1. Pancreas
Location
Mostly retroperitoneal, deep to greater curvature of stomach
Head encircled by duodenum; tail abuts spleen
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2. Watery alkaline solution (pH 8) neutralizes chyme
Pancreatic Juice
1200 – 1500 ml/day
Watery alkaline solution (pH 8) neutralizes chyme
Electrolytes (primarily HCO3–)
Enzymes
Amylase, lipases, nucleases secreted in active form but require ions or bile for optimal activity
Proteases secreted in inactive form
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3. Digestion in the Small Intestine
Chyme from stomach contains
Partially digested carbohydrates and proteins
Undigested fats
3–6 hours in small intestine
Most water absorbed
~ All nutrients absorbed
Small intestine, like stomach, no role in ingestion or defecation
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4. Requirements for Digestion and Absorption in the Small Intestine
Slow delivery of acidic, hypertonic chyme
Delivery of bile, enzymes, and bicarbonate ions from liver and pancreas
Mixing
© 2013 Pearson Education, Inc.

5. Motility of the Small Intestine
Segmentation
Most common motion of small intestine
Initiated by intrinsic pacemaker cells
Mixes/moves contents toward ileocecal valve
Wanes in late intestinal (fasting) phase
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6. Motility of the Small Intestine
Peristalsis
Initiated by rise in hormone motilin in late intestinal phase; every 90–120 minutes
Each wave starts distal to previous
Migrating motor complex
Meal remnants, bacteria, and debris moved to large intestine
From duodenum  ileum ~ 2 hours
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7. Figure 23.3a Peristalsis and segmentation.
From
mouth
Peristalsis: Adjacent segments of alimentary tract organs alternately contract and relax, moving food along the tract distally.
© 2013 Pearson Education, Inc.

8. Motility of the Small Intestine
Local enteric neurons coordinate intestinal motility
Cholinergic sensory neurons may activate myenteric plexus
Causes contraction of circular muscle proximally and of longitudinal muscle distally
Forces chyme along tract
© 2013 Pearson Education, Inc.

9. Large Intestine Unique features Teniae coli Haustra
Three bands of longitudinal smooth muscle in muscularis
Haustra
Pocketlike sacs caused by tone of teniae coli
Epiploic appendages
Fat-filled pouches of visceral peritoneum
© 2013 Pearson Education, Inc.

10. Large Intestine Regions Cecum Appendix Colon Rectum Anal canal
© 2013 Pearson Education, Inc.

11. External anal sphincter
Figure 23.29a 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
© 2013 Pearson Education, Inc.

12. Subdivisions of the Large Intestine
Cecum – first part of large intestine
Appendix – masses of lymphoid tissue
Part of MALT of immune system
Bacterial storehouse  recolonizes gut when necessary
Twisted  enteric bacteria accumulate and multiply
© 2013 Pearson Education, Inc.

13. Retroperitoneal except for transverse and sigmoid regions
Colon
Retroperitoneal except for transverse and sigmoid regions
Ascending colon (right side – to level of right kidney)  right colic (hepatic) flexure 
Transverse colon  left colic (splenic) flexure 
Descending colon (left side) 
Sigmoid colon in pelvis  rectum
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14. Greater omentum Transverse colon Transverse mesocolon Descending colon
Figure 23.30c Mesenteries of the abdominal digestive organs.
Greater omentum
Transverse colon
Transverse
mesocolon
Descending colon
Jejunum
Mesentery
Sigmoid
mesocolon
Sigmoid colon
Ileum
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15. Liver Lesser omentum Pancreas Stomach Duodenum Transverse mesocolon
Figure 23.30d Mesenteries of the abdominal digestive organs.
Liver
Lesser omentum
Pancreas
Stomach
Duodenum
Transverse mesocolon
Transverse colon
Mesentery
Greater omentum
Jejunum
Ileum
Visceral peritoneum
Parietal peritoneum
Urinary bladder
Rectum
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16. Rectum and Anus Rectum Anal canal Sphincters
Three rectal valves stop feces from being passed with gas (flatus)
Anal canal
Last segment of large intestine
Opens to body exterior at anus
Sphincters
Internal anal sphincter—smooth muscle
External anal sphincter—skeletal muscle
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17. Anal columns Pectinate line Anal sinuses Anus
Figure 23.29b 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
© 2013 Pearson Education, Inc.

