1. Ch. 23 The Digestive System

2. I. Basic Concepts & Processes Shared By Most Digestive Organs
A. Two Groups of Organs:
Alimentary canal =
Organs: Students Do
Accessory digestive organs =

3. B. Digestive Processes (Text p. 1040)
Ingestion
2. Propulsion
Peristalsis
3. Mechanical digestion
Mastication
Segmentation
4. Chemical digestion
5. Absorption
6. Defecation
Ingestion
Propulsion
Mechanical Digestion
Absorption
Defacation

4. Propulsion& Segmentation
From
mouth
(a) Peristalsis: successive waves of contraction move food distally (1-way).
(b) Segmentation: Food mixing/slow food propulsion occurs.
Figure 23.3

5. C. Control of Digestive Processes
Mechanical and Chemical stimuli STUDENTS DO
2. Nervous System Control:
a) Extrinsic: via CNS & autonomic nerves
Use long reflexes (brain to gut)
Intrinsic = Enteric Nerves
In digestive organs-- Use short reflexes
Submucosal nerve plexus: within submucosa
Myenteric nerve plexus within muscularis externa #3
• Myenteric nerve plexus
• Submucosal nerve plexus

6. 4. Hormonal Controls
Stomach
Gastrin:
Small Intestine
Secretin:
Cholecystokinin (CCK)

7. D. Blood Supply: Splanchnic Circulation
Branches of Abdominal Aorta
Students Do
Celiac Trunk
Superior mesenteric
Inferior mesenteric
Hepatic Portal Vein

8. E. Peritoneum Students Do
Peritoneum, Greater Omentum, Mesentery
Dorsal
mesentery
Parietal
peritoneum
Visceral
peritoneum
Ventral
mesentery
Peritoneal
cavity
Alimentary
canal organ
Liver
Figure 23.5a

9. F. Histology of Alimentary Canal
Mucosa
Epithelium
Lamina Propria
Areolar
Lympoid Follicles:
= collection of small lymphoid nodules
Part of MALT = Mucus-Associated
Muscularis Mucosae
Submucosa
Many vessels
Glands (Duodenal in s.i.)
Mucosa
Muscularis Muscosae
Lympoid Follicles

10. Lympathic tissue (Lymph Nodules in s.i.) Submucosal nerves plexus
3. Muscularis externa
Circular (inner)
Sphincters
Longitudinal
Myenteric nerve
4. Serosa = Visceral Peritoneum
Areolar
Mesothelium (simple squ.)
Submucosa

11. Histology of Alimentary Canal …#6
Glands in submucosa
Mucosa
• Epithelium
• Lamina propria
• Muscularis
mucosae
Submucosa
Muscularis
externa
• Longitudinal
muscle
• Circular muscle
Serosa
Nerve
Lumen
Gland in mucosa
• Epithelium
Artery
• Connective
tissue
Vein
Mucosa-associated
lymphoid tissue (MALT)
Lymphatic
vessel
Mesentery

12. II. Digestive System Organs of the Head and
II. Digestive System Organs of the Head and Thorax: Anatomy & Function A. The Mouth & Associated Organs
Students Do Following
1. Mouth Anatomy
Tissue Lining:
Palate: Hard &Soft
Uvula:
2. Overall Functions:
Ingestion, Mechanical Digestions
Chemical digestion: amylase
Swallowing (Deglutition)

13. 2. The Tongue STUDENTS DO Composition: Functions: 3 Bolus
Lingual Tonsil
Lingual Lipase

14. 3. The Salivary Glands Students Do 3 pairs of Glands Functions
Composition of
Saliva
1. Lubrication
2. hydration of food
3. chemical digestion
4. protection from microbes
(clinical medium)
Tongue
Parotid
gland
Parotid duct
Ducts of
sublingual
gland
Submandibular
duct
Masseter muscle
Sublingual
gland
Body of
mandible (cut)
Submandibular
gland

