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Chapter 24: The Digestive System

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Title: Chapter 24: The Digestive System


1
Chapter 24 The Digestive System
  • BIO 211 Lecture
  • Instructor Dr. Gollwitzer

2
  • Today in class we will
  • Describe the general functions of the digestive
    system
  • Discuss how enzymes work
  • Discuss the movement of digestive materials
    through the digestive tract
  • Discuss the mechanisms that control digestive
    functions
  • Begin our discussion on the major functions of
    the organs, regions and anatomical structures of
    the digestive tract
  • Oral cavity
  • Tongue
  • Saliva
  • Mastication
  • Pharynx
  • Deglutition
  • Swallowing reflex
  • Esophagus
  • Stomach
  • Secretory structures and secretions

3
Components and Primary Functions
Figure 24-1
4
Digestive System
  • Provides fuel that keeps body running
  • Glucose
  • ATP
  • Provides building blocks needed for cell growth
    and repair
  • Monosaccharides (carbohydrates, CHOs)
  • Amino acids (proteins)
  • Monoglycerides and fatty acids (lipids)

5
Functions of the Digestive System
  • Ingestion
  • Mechanical processing
  • Digestion
  • Secretion
  • Absorption
  • Excretion

6
Functions of the Digestive System
  • Ingestion
  • Entry of materials into digestive tract via mouth

7
Functions of the Digestive System
  • Mechanical processing
  • Crushing/shearing of food
  • Makes materials easier to move along GI tract
  • Increases surface area of available to enzymes
  • May/may not be required before ingestion
  • Not for liquids
  • For solids
  • Teeth- tear, mash food (mastication)
  • Tongue squashes, compacts food
  • Stomach and intestines swirl, mix, churn

8
Functions of the Digestive System
  • Digestion
  • Chemical breakdown of food into small organic
    fragments that can be absorbed by digestive
    epithelium
  • Simple molecules absorbed intact, e.g., glucose
  • Larger molecules must be broken down by digestive
    enzymes (e.g., polysaccharides, proteins,
    triglycerides)

9
Functions of the Digestive System
  • Secretion
  • Release of water, acids, enzymes, buffers,
    salts into digestive tract
  • By
  • Digestive tract epithelium
  • Glandular organs, e.g., pancreas
  • Into digestive tract

10
Functions of the Digestive System
  • Absorption
  • Movement of organic substrates, electrolytes
    (ions), vitamins, water
  • Across digestive epithelium and into interstitial
    fluid around digestive tract
  • Surface area greatly increased by folds in lining
    of digestive tract

11
Functions of the Digestive System
  • Excretion
  • Digestive tract and glandular organs ? waste
    products into lumen of tract
  • Waste mixes with indigestible residue of
    digestive process
  • Leaves body as feces eliminated through
    defecation

12
Lining of the Digestive Tract
  • Protects surrounding tissues against
  • Corrosion from digestive acids and enzymes
  • Mechanical stresses, abrasion
  • Bacteria swallowed with food that are found
    naturally in digestive tract

13
Enzymes
  • Are catalysts
  • Proteins that lower the activation energy of a
    chemical reaction
  • Not changed or used up in the reaction

14
How Enzymes Work
Figure 221
15
Movement of Digestive Materials
  • By smooth muscle layers of digestive tract
  • Pacesetter cells
  • Smooth muscle cells in
  • Muscularis mucosae
  • Muscularis externa
  • Contract spontaneously
  • Trigger rhythmic waves of contraction that spread
    through digestive tract

16
Figure 24-3
17
Movement of Digestive Materials
  • Muscularis externa
  • Involved in
  • Peristalsis
  • Segmentation

18
Movement of Digestive Materials
  • Peristalsis
  • Waves of muscular contractions
  • Move bolus (small, oval mass of digestive
    contents) along GI tract
  • Process
  • Circular muscles behind bolus contract, while
    circular muscles ahead of bolus relax
  • Longitudinal muscles ahead of bolus contract
    (shortens adjacent segments)
  • Bolus forced forward

19
Figure 24-4, 7th edition
20
Movement of Digestive Materials
  • Mass movements
  • Powerful peristaltic contractions
  • Move GI contents from transverse colon through
    rest of large intestine (? bowel movements)

21
Movement of Digestive Materials
  • Segmentation
  • Regional mechanical processing (e.g., haustral
    churning in large intestine)
  • Cycles of contractions
  • Churn and break up the bolus
  • Mix contents with intestinal secretions
  • Not a set pattern so does not push materials
    along tract