18. Large Intestine: Microscopic Anatomy
Thicker mucosa of simple columnar epithelium except in anal canal (stratified squamous to withstand abrasion)
No circular folds, villi, digestive secretions
Abundant deep crypts with goblet cells
Superficial venous plexuses of anal canal form hemorrhoids if inflamed
© 2013 Pearson Education, Inc.

19. Enter from small intestine or anus
Bacterial Flora
Enter from small intestine or anus
Colonize colon
Synthesize B complex vitamins and vitamin K
Metabolize some host-derived molecules (mucin, heparin, hyaluronic acid)
Ferment indigestible carbohydrates
Release irritating acids and gases (~500 ml/day)
© 2013 Pearson Education, Inc.

20. Viruses and protozoans
Intestinal Flora
Viruses and protozoans
Bacteria prevented from breaching mucosal barrier
Epithelial cells recruit dendritic cells to mucosa  sample microbial antigens  present to T cells of MALT  IgA antibody-mediated response  restricts microbes
© 2013 Pearson Education, Inc.

21. Digestive Processes in the Large Intestine
Residue remains in large intestine 12–24 hours
No food breakdown except by enteric bacteria
Vitamins (made by bacterial flora), water, and electrolytes (especially Na+ and Cl–) reclaimed
Major functions - propulsion of feces to anus; defecation
Colon not essential for life
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22. Motility of the Large Intestine
Most contractions of colon
Haustral contractions
Slow segmenting movements
Haustra sequentially contract in response to distension
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23. Motility of the Large Intestine
Gastrocolic reflex
Initiated by presence of food in stomach
Activates three to four slow powerful peristaltic waves per day in colon (mass movements)
© 2013 Pearson Education, Inc.

24. Homeostatic Imbalance
Low fiber diet  narrowed colon  strong contractions  increased pressure on walls  diverticula (herniations of mucosa)
Diverticulosis commonly in sigmoid colon
Affects ½ people > 70 years
Diverticulitis
Inflamed diverticula; may rupture and leak into peritoneal cavity; may be life threatening
© 2013 Pearson Education, Inc.

25. Homeostatic Imbalance
Irritable bowel syndrome
Functional GI disorder
Recurring abdominal pain, stool changes, bloating, flatulence, nausea, depression
Stress common precipitating factor
Stress management important in treatment
© 2013 Pearson Education, Inc.

26. Mass movements force feces toward rectum
Defecation
Mass movements force feces toward rectum
Distension initiates spinal defecation reflex
Parasympathetic signals
Stimulate contraction of sigmoid colon and rectum
Relax internal anal sphincter
Conscious control allows relaxation of external anal sphincter
© 2013 Pearson Education, Inc.

27. Muscles of rectum contract to expel feces
Defecation
Muscles of rectum contract to expel feces
Assisted by Valsalva's maneuver
Closing of glottis, contraction of diaphragm and abdominal wall muscles  increased intra-abdominal pressure
Levator ani muscle contracts  anal canal lifted superiorly  feces leave body
© 2013 Pearson Education, Inc.

28. stimulating stretch receptors there. The receptors transmit
Figure Defecation reflex.
Slide 1
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
© 2013 Pearson Education, Inc.

29. stimulating stretch receptors there. The receptors transmit
Figure Defecation reflex.
Slide 2
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
Sigmoid
colon
Stretch receptors in wall
© 2013 Pearson Education, Inc. 29

30. stimulating stretch receptors there. The receptors transmit
Figure Defecation reflex.
Slide 3
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
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
Involuntary motor nerve
(parasympathetic division)
Internal anal sphincter (smooth muscle)
© 2013 Pearson Education, Inc. 30

31. stimulating stretch receptors there. The receptors transmit
Figure Defecation reflex.
Slide 4
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
© 2013 Pearson Education, Inc. 31

32. Digestion Digestion Enzymes Hydrolysis
Catabolic; macromolecules  monomers small enough for absorption
Enzymes
Intrinsic and accessory gland enzymes break down food
Hydrolysis
Water is added to break bonds
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33. Digestion of Carbohydrates
Only monosaccharides can be absorbed
Monosaccharides absorbed as ingested
Glucose, fructose, galactose
Digestive enzymes
Salivary amylase, pancreatic amylase, and brush border enzymes (dextrinase, glucoamylase, lactase, maltase, and sucrase)
Break down disaccharides sucrose, lactose, maltose; polysaccharides glycogen and starch
© 2013 Pearson Education, Inc.