15. B. Pharynx Regions: Students Do Stratified squamous e.t.
skeletal muscle
Propulsion
Oropharynx
Laryngopharynx

16. C. Esophagus = propulsion only
Muscular tube
Esophageal hiatus
Upper & Lower Esophageal Sphincters (Lower = Gastroesophageal Sphincter)
Histology:
stratified
squamous

17. D. Digestive Processes: Mouth to Esophagus--SWALLOWING (Text p
D. Digestive Processes: Mouth to Esophagus--SWALLOWING (Text p. ) STUDENTS DO FOLLOWING
1) MOUTH: Voluntary (Buccal) Phase - tongue presses against hard palate; bolus oropharynx.
Bolus of food
Tongue
Pharynx
Epiglottis
Glottis
Trachea

18. Uvula Bolus Epiglottis Esophagus
2) Pharyngeal (-Esophageal) Phase: uvula and larynx block airways. Upper esophageal sphincter relaxes and pharynx muscles force bolus into esophagus. Upper esophageal sphincter closes
Figure 23.13, step 2

19. Gastroesophageal sphincter opens
Bolus
3) Esophageal Phase:. And Bolus moved to stomach by peristalsis; Gastroesophageal (a.k.a. cardiac) sphincter opens, food  stomach.
Figure 23.13, step 3

20. III. Digestive Organs of the Abdomen-Pelvis A. The Stomach: 1
III. Digestive Organs of the Abdomen-Pelvis A. The Stomach: Overall Functions a) Store Food b) Mechanical D. c) Chemical D. Proteins d) Intrinsic Factor 2. Gross Anatomy
Cardia
Fundus
Serosa
Body
Lesser
curvature
Rugae of
mucosa
a) Regions
Body
Cardia
Pyloric
Fundus
b) Rugae
Pyloric sphincter
Pyloric Region
Greater
curvature
Duodenum
Figure 23.14a

21. A. The Stomach … 2. Gross Anatomy …
Cardia
Fundus
c) Curvatures
Greater
Lesser
d) Sphincters
Cardiac
Pyloric
Serosa
Body
Lesser
curvature
Rugae of
mucosa
Pyloric sphincter
Pyloric Region
Greater
curvature
Duodenum
(a)
Figure 23.14a

22. Lesser omentum Greater omentum
2. Gross Anatomy …
e) Mesentaries
Lesser omentum
From liver to lesser curvature
Greater omentum
Drapes from greater curvature
Anterior to small intestine
Lesser omentum
Greater omentum

23. The Stomach: … Gross Anatomy …
Cardia
f) Muscular tunic has extra 3rd layer – inner most oblique layer = churning action
Slide: difficult to see; is thin
Fundus
Serosa
Body
Lesser
curvature
Rugae of
mucosa
Pyloric sphincter
(valve) at pylorus
Pyloric
canal
Greater
curvature
Pyloric
antrum
Duodenum
(a)
Figure 23.14a

24. 3. Microscopic Anatomy of the Stomach

25. ii) Gastric Pits lead to the  Gastric Glands which produce
3. Microscopic Anatomy of Stomach … a) Mucosa i) Simple Columnar E.T. in loops w/ Goblet cells
Esophagus
ii) Gastric Pits lead to the 
Gastric Glands which produce
Gastric Juice– mostly from Fundus and Body
iii) Cells of Gastric Glands
Muscus Neck Cells
Alkaline mucus– bicarbonate rich
Function: protect cells from pH1.5 – 3.5 gastric juice
In all stomach regions
Stomach
Gastric Pits
Mucous neck cells
Gastric Glands
Figure 23.12b

