1. Pharynx (throat) Salivary Oral cavity glands (mouth) Esophagus Stomach
Fig. 16.1
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Pharynx
(throat)
Oral cavity
(mouth)
Salivary
glands
Esophagus
Stomach
Pancreas
Small
intestine
Liver
Large
intestine
Gallbladder
Appendix
Rectum
Anus

2. Fatty acids Mono- glycerides Amino acids
Fig
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Food
Carbohydrates
Lipids
Proteins
Fatty
acids
Mono-
glycerides
Amino
acids
Monosaccharides

3. Fig
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Carbohydrates
Lipids
Proteins
Mouth
(salivary glands)
Salivary amylase
Polysaccharides, Disaccharides
Stomach
Pepsin
Polypeptides
Duodenum
(pancreas, liver)
Bile salts
(liver)
Trypsin, chymotrypsin,
carboxypeptidase
(pancreas)
Pancreatic amylase
Lipase
(pancreas)
Disaccharides
Peptides
Epithelium of
small intestine
Disaccharidases
Peptidases
Monosaccharides
Fatty acids
Monoglycerides
Amino acids

4. Pharynx (throat) Salivary Oral cavity glands (mouth) Esophagus Stomach
Fig. 16.1
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Pharynx
(throat)
Oral cavity
(mouth)
Salivary
glands
Esophagus
Stomach
Pancreas
Small
intestine
Liver
Large
intestine
Gallbladder
Appendix
Rectum
Anus

5. Fig. 16.2 Blood vessels Myenteric plexus Lymphatic vessel Enteric
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Blood vessels
Myenteric
plexus
Lymphatic vessel
Enteric
plexus
Submucosal
plexus
Nerve
Gland in
submucosa
Mesentery
Ducts from
glands
Lymphatic
nodule
Intestinal
gland
Mucosa
(mucous
membrane)
Submucosa
Muscularis
Circular
muscle
layer
Longitudinal
Serosa
(serous
membrane;
visceral
peritoneum)
Epithelium
Lamina
propria
Connective
tissue
layer
Muscularis
mucosae
Simple
squamous
epithelium

6. Table 7.2

7. Table 4.10b

8. A wave of smooth muscle relaxation moves
Fig. 16.9
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Digestive tract
Bolus 1
Wave of
relaxation 1
A wave of smooth muscle relaxation moves
ahead of the bolus, allowing the digestive
tract to expand. 2
A wave of contraction of the smooth muscle
behind the bolus propels it through the
digestive tract.
Bolus
moves. 2
Wave of
contraction

9. A secretion introduced into the digestive tract or into food within
Fig
Copyright © McGraw-Hill Education. Permission required for reproduction or display. 1
A secretion introduced into the
digestive tract or into food within
the tract begins in one location.
Secretion or food 1 2
Segments of the digestive tract
alternate between contraction
and relaxation.
Contraction waves 2 3
Material (brown) in the intestine is
spread out in both directions from
the site of introduction. 3 4
Contraction waves 4
The secretion or food is spread out
in the digestive tract and becomes more
diffuse (lighter color) through time.

10. Fig. 16.2 Blood vessels Myenteric plexus Lymphatic vessel Enteric
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Blood vessels
Myenteric
plexus
Lymphatic vessel
Enteric
plexus
Submucosal
plexus
Nerve
Gland in
submucosa
Mesentery
Ducts from
glands
Lymphatic
nodule
Intestinal
gland
Mucosa
(mucous
membrane)
Submucosa
Muscularis
Circular
muscle
layer
Longitudinal
Serosa
(serous
membrane;
visceral
peritoneum)
Epithelium
Lamina
propria
Connective
tissue
layer
Muscularis
mucosae
Simple
squamous
epithelium

11. Fig. 16.4 Upper lip Gingiva covering the maxillary alveolar process
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Hard palate
Soft palate
Uvula
Cheek
Molars
Premolars
Canine
Incisors
Upper lip
Tongue
Frenulum of the tongue
Lower lip
Gingiva covering the
maxillary alveolar
process
Openings of the
submandibular ducts
mandibular alveolar