34. Digestion of Carbohydrates
Starch digestion
Salivary amylase (saliva)  oligosaccharides at pH 6.75 – 7.00
Pancreatic amylase (small intestine)  breaks down any that escaped salivary amylase  oligosaccharides
Brush border enzymes (dextrinase, glucoamylase, lactase, maltase, sucrase)  oligosaccharides  monosaccharides
© 2013 Pearson Education, Inc.

35. Starch and disaccharides
Figure Flowchart of digestion and absorption of foodstuffs. (1 of 4)
Foodstuff
Enzyme(s) and source
Site of action
Path of absorption
Starch and disaccharides
Glucose and galactose are
absorbed via cotransport with
sodium ions.
Fructose passes via facilitated
diffusion.
All monosaccharides leave the
epithelial cells via facilitated
diffusion, enter the capillary blood
in the villi, and are transported to
the liver via the hepatic portal vein.
Salivary amylase
Mouth
Pancreatic
amylase
Small
intestine
Oligosaccharides
and disaccharides
Carbohydrate
digestion
Brush border
enzymes in
small intestine
(dextrinase, gluco-
amylase, lactase,
maltase, and sucrase)
Small
intestine
Lactose
Maltose
Sucrose
Galactose
Glucose
Fructose
© 2013 Pearson Education, Inc.

36. Digestion of Proteins
Source is dietary, digestive enzymes, mucosal cells; digested to amino acid monomers
Begins with pepsin in stomach at pH 1.5 – 2.5
Inactive in high pH of duodenum
Pancreatic proteases
Trypsin, chymotrypsin, and carboxypeptidase
Brush border enzymes
Aminopeptidases, carboxypeptidases, and dipeptidases
© 2013 Pearson Education, Inc.

37. Amino acids of protein fragments
Figure Protein digestion and absorption in the small intestine.
Slide 1
Lumen
of intestine
Amino acids of protein fragments
Brush border enzymes
Pancreatic
proteases
Apical membrane (microvilli)
Na+
Proteins and protein fragments
are digested to amino acids by
pancreatic proteases (trypsin,
chymotrypsin, and carboxy-
peptidase), and by brush border
enzymes (carboxypeptidase,
aminopeptidase, and dipeptidase)
of mucosal cells. 1
Absorptive
epithelial
cell
Na+
The amino acids are then
absorbed by active transport into
the absorptive cells, and move to
their opposite side. 2
Amino
acid
carrier
The amino acids leave the villus
epithelial cell by facilitated diffusion
and enter the capillary via
intercellular clefts. 3
Capillary
© 2013 Pearson Education, Inc.

38. Amino acids of protein fragments
Figure Protein digestion and absorption in the small intestine.
Slide 2
Lumen
of intestine
Amino acids of protein fragments
Brush border enzymes
Pancreatic
proteases
Apical membrane (microvilli)
Na+
Proteins and protein fragments
are digested to amino acids by
pancreatic proteases (trypsin,
chymotrypsin, and carboxy-
peptidase), and by brush border
enzymes (carboxypeptidase,
aminopeptidase, and dipeptidase)
of mucosal cells. 1
Absorptive
epithelial
cell
Na+
Capillary
© 2013 Pearson Education, Inc. 38

39. Amino acids of protein fragments
Figure Protein digestion and absorption in the small intestine.
Slide 3
Lumen
of intestine
Amino acids of protein fragments
Brush border enzymes
Pancreatic
proteases
Apical membrane (microvilli)
Na+
Proteins and protein fragments
are digested to amino acids by
pancreatic proteases (trypsin,
chymotrypsin, and carboxy-
peptidase), and by brush border
enzymes (carboxypeptidase,
aminopeptidase, and dipeptidase)
of mucosal cells. 1
Absorptive
epithelial
cell
Na+
The amino acids are then
absorbed by active transport into
the absorptive cells, and move to
their opposite side. 2
Amino
acid
carrier
Capillary
© 2013 Pearson Education, Inc. 39

40. Amino acids of protein fragments
Figure Protein digestion and absorption in the small intestine.
Slide 4
Lumen
of intestine
Amino acids of protein fragments
Brush border enzymes
Pancreatic
proteases
Apical membrane (microvilli)
Na+
Proteins and protein fragments
are digested to amino acids by
pancreatic proteases (trypsin,
chymotrypsin, and carboxy-
peptidase), and by brush border
enzymes (carboxypeptidase,
aminopeptidase, and dipeptidase)
of mucosal cells. 1
Absorptive
epithelial
cell
Na+
The amino acids are then
absorbed by active transport into
the absorptive cells, and move to
their opposite side. 2
Amino
acid
carrier
The amino acids leave the villus
epithelial cell by facilitated diffusion
and enter the capillary via
intercellular clefts. 3
Capillary
© 2013 Pearson Education, Inc. 40