26. STOMACH

27. a) Mucosa iii) Gastric Gland Cells …
Gastric pits
Gastric
pit
Parietal Cells
Function: Hydrochloric Acid (HCl) for activation of enzyme pepsinogen and intrinsic factor for B12 absorption in small intestine)
HCl also kills bacteria
Slide: Round, large, pinkish cells
Surface epithelium
(mucous cells)
Gastric
gland
Mucous neck cells
Pepsinogen
Pepsin
Parietal cell
HCl
Chief cell
Enteroendocrine cell
(b) Enlarged view of gastric pits
and gastric glands

28. a) Mucosa iii) Gastric Gland Cells …
Gastric pits
Gastric
pit
Chief Cells
Function: produce enzyme Pepsinogen
HCl Activates it to Pepsin
Most numerous cells
Slide: Small, purplish cells
Enteroendocrine cells
G cells:
Function: produce hormones Gastrin, Histamine which promote secretion of gastric juices w/ HCl and Pepsinogen
Surface epithelium
(mucous cells)
Gastric
gland
Mucous neck cells
Parietal cell
Chief cell
Enteroendocrine cell
(b) Enlarged view of gastric pits
and gastric glands

29. Stomach

30. 4. Digestive Processes Occurring in the Stomach
a) Introduction
i) Secretions: Up to 3L gastric juices per day secreted
ii) Nervous Control:
Parasympathetic NS via Vagus Nerve: stimulates glands
Sympathetic NS: depress secretary action
Enteric Plexuses
iii) Hormonal Control
Gastrin, most important hormone
Stimulates secretion of enzymes, HCl, & intestinal enzymes
iv) Stimulus: Head, Stomach, and Small Intestine

31. 4. Digestive Processes occurring in the Stomach …
b. Regulation of Gastric Secretion
3 Phases
i) Cephalic (reflex) phase: a few min.
Gets stomach ready for digestive processes
Long Reflexes from CNS to Enteric Ganglia
Conditioned Reflex
Stimulatory events
Cephalic
phase
Sight and thought
of food 1
Cerebral cortex
Conditioned reflex
Stimulation of
taste and smell
receptors 2
Hypothalamus
and medulla
oblongata
Vagus
nerve
Stomach
secretory
activity
Figure 23.17
(1) Sight and Thoughts  Hypothalamus  Medulla nuclei
 Vagus Nerve  Ach/Stomach  increased secretions

32. a. Cephalic Phase …
(2) Taste and Smell  Hypothalamus  Medulla vagal nuclei  vagus nerve  Ach/ stomach  ↑ secretion of gastric juices
Inhibitory Events: From Cerebrum-- Depressed or not hungry then  Parasympathetic NS. Not stimulated  Cephalic Phase inhibited
Stimulatory events
Cephalic
phase
Sight and thought
of food 1
Cerebral cortex
Conditioned reflex
Stimulation of
taste and smell
receptors 2
Hypothalamus
and medulla
oblongata
Vagus
nerve
Stomach
secretory
activity
Figure 23.17
Figure 23.17

33. b. Gastric Phase– 3-4 hours, after food first enters stomach
2. Regulation of …
b. Gastric Phase– 3-4 hours, after food first enters stomach
Produces 2/3 gastric juice produced
Stomach distention  Myenteric Reflex (local)  AND
Vagovagal Reflex = 
(2) Food Chemicals (proteins) & Rising pH  Chemoreceptors  activate G cells (enteroendocrine cells)  Gastrin (hormone)  increased HCl secretion by Parietal Cells
 Vagus  Medulla  Vagus 
at Stomach AcH released  increased gastric juices
Stimulatory events
Inhibitory events
Stomach
distension
activates
stretch
receptors 1
Vagovagal
reflexes
Medulla
Vagus
nerve
Gastrin
secretion
declines
G cells
1. Excessive
acidity
(pH <2)
in stomach
Excessive
acidity
(pH <2)
in stomach 1
Stomach
distension
activates
stretch
receptors 1
Vagovagal
reflexes
Medulla
Vagus
nerve
Gastrin
secretion
declines
G cells
Gastric
phase
Local
reflexes
Overrides
parasym-
pathetic
controls
Sympathetic
nervous
system
activation
Emotional
upset 2
Ach
Local
reflexes
Overrides
parasym-
pathetic
controls
Sympathetic
nervous
system
activation
2. Emotional
upset
Food chemicals
(especially peptides and
caffeine) and rising pH
activate chemoreceptors 2
G cells
Gastrin
release
to blood
Food chemicals
(especially peptides and caffeine) and rising pH activate chemoreceptors 2
G cells
Gastrin
release
to blood
Stomach
secretory
activity
Stomach
secretory
activity
Stimulate
Entero-
gastric
reflex
Local
reflexes 1
Inhibit
Figure 23.17
Presence