22
Control of Digestive Functions
  • Regulated by 3 types of mechanisms
  • Neural
  • Hormonal
  • Local

23
Figure 24-5, 7th edition
24
Neural Mechanisms
  • Control
  • Movement of materials along digestive tract
  • Local peristaltic movements
  • Control small segments (via short reflex to
    myenteric plexus)
  • Large-scale peristaltic waves
  • Control movement from one region of digestive
    tract to another (via long reflex to CNS)
  • Digestive gland secretions
  • Exocrine secretory cells ? buffers, acids,
    enzymes
  • Enteroendocrine cells ? hormones

25
Hormonal Mechanisms
  • Via hormones produced by digestive tract
  • Hormones
  • Are peptides (e.g., gastrin, secretin,
    cholecystokinin CCK, gastric inhibitory peptide
    GIP)
  • Produced by enteroendocrine cells in stomach
    (gastrin) or duodenum (secretin, CCK, GIP)
  • Target cells in stomach, small intestine, liver,
    pancreas
  • Reach targets via bloodstream
  • Affect every aspect of digestive function
  • Can stimulate or inhibit smooth muscle cells
    responses to neural commands

26
Local Mechanisms
  • Via local factors, e.g.,
  • pH, chemical messengers, e.g., prostaglandins,
    histamine
  • Coordinate response to local conditions
  • Affect only that portion of tract, e.g.,
  • Lamina propria of stomach releases histamine ?
    secretion of HCl by parietal cells

27
Oral Cavity
  • Tongue
  • Functions
  • Mechanical processing - compresses, abrades food
  • Manipulation assists in chewing, preparing
    material for swallowing
  • Sensory analysis - by touch, temperature, taste
    receptors
  • Secretion
  • Mucins ? mucous layer
  • Lingual lipase ? breaks down lipids

28
Oral Cavity
  • Saliva
  • Produced by 3 pairs of salivary glands
  • Submandibulars ? 70
  • Parotids ? 25
  • Sublinguals ? 5
  • Components
  • Water ? 99.4
  • Remaining 0.6
  • Electrolytes (Na, Cl, HCO3)
  • Buffers ? pH near 7.0
  • Glycoproteins (mucins) ? lubricating action
  • Antibodies and digestive enzymes help control
    oral bacteria

29
Oral Cavity
  • Saliva (continued)
  • Functions
  • Lubricates mouth and materials in it
  • Dissolves chemicals that stimulate taste buds
  • Initiates digestion
  • Of complex carbohydrates via salivary amylase
  • Of lipids via lingual lipase (from tongue glands)
  • Control of secretions
  • By ANS
  • Secretions increased by
  • Chewing with empty mouth
  • Smell of/thinking about food
  • Irritating/unpleasant stimuli, nausea

30
Oral Cavity
  • Mastication (chewing)
  • Combination of mandibular movements by muscles of
    mastication (elevation/depression, protraction/
    retraction, medial/lateral movement)
  • Forces food back and forth across oral cavity
    also involves muscles of cheeks, lips, tongue
  • Ingested material shredded and moistened with
    salivary secretions
  • Tongue compacts food into bolus
  • Compact, moist bolus easy to swallow
  • No nutrients absorbed in oral cavity
  • But lipid-soluble drugs can dissolve, e.g.,
    nitroglycerine

31
Pharynx
  • Shared passage for food and air
  • Connects nasal and oral passages to respiratory
    and digestive systems, respectively
  • Lymphoid tissue (tonsils) contributes to bodys
    defense system
  • Muscles cooperate with muscles of oral cavity and
    esophagus to initiate deglutition (swallowing)

32
Pharynx
  • Deglutition
  • Complex process
  • Control
  • Initiation voluntary but proceeds involuntarily
  • Also occurs unconsciously as result of saliva
    collecting at back of mouth
  • Occurs approximately every 40 seconds

33
Pharynx
  • Deglutition (continued)
  • Swallowing reflex
  • Begins when bolus stimulates tactile receptors on
    posterior palate
  • Info relayed to swallowing center in brain ?
    motor commands to
  • Larynx ? epiglottis covers entrance to airway
    (glottis)
  • Uvula and soft palate ? block backward passage
  • Pharyngeal muscles ? propel bolus into esophagus

34
Figure 24-11
35
Esophagus
  • Primary function
  • Carries solid food and liquids to stomach from
    oral cavity and pharynx
  • Bolus pushed through esophagus/toward stomach by
    peristaltic wave (under CNS control)
  • Approach of bolus triggers esophageal sphincter
    and bolus enters stomach
  • Transit time through esophagus
  • Liquids 2 sec
  • Bolus 9 sec
  • Dry or poorly lubricated bolus much slower, may
    need second peristaltic wave to push into stomach