41. Figure 23. 32 Flowchart of digestion and absorption of foodstuffs
Figure Flowchart of digestion and absorption of foodstuffs. (2 of 4)
Foodstuff
Enzyme(s) and source
Site of action
Path of absorption
Proteins
Amino acids are absorbed via
cotransport with sodium ions.
Some dipeptides and tripeptides
are absorbed via cotransport with
H+ and hydrolyzed to amino acids
within the cells.
Infrequently, transcytosis of small
peptides occurs.
Amino acids leave the epithelial
cells by facilitated diffusion, enter
the capillary blood in the villi, and
are transported to the liver via the
hepatic portal vein.
Pepsin
(stomach glands)
in presence
of HCl
Stomach
Large polypeptides
Pancreatic
enzymes (trypsin,
chymotrypsin,
carboxypeptidase)
Small
intestine
Protein
digestion
Small polypeptides,
small peptides
Brush border
enzymes
(aminopeptidase,
carboxypeptidase,
and dipeptidase)
Small
intestine
Amino acids
(some dipeptides
and tripeptides)
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42. Pre-treatment—emulsification by bile salts Enzymes—pancreatic lipases
Digestion of Lipids
Pre-treatment—emulsification by bile salts
Does not break bonds
Enzymes—pancreatic lipases
 Fatty acids and monoglycerides
© 2013 Pearson Education, Inc.

43. with bile salts to form micelles which
Figure Emulsification, digestion, and absorption of fats.
Slide 1
Fat globule
Bile salts in the duodenum emulsify large fat globules (physically break them up into smaller fat droplets). 1
Bile salts
Digestion of fat by the pancreatic enzyme lipase yields free fatty acids and monoglycerides. These then associate
with bile salts to form micelles which
“ferry” them to the intestinal mucosa. 2
Fat droplets
coated with
bile salts
Micelles made up of fatty acids,
monoglycerides, and bile salts
Fatty acids and monoglycerides
leave micelles and diffuse into
epithelial cells. There they are
recombined and packaged with other
fatty substances and proteins to form
chylomicrons. 3
Chylomicrons are extruded from
the epithelial cells by exocytosis. The chylomicrons enter lacteals and are
carried away from the intestine in
lymph. 4
Epithelial
cells of
small
intestine
Lacteal
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44. Figure 23.34 Emulsification, digestion, and absorption of fats.
Slide 1
Fat globule
Bile salts in the duodenum emulsify large fat globules (physically break them up into smaller fat droplets). 1
Bile salts
Fat droplets
coated with
bile salts
© 2013 Pearson Education, Inc. 44

45. with bile salts to form micelles which
Figure Emulsification, digestion, and absorption of fats.
Slide 3
Fat globule
Bile salts in the duodenum emulsify large fat globules (physically break them up into smaller fat droplets). 1
Bile salts
Digestion of fat by the pancreatic enzyme lipase yields free fatty acids and monoglycerides. These then associate
with bile salts to form micelles which
“ferry” them to the intestinal mucosa. 2
Fat droplets
coated with
bile salts
Micelles made up of fatty acids,
monoglycerides, and bile salts
© 2013 Pearson Education, Inc. 45

46. with bile salts to form micelles which
Figure Emulsification, digestion, and absorption of fats.
Slide 4
Fat globule
Bile salts in the duodenum emulsify large fat globules (physically break them up into smaller fat droplets). 1
Bile salts
Digestion of fat by the pancreatic enzyme lipase yields free fatty acids and monoglycerides. These then associate
with bile salts to form micelles which
“ferry” them to the intestinal mucosa. 2
Fat droplets
coated with
bile salts
Micelles made up of fatty acids,
monoglycerides, and bile salts 3
Fatty acids and monoglycerides
leave micelles and diffuse into
epithelial cells. There they are
recombined and packaged with other
fatty substances and proteins to form
chylomicrons.
Epithelial
cells of
small
intestine
Lacteal
© 2013 Pearson Education, Inc. 46