34. Negatie Feedback Loop:
(2) Food Chemicals …
The increase in acidity activates pepsinogen to pepsin so that proteins can be digested
Inhibitory Events
Negatie Feedback Loop:
Acidity: Low H+ (High pH) stimulates release of Gastrin
High H+ (low pH) inhibits release of Gastrin
Emotional distress– activates sympathetic N.S.
Stimulatory events
Inhibitory events
Stomach
distension
activates
stretch
receptors 1
Vagovagal
reflexes
Medulla
Vagus
nerve
Gastrin
secretion
declines
G cells
Excessive
acidity
(pH <2)
in stomach 1
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
upset 2
Ach
Local
reflexes
Overrides
parasym-
pathetic
controls
Sympathetic
nervous
system
activation
Emotional
upset 2
Food chemicals
(especially peptides and
caffeine) and rising pH
activate chemoreceptors 2
Stimulate
G cells
Gastrin
release
to blood
Food chemicals
(especially peptides and
caffeine) and rising pH
activate chemoreceptors 2
G cells
Gastrin
release
to blood
Inhibit
Stomach
secretory
activity
Stomach
secretory
activity
Entero-
gastric
reflex
Local
reflexes 1
Figure 23.17
Presence

35. c. Intestinal Phase In Duodenum
Begins when stomach begins to empty chyme to duodenum
Two parts: Excitatory and Inhibitory
EXCITATORY PART
Brief effect
(1) Partially digested food (including fats), low pH, & hypertonic solution  release Intestinal Gastrin  Stomach glands continue to secrete gastric fluids briefly
Stomach
secretory
activity
Stimulatory events
Presence of low
pH, partially digested
foods, fats, or
hypertonic solution
in duodenum when
stomach begins to
empty 1
Intestinal
(enteric)
gastrin
release
to blood
Intestinal
phase
Brief
effect
Stimulate
Figure 23.17
Inhibit

36. (2) Distension of Duodenum, …  Release of intestinal Hormones
c. Intestinal Phase …
INHIBITORY PART
Distension of Duodenum, very low pH, fats, part dig. proteins, & irritants  Enterogastric Reflex inhibits gastric secretion and closes the Pyloric Sphincter
Function: to move a small bit of chyme into duodenum and to protect it from over-distension
(2) Distension of Duodenum, …  Release of intestinal
Hormones
Cholecystokinin (CCK)
Secretin
TO BE CONTINUED
UNDER SM. INTESTINE
Figure 23.17
Intestinal Phase …
Stomach
secretory
activity
Inhibitory events
Entero-
gastric
reflex
Local
reflexes
Distension
of duodenum;
presence of
fatty, acidic,
hypertonic
chyme, and/or
irritants in
the duodenum 1
Vagal
nuclei
in medulla
Pyloric
sphincter
Release of intestinal
hormones (secretin,
cholecystokinin, vasoactive
intestinal peptide)
Distension;
presence of
fatty, acidic,
partially
digested food
in the
duodenum 2
Stimulate
Inhibit

37. B. Small Intestine 1. Gross Anatomy 2–4 m long; Subdivisions
Duodenum– 10 inches
Jejunum– 8 feet
Ileum– 12 feet
Duodenum
Most chemical dig. & absorption occurs here
Receives bile from liver & enzymes and bicarbonate from pancreas
Small
intestine
Duodenum
Jejunum
Ileum