12. Parotid duct Buccinator muscle Mucous membrane (cut) Ducts of the
Fig. 16.7
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Buccinator
muscle
Mucous membrane
(cut)
Ducts of the
sublingual gland
Sublingual
gland
Submandibular
duct
Parotid
Masseter
Parotid duct

13. During the voluntary phase, a bolus of food
Fig
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Tongue
Hard palate
Soft palate 1
Bolus
Oropharynx 1
During the voluntary phase, a bolus of food
(yellow) is pushed by the tongue against the
hard and soft palates and posteriorly toward
the oropharynx (blue arrow indicates tongue
movement; black arrow indicates movement
of the bolus). Tan: bone; purple: cartilage;
red: muscle.

14. Fig. 16.8
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Tongue
Hard palate
Soft palate
Nasopharynx 1
Soft palate 2
Superior pharyngeal
constrictor
Middle pharyngeal
constrictor
Bolus
Epiglottis
Oropharynx
Inferior pharyngeal
constrictor
Larynx
Upper esophageal
sphincter
Esophagus 1
During the voluntary phase, a bolus of food
(yellow) is pushed by the tongue against the
hard and soft palates and posteriorly toward
the oropharynx (blue arrow indicates tongue
movement; black arrow indicates movement
of the bolus). Tan: bone; purple: cartilage;
red: muscle. 2
During the pharyngeal phase, the soft
palate is elevated, closing off the
nasopharynx. The pharynx and larynx are
elevated (blue arrows indicate muscle
movement; green arrow indicates
elevation of the larynx). 3 3
Epiglottis
Superior
pharyngeal
constrictor
Middle
pharyngeal
constrictor
Opening of larynx
Vestibular fold
Vocal fold 3
Successive constriction of the pharyngeal constrictors from superior to inferior (blue arrows)
forces the bolus through the pharynx and into the esophagus. As this occurs, the vestibular and
vocal folds expand medially to close the passage of the larynx. The epiglottis (green arrow) is
bent down over the opening of the larynx largely by the force of the bolus pressing against it.
Inferior pharyngeal
constrictor
Upper esophageal
sphincter 4 5
Esophagus
Esophagus 4
As the inferior pharyngeal constrictor
contracts, the upper esophageal sphincter
relaxes (outwardly directed blue arrows),
allowing the bolus to enter the esophagus. 5
During the esophageal phase, the bolus is
moved by peristaltic contractions of the
esophagus toward the stomach (inwardly
directed blue arrows).

15. Fig
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Esophagus
Fundus
Location of lower
esophageal sphincter
Body
Gastroesophageal opening
Serosa
Cardiac part
Longitudinal muscle layer
Circular muscle layer
Muscularis
Oblique muscle layer
Pyloric sphincter
Submucosa
Pyloric orifice
Mucosa
Pyloric
part
Pyloric canal
Pyloric antrum
Duodenum
Rugae
Gastric
pit
Surface
mucous
cell
Lamina
propria
Gastric
glands
Goblet
cell
Mucous
neck cells
Surface
mucous
cell
Parietal
cells
Mucosa
Mucous
neck cell
Gastric pit
Chief
cells
Endocrine
cells
Submucosa
Blood vessels
Oblique muscle
layer
Muscularis
Circular muscle
layer
Longitudinal
muscle layer
Connective
tissue layer
Simple
Serosa
(visceral
peritoneum)
squamous
epithelium
LM 30x
©Victor Eroschenko

