum,
stimulating stretch receptors
there. The receptors transmit
signals along afferent fibers
to spinal cord neurons. 1
Voluntary motor
nerve to external
anal sphincter
Sigmoid
colon
Stretch receptors in wall
A spinal reflex is initiated in which
parasympathetic motor (efferent) fibers
stimulate contraction of the rectum and
sigmoid colon, and relaxation of the
internal anal sphincter. 2
Rectum
External anal
sphincter
(skeletal muscle)
Involuntary motor nerve
(parasympathetic division)
Internal anal sphincter (smooth muscle)
If it is convenient to defecate,
voluntary motor neurons are inhibited,
allowing the external anal sphincter to
relax so feces may pass. 3
© 2014 Pearson Education, Inc.