38. ii) Plicae Circulares—deep folds of mucosa and submucosa
a. Duodenum …
i) Hepatopancreatic Ampulla: Bulb-like point where Bile duct & main pancreatic duct join
Major Duodenal Papilla: Volcano-shaped opening into Duodenum H. Ampulla attached and releases contents to Papilla  Duodenum
Hepatopancreatic Sphincter: at Ampulla/Papilla junction
ii) Plicae Circulares—deep folds of mucosa and submucosa
Bile duct and sphincter
Major duodenal
papilla
Plicae Circulares
Main pancreatic duct
and sphincter
Hepatopancreatic
ampulla and sphincter
Duodenum

39. Jejunum
Attached to Duodenum
Location In central and lower part of Abdominal Cavity
Coiled
Ileum
Attached to Jejunum
Location– same
Both framed by Large Intestine

40. 2. Microscopic Anatomy Small Intestine

41. a. Mucosa w/ folds & loops
2. Microscopic Anatomy …
a. Mucosa w/ folds & loops
i) Villi—loops of mucosa (epithelia = scattered goblets among absorptive cells)
Blood vessels, nerves, and lacteal
Cells with Microvilli: small loops at apical side of cells; form brush border
Digestive Enzymes embedded in microvilli
Function of folds and loops:

42. Small Intestine

43. ii) Intestinal Glands (Crypts) in Mucosa = tubular glands b/n villi
2. Microscopic Anatomy …
ii) Intestinal Glands (Crypts) in Mucosa = tubular glands b/n villi
Secretory cells epithelium produce intestinal juice: water, some mucus, slightly alkaline (pH = ) and low in enzymes
Enteroendocrine cells (secrete CCK, secretin among others)
iii) Lamnia Propria
- agregations of intestinal nodules (MALT)
Absorptive cells
Goblet cell
Lacteal
Vilus
Intestinal crypt
Enteroendocrine
cells
Venule
Lymphatic vessel
Submucosa
Duodenal gland

44. b) Submucosa of small intestine Areolar Tissue
Peyer’s patches = aggregated lymphoid follicles; increase towards end sm. int. They protect distal areas against bacteria
Have lymphocytes
Duodenal (Brunner’s) glands: of duodenum secrete alkaline (bicarbonate)mucus to neutralize the acidic chime coming in from stomach
c. Muscularis Externa
d. Serosa
Submucosa
Duodenal gland
Peyer’s Patches

46. Small Intestine

47. END PPT
 NEXT FILE

48. Review Questions
The mucosa of the lower pharanx and esophagus has _________ __________ epithelia.
___________, i.e. swallowing, involves over 22 muscle groups and moves a _________ from the oral cavity to the stomach.
stratified squamous
Deglutition
bolus

49. Review Questions amylase
Enzymes in saliva include _________, which is responsible for starch breakdown.
2I, 1C, 2PM, 3M

50. enteric nerve plexuses
Review Questions
Short reflexes of the GI tract are housed and completed within _____ ____ ______ while _______ reflexes involve the CNS.
enteric nerve plexuses
long

51. Review Questions
In the small intestine, ___________ __________, __________, and ___________ all contribute to expanding the surface area for adequate __________.
plicae circulares
villi
microvilli
absorption

52. Review Questions
From the esophagus to the anus, the GI tract contains how many layers?
Which 2 layers contain smooth muscle?
4: mucosa, submucosa, muscularis externa, serosa
Mucosa & muscularis externa

53. Participating… gastric
The _________ phase is responsible for the production of most gastric secretions by releasing the hormone _________.
What other 2 hormones promote gastric secretions?
gastrin
ACh and Histamine