16. Fig
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Cephalic Phase 1
The taste, smell, or thought of food or tactile
sensations of food in the mouth stimulate the
medulla oblongata (green arrows).
Taste, smell, or thought of food
(chemoreceptors) 2
Vagus nerves carry parasympathetic action
potentials to the stomach (pink arrow), where
enteric plexus neurons are activated. 1
Tactile sensation in mouth
Hypothalamus 3
Postganglionic neurons stimulate secretion by
parietal and chief cells and stimulate gastrin and
histamine secretion by endocrine cells.
Medulla oblongata
Secretions
stimulated 4
Gastrin is carried through the circulation back to the
stomach (purple arrow), where, along with
histamine, it stimulates secretion. 4
Vagus nerves 2
(a) 3
Histamine
Gastrin
Circulation
Stomach
Gastric Phase 1
Distention of the stomach stimulates
mechanoreceptors (stretch receptors) and activates
a parasympathetic reflex. Action potentials
generated by the mechanoreceptors are carried by
the vagus nerves to the medulla oblongata (green
arrow).
Vagus nerves
Medulla
oblongata 2
The medulla oblongata increases action potentials
in the vagus nerves that stimulate secretions by
parietal and chief cells and stimulate gastrin and
histamine secretion by endocrine cells (pink arrow). 1
Secretions
stimulated
Secretions
stimulated 3
Distention of the stomach also activates local
reflexes that increase stomach secretions (orange
arrow). 2 4
Distention 3 4
Gastrin is carried through the circulation back to the
stomach (purple arrow), where, along with
histamine, it stimulates secretion.
Histamine
Gastrin
Circulation
(b)
Intestinal Phase
Stomach 1
Chyme in the duodenum with a pH less than 2 or
containing fat digestion products (lipids) inhibits
gastric secretions by three mechanisms (2–4).
Vagus
nerves 2
Chemoreceptors in the duodenum are stimulated
by H+ (low pH) or lipids. Action potentials generated
by the chemoreceptors are carried by the vagus
nerves to the medulla oblongata (green arrow),
where they inhibit parasympathetic action potentials
(pink arrow), thereby decreasing gastric secretions.
Medulla oblongata
Secretions
inhibited
Decreased
gastric
secretions
Vagus
nerves 4 3
Local reflexes activated by H+ or lipids also inhibit
gastric secretion (orange arrows). 2
Local
reflexes 1 4
Secretin and cholecystokinin produced by the
duodenum (brown arrows) decrease gastric
secretions in the stomach.
pH <2
or lipids 3
(c)
Circulation
Secretin and cholecystokinin

17. Fig. 16.12 1 A mixing wave initiated in the body
Copyright © McGraw-Hill Education. Permission required for reproduction or display. 1
A mixing wave initiated in the body
of the stomach progresses toward
the pyloric sphincter (pink arrows
directed inward).
Esophagus
Mixing
wave
Chyme
Pyloric
sphincter 2
The more fluid part of the chyme
is pushed toward the pyloric
sphincter (blue arrows), whereas
the more solid center of the chyme
squeezes past the peristaltic
constriction back toward the body
of the stomach (orange arrow). 1
Duodenum
Body of
stomach 2
More solid
chyme 3
Peristaltic waves (purple
arrows) move in the same
direction and in the same way as
the mixing waves but are stronger.
Pyloric
region
More fluid
chyme 4
Again, the more fluid part of the
chyme is pushed toward the
pyloric region (blue arrows),
whereas the more solid center of
the chyme squeezes past the
peristaltic constriction back
toward the body of the stomach
(orange arrow). 3 5
Peristaltic contractions force a
few milliliters of the most fluid
chyme through the pyloric opening
into the duodenum (small red arrows).
Most of the chyme, including the more
solid portion, is forced back toward
the body of the stomach for further
mixing (yellow arrow). 4 5

18. Stomach Duodenum Ascending colon Jejunum Mesentery Ileocecal junction
Fig
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Stomach
Duodenum
Ascending
colon
Jejunum
Mesentery
Ileocecal
junction
Ileum
Cecum
Appendix

19. Fig
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Villi
Blood capillary
network
Lacteal
Circular folds
Epithelium
Epithelium
Submucosa
Intestinal
gland
Circular muscle
Longitudinal muscle
Serosa
Duodenal
gland
(a)
(b)
Top of
circular fold
Microvilli of epithelial cell surface
Epithelial
Villus
cell
Capillary
(blood)
Lacteal
(lymph)
(d)
(c)

20. A secretion introduced into the digestive tract or into food within
Fig
Copyright © McGraw-Hill Education. Permission required for reproduction or display. 1
A secretion introduced into the
digestive tract or into food within
the tract begins in one location.
Secretion or food 1 2
Segments of the digestive tract
alternate between contraction
and relaxation.
Contraction waves 2 3
Material (brown) in the intestine is
spread out in both directions from
the site of introduction. 3 4
Contraction waves 4
The secretion or food is spread out
in the digestive tract and becomes more
diffuse (lighter color) through time.