47. with bile salts to form micelles which
Figure Emulsification, digestion, and absorption of fats.
Slide 5
Fat globule
Bile salts in the duodenum emulsify large fat globules (physically break them up into smaller fat droplets). 1
Bile salts
Digestion of fat by the pancreatic enzyme lipase yields free fatty acids and monoglycerides. These then associate
with bile salts to form micelles which
“ferry” them to the intestinal mucosa. 2
Fat droplets
coated with
bile salts
Micelles made up of fatty acids,
monoglycerides, and bile salts 3
Fatty acids and monoglycerides
leave micelles and diffuse into
epithelial cells. There they are
recombined and packaged with other
fatty substances and proteins to form
chylomicrons.
Chylomicrons are extruded from
the epithelial cells by exocytosis. The chylomicrons enter lacteals and are
carried away from the intestine in
lymph. 4
Epithelial
cells of
small
intestine
Lacteal
© 2013 Pearson Education, Inc. 47

48. Figure 23. 32 Flowchart of digestion and absorption of foodstuffs
Figure Flowchart of digestion and absorption of foodstuffs. (3 of 4)
Foodstuff
Enzyme(s) and source
Site of action
Path of absorption
Unemulsified triglycerides
Fatty acids and monoglycerides
enter the intestinal cells via
diffusion.
Fatty acids and monoglycerides are
recombined to form triglycerides
and then combined with other lipids
and proteins within the cells. The
resulting chylomicrons are
extruded by exocytosis.
The chylomicrons enter the lacteals
of the villi and are transported to
the systemic circulation via the
lymph in the thoracic duct.
Some short-chain fatty acids are
absorbed, move into the capillary
blood in the villi by diffusion, and
are transported to the liver via the
hepatic portal vein.
Lingual lipase
Mouth
Gastric lipase
Stomach
Emulsification by
the detergent
action of bile
salts ducted
in from the liver
Small
intestine
Fat
digestion
Pancreatic
lipases
Small
intestine
Monoglycerides (or diglycerides
with gastric lipase) and fatty acids
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49. Digestion of Nucleic Acids
Enzymes
Pancreatic ribonuclease and deoxyribonuclease  nucleotide monomers
Brush border enzyme nucleosidases and phosphatases  free bases, pentose sugars, phosphate ions
© 2013 Pearson Education, Inc.

50. Figure 23. 32 Flowchart of digestion and absorption of foodstuffs
Figure Flowchart of digestion and absorption of foodstuffs. (4 of 4)
Foodstuff
Enzyme(s) and source
Site of action
Path of absorption
Nucleic acids
Units enter intestinal cells by active
transport via membrane carriers.
Units are absorbed into capillary
blood in the villi and transported to
the liver via the hepatic portal vein.
Pancreatic ribo-
nuclease and
deoxyribonuclease
Small
intestine
Nucleic acid
digestion
Brush border
enzymes
(nucleosidases
and phosphatases)
Small
intestine
Pentose sugars,
N-containing bases,
phosphate ions
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51. ~ All food; 80% electrolytes; most water absorbed in small intestine
Absorption
~ All food; 80% electrolytes; most water absorbed in small intestine
Most prior to ileum
Ileum reclaims bile salts
Most absorbed by active transport  blood
Exception - lipids
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52. Absorption of Carbohydrates
Glucose and galactose
Secondary active transport (cotransport) with Na+  epithelial cells
Move out of epithelial cells by facilitated diffusion  capillary beds in villi
Fructose
Facilitated diffusion to enter and exit cells
© 2013 Pearson Education, Inc.

53. Absorption of Carbohydrates
Glucose and galactose
Secondary active transport (cotransport) with Na+  epithelial cells
Move out of epithelial cells by facilitated diffusion  capillary beds in villi
Fructose
Facilitated diffusion to enter and exit cells
© 2013 Pearson Education, Inc. 53

54. Amino acids transported by several types of carriers
Absorption of Protein
Amino acids transported by several types of carriers
Most coupled to active transport of Na+
Dipeptides and tripeptides actively absorbed by H+-dependent cotransport; digested to amino acids within epithelial cells
Enter capillary blood by diffusion
© 2013 Pearson Education, Inc.

55. Homeostatic Imbalance
Whole proteins not usually absorbed
Can be taken up by endocytosis/exocytosis
Most common in newborns  food allergies
Usually disappear with mucosa maturation
Allows IgA antibodies in breast milk to reach infant's bloodstream  passive immunity
© 2013 Pearson Education, Inc.