54. Review Questions Parietal gastric
________ cells of _______ glands produce HCl and ___________ __________. __________ cells produce pepsinogen.
What is intrinsic factor for?
intrinsic factor
Chief
B12 absorption

55. Figure 23.17 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
upset 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,
hypertonic
chyme, and/or
irritants in
the duodenum 1
Presence of low
pH, partially digested
foods, fats, or
hypertonic solution
in 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 intestinal
hormones (secretin,
cholecystokinin, vasoactive
intestinal peptide)
Distension;
presence of
fatty, acidic,
partially
digested food
in the
duodenum 2
Stimulate
Inhibit
Figure 23.17

56. Figure 23.17 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
upset 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,
hypertonic
chyme, and/or
irritants in
the duodenum 1
Presence of low
pH, partially digested
foods, fats, or
hypertonic solution
in 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 intestinal
hormones (secretin,
cholecystokinin, vasoactive
intestinal peptide)
Distension;
presence of
fatty, acidic,
partially
digested food
in the
duodenum 2
Stimulate
Inhibit
Figure 23.17

57. b) Intrinsic = Enteric Nervous System (Gut Brain)
CNS is linked via extrinsic long ANS fibers
Intrinsic nerve plexuses
• Myenteric nerve plexus
• Submucosal nerve plexus

58. Gingivae (gums)
Hard palate
Soft palate
Uvula
Posterior wall
of oropharynx
Palatine tonsil

59. 100 million bacteria/mL of saliva!
Serous & Mucous Cells
Water content
Enzyme =
Mucin
Control of Salivation:
Parasym. Sys. via chemo-
& mechano-receptors
100 million bacteria/mL of saliva!

60. Hiatal hernia

61. Homeostatic Imbalance
Peptic or gastric ulcers: erosion of stomach wall
Helicobacter pylori bacteria
Bacteria
Mucosa
layer of
stomach
(a) A gastric ulcer lesion
(b) H. pylori bacteria

62. Regulation of Gastric Secretion
Figure 23.17
Stimulatory events
Inhibitory events
Sight and thought
of food 1
Cephalic
phase
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
upset 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,
hypertonic
chyme, and/or
irritants in
the duodenum 1
Presence of low
pH, partially digested
foods, fats, or
hypertonic solution
in 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 intestinal
hormones (secretin,
cholecystokinin, vasoactive
intestinal peptide)
Distension;
presence of
fatty, acidic,
partially
digested food
in the
duodenum 2
Stimulate
Inhibit

63. Regulation of Gastric Secretion
Stimulatory events
Inhibitory events
Sight and thought
of food 1
Cerebral cortex
Lack of
stimulatory
impulses to
parasym-
pathetic
center
Cerebral
cortex
Loss of
appetite,
depression 1
Cephalic
phase
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
upset 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,
hypertonic
chyme, and/or
irritants in
the duodenum 1
Presence of low
pH, partially digested
foods, fats, or
hypertonic solution
in 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 intestinal
hormones (secretin,
cholecystokinin, vasoactive
intestinal peptide)
Distension;
presence of
fatty, acidic,
partially
digested food
in the
duodenum 2
Stimulate
Inhibit
Figure 23.17

64. 3. Gastric Motility & Emptying
Stretch-Relaxation Response: Relaxes to recieve food, then contracts
Contractile Activity: Pacemaker cells (in smooth muscle) initiate bi-directional peristalsis 3X a min = BER (basic electrical rhythm)
Stimulated by neural and hormonal factors
Stomach & Duodenum coordinated: 3 mL chyme  duodenum/time
Emptying time: 4 hours normally, if much fat up to 6 hours
each
Pyloric
valve
closed
Pyloric
valve
slightly
opened
3. Retropulsion: Small amounts of chyme enter duodenum, most moves backward = more mixing
1 Propulsion: Peristaltic waves move from fundus toward pylorus.
2. Grinding: Most vigorous peristalsis/ mixing action occur near pylorus.
Figure 23.19