21. A wave of smooth muscle relaxation moves
Fig. 16.9
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Digestive tract
Bolus 1
Wave of
relaxation 1
A wave of smooth muscle relaxation moves
ahead of the bolus, allowing the digestive
tract to expand. 2
A wave of contraction of the smooth muscle
behind the bolus propels it through the
digestive tract.
Bolus
moves. 2
Wave of
contraction

22. ©CNRI/SPL/Science Source
Fig
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Transverse colon
Left colic flexure
Right colic flexure
Ascending
colon
Descending colon
Ileum
Teniae coli
Ileocecal
valve
Cecum
Appendix
Sigmoid colon
Rectum
Internal anal sphincter
Anal canal
(a)
External anal sphincter
(b)
©CNRI/SPL/Science Source

23. Fig
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Inferior vena cava
Right lobe
Left lobe
Falciform
ligament
Round ligament
Liver
Gallbladder
(a)
Gallbladder
Quadrate lobe
Hepatic ducts
Right lobe
Hepatic portal vein
Portal
triad
Hepatic artery
Caudate lobe
Left lobe
Lesser
omentum
Inferior vena cava
(b)
To hepatic vein and
inferior vena cava
Liver lobule
Hepatic cords
Central vein
Bile canaliculi
Hepatic
phagocytic cells
Hepatic duct
Hepatic portal vein
Portal triad
Hepatic artery
Hepatocyte
Hepatic
sinusoid
To common bile duct
From aorta
(c)
From digestive tract

24. Fig. 13.19 Inferior vena cava Hepatic veins Liver Stomach
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Inferior vena cava
Hepatic veins
Liver
Stomach
Gastric veins
Gallbladder
Gastroomental veins
Cystic
vein
Spleen
Splenic vein with
pancreatic branches
Hepatic
portal vein
Tail of pancreas
Duodenum
Splenic vein
Gastroomental veins
Head of pancreas
Superior
mesenteric vein
Inferior mesenteric vein
Descending colon
Ascending colon
Small intestine
Appendix

25. Fig. 16.17 1 The hepatic ducts from the liver lobes
Copyright © McGraw-Hill Education. Permission required for reproduction or display. 1
The hepatic ducts from the liver lobes
combine to form the common hepatic
duct.
Liver
Gallbladder
Hepatic ducts
Common
hepatic duct 1 2
The common hepatic duct combines
with the cystic duct from the gallbladder
to form the common bile duct.
Cystic duct
Spleen
Hepatic portalvein 2
Common bile duct 3
The common bile duct joins the
pancreatic duct.
Accessory pancreatic
duct 5 4
The combined duct empties into the
duodenum at the duodenal papilla. 4 3
Pancreatic
duct
Duodenal
papilla 5
Pancreatic secretions may also enter
the duodenum through an accessory
pancreatic duct, which also empties
into the duodenum.
Pancreas
Duodenum
(cutaway view)

26. Fig. 16.18 Brain 1 Vagus nerve stimulation (red arrow)
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Brain 1
Vagus nerve stimulation (red arrow)
causes the gallbladder to contract,
thereby releasing bile into the
duodenum. 2
Secretin, produced by the
duodenum (purple arrows) and
carried through the circulation to the
liver, stimulates bile secretion by the
liver (green arrows inside the liver). 1
Vagus nerves 3
Cholecystokinin, produced by the
duodenum (pink arrows) and
carried through the circulation to the
gallbladder, stimulates the
gallbladder to contract and the
sphincters to relax, thereby
releasing bile into the duodenum
(green arrow outside the liver).
Bile
Bile
Liver
Bile 4
Bile salts also stimulate bile
secretion. Over 90% of bile salts
are reabsorbed in the ileum and
returned to the liver (green
arrows), where they stimulate
additional secretion of bile salts. 2
Cholecystokinin
Secretin
Gallbladder
Bile
Stomach 3
Cholecystokinin
Secretin
Pancreas
Bile salts
Circulation 4
Duodenum