56. Absorption of Lipids Absorption of monoglycerides and fatty acids
Cluster with bile salts and lecithin to form micelles
Released by micelles to diffuse into epithelial cells
Combined with lecithin, phospholipids, cholesterol, & coated with proteins to form chylomicrons
Enter lacteals; transported to systemic circulation
Hydrolyzed to free fatty acids and glycerol by lipoprotein lipase of capillary endothelium
Cells can use for energy or stored fat
Absorption of short chain fatty acids
Diffuse into portal blood for distribution
© 2013 Pearson Education, Inc.

57. Absorption of Nucleic Acids
Active transport across epithelium  bloodstream
© 2013 Pearson Education, Inc.

58. Absorption of Vitamins
In small intestine
Fat-soluble vitamins (A, D, E, and K) carried by micelles; diffuse into absorptive cells
Water-soluble vitamins (vitamin C and B vitamins) absorbed by diffusion or by passive or active transporters.
Vitamin B12 (large, charged molecule) binds with intrinsic factor, and is absorbed by endocytosis
© 2013 Pearson Education, Inc.

59. Absorption of Vitamins
In large intestine
Vitamin K and B vitamins from bacterial metabolism are absorbed
© 2013 Pearson Education, Inc.

60. Absorption of Electrolytes
Most ions actively along length of small intestine
Iron and calcium are absorbed in duodenum
Na+ coupled with active absorption of glucose and amino acids
Cl– transported actively
K+ diffuses in response to osmotic gradients; lost if poor water absorption
Usually amount in intestine is amount absorbed
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61. Absorption of Electrolytes
Iron and calcium absorption related to need
Ionic iron stored in mucosal cells with ferritin
When needed, transported in blood by transferrin
Ca2+ absorption regulated by vitamin D and parathyroid hormone (PTH)
© 2013 Pearson Education, Inc.

62. 9 L water, most from GI tract secretions, enter small intestine
Absorption of Water
9 L water, most from GI tract secretions, enter small intestine
95% absorbed in the small intestine by osmosis
Most of rest absorbed in large intestine
Net osmosis occurs if concentration gradient established by active transport of solutes
Water uptake coupled with solute uptake
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63. Malabsorption of Nutrients
Causes
Anything that interferes with delivery of bile or pancreatic juice
Damaged intestinal mucosa (e.g., bacterial infection; some antibiotics)
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64. Malabsorption of Nutrients
Gluten-sensitive enteropathy (celiac disease)
Immune reaction to gluten
Gluten causes immune cell damage to intestinal villi and brush border
Treated by eliminating gluten from diet (all grains but rice and corn)
© 2013 Pearson Education, Inc.

65. Developmental Aspects
Oral membrane  mouth opening
Cloacal membrane  anus
By week 5 alimentary canal continuous tube from mouth to anus
Shortly after, accessory organs bud from mucosa
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66. Figure 23.36 Embryonic development of the digestive system.
Lung bud
Stomodeum
Brain
Foregut
Oral membrane
Liver
Stomach
Heart
Site of liver
development
Bile
duct
Yolk sac
Midgut
Spinal cord
Gall-
bladder
Dorsal
pancreatic
bud
Cloacal
membrane
Hindgut
Cystic duct
Duodenum
Body stalk
Ventral pancreatic bud
Proctodeum
Endoderm
© 2013 Pearson Education, Inc.

67. Homeostatic Imbalance
Cleft palate and cleft lip
Tracheoesophageal fistula
Opening between esophagus and trachea
Cystic fibrosis
Genetic disease  thick mucus  can block pancreatic duct
© 2013 Pearson Education, Inc.

68. Developmental Aspects
Fetal nutrition via placenta, but GI tract stimulated to mature by amniotic fluid swallowed in utero
Newborn's rooting reflex helps infant find nipple; sucking reflex aids in swallowing
Newborns double birth weight in six months; adult diet by 2 years
Cholecystitis, ulcers – problems of middle age
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69. Developmental Aspects
During old age
GI tract activity declines, less digestive juice, absorption less efficient, peristalsis slows  less frequent bowel movements
Taste/smell less acute; periodontal disease often develops
Diverticulosis, fecal incontinence, and cancer of GI tract fairly common
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70. Stomach and colon cancers rarely have early signs or symptoms
Metastasized colon cancers frequently cause secondary liver cancer
Prevention
Regular dental and medical examination
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