27. Fig. 16.17 1 The hepatic ducts from the liver lobes
Copyright © McGraw-Hill Education. Permission required for reproduction or display. 1
The hepatic ducts from the liver lobes
combine to form the common hepatic
duct.
Liver
Gallbladder
Hepatic ducts
Common
hepatic duct 1 2
The common hepatic duct combines
with the cystic duct from the gallbladder
to form the common bile duct.
Cystic duct
Spleen
Hepatic portalvein 2
Common bile duct 3
The common bile duct joins the
pancreatic duct.
Accessory pancreatic
duct 5 4
The combined duct empties into the
duodenum at the duodenal papilla. 4 3
Pancreatic
duct
Duodenal
papilla 5
Pancreatic secretions may also enter
the duodenum through an accessory
pancreatic duct, which also empties
into the duodenum.
Pancreas
Duodenum
(cutaway view)

28. Fig. 16.18 Brain 1 Vagus nerve stimulation (red arrow)
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Brain 1
Vagus nerve stimulation (red arrow)
causes the gallbladder to contract,
thereby releasing bile into the
duodenum. 2
Secretin, produced by the
duodenum (purple arrows) and
carried through the circulation to the
liver, stimulates bile secretion by the
liver (green arrows inside the liver). 1
Vagus nerves 3
Cholecystokinin, produced by the
duodenum (pink arrows) and
carried through the circulation to the
gallbladder, stimulates the
gallbladder to contract and the
sphincters to relax, thereby
releasing bile into the duodenum
(green arrow outside the liver).
Bile
Bile
Liver
Bile 4
Bile salts also stimulate bile
secretion. Over 90% of bile salts
are reabsorbed in the ileum and
returned to the liver (green
arrows), where they stimulate
additional secretion of bile salts. 2
Cholecystokinin
Secretin
Gallbladder
Bile
Stomach 3
Cholecystokinin
Secretin
Pancreas
Bile salts
Circulation 4
Duodenum

29. Fig. 16.19 Common bile duct Jejunum Duodenum Pancreatic duct
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Fig
Common bile duct
Jejunum
Duodenum
Pancreatic duct
Body of pancreas
Accessory
pancreatic
duct
Tail of pancreas
Duodenal
papilla
Head of
pancreas
(a)
Pancreatic
islet
Acini cells
(secrete enzymes)
Cells producing
glucagon
Cells producing
insulin
Vein To
pancreatic
duct To
bloodstream
(b)

30. Fig. 16.20 Brain Stomach Vagus nerves 1 Pancreatic juices 1
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Brain
Stomach
Vagus nerves 1
Pancreatic
juices 1
Parasympathetic stimulation from the vagus
nerve (red arrow) causes the pancreas to
release a secretion rich in digestive enzymes. 2
Secretin 2
Secretin (purple arrows), released from
the duodenum, stimulates the pancreas
to release a watery secretion, rich in
bicarbonate ions.
Cholecystokinin 3
Pancreas
Duodenum 3
Cholecystokinin (pink arrows), released from
the duodenum, causes the pancreas to
release a secretion rich in digestive enzymes.
Circulation
Cholecystokinin
Secretin

31. Fig. 16.24 Villus Capillary Lacteal Intestinal epithelial cell
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Villus
Capillary
Lacteal
Intestinal
epithelial cell
Monosaccharide (glucose) transport 1
Glucose is absorbed by symport with Na+
into intestinal epithelial cells. 2
Symport is driven by a sodium gradient
established by a Na+–K+ pump.
Glucose 4 3 1 3
Glucose moves out of the intestinal
epithelial cells by facilitated diffusion. Na + Na +
Glucose enters the capillaries of the
intestinal villi and is carried through the
hepatic portal vein to the liver. A TP 4
ADP 2 Na + K +
To liver

32. Fig. 16.27 Villus Capillary Lacteal Amino acid transport Intestinal
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Villus
Capillary
Lacteal
Amino acid transport
Intestinal
epithelial cell 1
Acidic and most neutral amino acids are absorbed
by symport into intestinal epithelial cells. 2
Symport is driven by a sodium gradient established
by a Na+–K+ pump.
Amino acid 3 3 4
Amino acids move out of intestinal epithelial
cells. 1 4
Amino acids enter the capillaries of the intestinal
villi and are carried through the hepatic portal
vein to the liver. Na + Na + A TP
ADP Na + K + 2
To liver

33. Fig. 13.19 Inferior vena cava Hepatic veins Liver Stomach
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Inferior vena cava
Hepatic veins
Liver
Stomach
Gastric veins
Gallbladder
Gastroomental veins
Cystic
vein
Spleen
Splenic vein with
pancreatic branches
Hepatic
portal vein
Tail of pancreas
Duodenum
Splenic vein
Gastroomental veins
Head of pancreas
Superior
mesenteric vein
Inferior mesenteric vein
Descending colon
Ascending colon
Small intestine
Appendix

34. Fig. 16.25 Lipid transport Villus 1
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Lipid transport
Villus 1
Bile salts surround fatty acids and
monoglycerides to form micelles.
Capillary
Lacteal 2
Micelles attach to the plasma membranes
of intestinal epithelial cells, and the fatty
acids and monoglycerides pass by simple
diffusion into the intestinal epithelial cells.
Intestinal
epithelial cell
Micelles contact
epithelial cell
membrane. 3
Within the intestinal epithelial cell, the fatty
acids and monoglycerides are converted to
triglycerides; proteins coat the triglycerides
to form chylomicrons, which move out of
the intestinal epithelial cells by exocytosis. 1
Triglycerides
Protein coat 4 3
Bile
salt
Fatty acids
and monoglycerides 2
Simple
diffusion
Exocytosis 4
The chylomicrons enter the lacteals of the
intestinal villi and are carried through the
lymphatic system to the general circulation.
Micelle
Chylomicron
Lymphatic
system

35. Tonsils Cervical lymph node Right lymphatic duct Thoracic duct Thymus
Fig
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Tonsils
Cervical
lymph node
Right lymphatic
duct
Thoracic duct
Thymus
Axillary
lymph node
Subclavian
veins
Thoracic
duct
Mammary
plexus
Spleen
Lacteals in
intestinal wall
Lymphatic vessel
(transports lymph)
Inguinal
lymph node
Bone
marrow
(a)

36. Fig. 16.28 Ingestion (2 L) Salivary gland secretions (1 L) Gastric
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Ingestion
(2 L)
Salivary gland secretions
(1 L)
Gastric
secretions
(2 L)
Pancreatic
secretions
(1.2 L)
Bile
(0.7 L)
92%
absorbed in the
small intestine
Small intestine
secretions
(2 L)
6%–7%
absorbed in the
large intestine
Ingestion or
secretion
Absorption
1% in
feces
(Water infeces = Ingested + Secreted – Absorbed)

37. ©CNRI/SPL/Science Source
Fig
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Transverse colon
Left colic flexure
Right colic flexure
Ascending
colon
Descending colon
Ileum
Teniae coli
Ileocecal
valve
Cecum
Appendix
Sigmoid colon
Rectum
Internal anal sphincter
Anal canal
(a)
External anal sphincter
(b)
©CNRI/SPL/Science Source

38. Fig. 16.3 Liver Visceral peritoneum Lesser omentum Stomach
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Liver
Visceral peritoneum
Lesser omentum
Stomach
Peritoneal cavity
containing peritoneal
fluid
Pancreas (retroperitoneal)
Kidney (retroperitoneal)
Parietal peritoneum
Duodenum (retroperitoneal)
Greater omentum
Transverse colon
Omental bursa
Mesentery proper
Small intestine
Urinary bladder
(retroperitoneal)
Rectum (retroperitoneal)
Medial view