36
Stomach
  • Primarily a holding tank
  • Food saturated with gastric juices, exposed to
    stomach acids, and digestive effects of enzyme
    pepsin
  • Preliminary digestive steps occur here
  • Can distend a lot as it receives food because of
    rugae (temporary folds)

37
Stomach
  • 4 major functions
  • Storage of ingested food
  • Mechanical breakdown of ingested food
  • Disruption of chemical bonds in food through
    actions of acids/enzymes
  • Production of intrinsic factor
  • Glycoprotein required for vitamin B12 absorption
    in small intestine
  • Essential for hematopoiesis and synthesis of bone
    proteins
  • Only essential function of stomach

38
Stomach
  • Produces chyme
  • Viscous, acidic soupy mixture of partially
    digested food
  • Formed from ingested substances stomach gland
    secretions
  • Has extra layers of muscle to assist in
    churning/mixing
  • Muscularis mucosae outer, circular layer
  • Muscularis externa inner, oblique layer

39
Stomach
  • Secretory sheet
  • Simple columnar epithelium that covers surface
  • Produces alkaline mucous layer
  • Protects epithelial cells against acids and
    enzymes in gastric lumen
  • Gastric pits
  • Openings to gastric glands
  • Open onto gastric surface

40
Figure 24-13
41
Gastric Glands
  • In stomach fundus and body
  • ? gastric juice with enzymes and acid
  • 2 types of secretory cells
  • Parietal cells
  • Chief cells

42
Parietal Cells
  • Produce
  • Intrinsic factor
  • Required for absorption of vitamin B12
  • Required for synthesis of bone proteins and
    hematopoiesis
  • HCl
  • Keeps stomach contents at pH 1.5 2
  • Does not digest chyme
  • Kills most microorganisms in food
  • Denatures protein and inactivates most enzymes in
    food
  • Breaks down plant cell walls and CT in meat
  • Low pH essential for production of pepsin
    protein digesting enzyme

43
HCl
  • Very strong acid
  • H and Cl- transported separately into stomach
    lumen by different mechanisms
  • Otherwise would destroy cell
  • H2O CO2 ?? H2CO3 ?? HCO3- H
  • H actively transported into lumen of gastric
    gland in stomach
  • HCO3- moves into interstitial fluid in exchange
    for Cl- which diffuses across cell and exits into
    lumen of gastric gland in stomach
  • H and Cl- ? HCl in stomach lumen

44
Figure 24-14
45
Chief Cells
  • Produce
  • Enzymes important for digesting milk in newborns
  • Rennin coagulates milk proteins
  • Gastric lipase initiates digestion of milk fats
  • Pepsinogen
  • Inactive proenzyme
  • Converted to pepsin (active proteolytic/
    protein-digesting enzyme) by HCl

46
Pyloric Glands
  • In stomach pylorus
  • 2 Types of glands
  • Mucus-secreting cells/glands ? mucous secretion
  • Enteroendocrine glands ? hormones
  • e.g., G cells ? gastrin that stimulates
  • Secretion by parietal and chief cells
  • Contractions of gastric wall that mix/stir
    gastric contents

47
Figure 24-13
48
Peptic Ulcers
  • Result from
  • Excessive acid production
  • Inadequate production of alkaline mucus that
    protects epithelium from acid
  • Digestive acids and enzymes erode
  • Lining of stomach (gastric ulcer)
  • Proximal small intestine (duodenal ulcer)
  • 80 caused by gastric bacterial infection by
    Heliobacter pylori (H. pylori)
  • Treat with antibiotic drugs that inhibit acid
    production

49
  • Today in class we will
  • Continue our discussion on the major functions of
    the organs, regions and anatomical structures of
    the digestive tract
  • Stomach
  • Regulation of gastric secretory activity
  • Cephalic, gastric and intestinal phases,
    associated events, mechanisms and hormones
  • Digestion and absorption
  • Small intestine
  • Digestion, nutrient absorption and associated
    structures
  • Surface characteristics
  • Intestinal secretions and associated structures
  • Intestinal movements
  • Emesis
  • Associated glandular organs (Pancreas, liver and
    gallbladder)
  • Mechanisms that coordinate digestive glands
  • Coordination of absorption

50
Regulation of Gastric Secretory Activity
  • Gastric secretions
  • HCl
  • Enzymes
  • Controlled via production of
  • Hormones (e.g., G cells ? Gastrin)
  • HCl (by parietal cells)
  • Enzymes (e.g., chief cells ? pepsinogen)
  • Involves three overlapping phases
  • Cephalic phase
  • Gastric phase
  • Intestinal phase

51
Regulation of Gastric Activity
Figure 24-15
52
Regulation of Gastric Secretory Activity
  • Phases named for location of control center
  • Cephalic phase
  • Controlled by CNS (brain and spinal cord)
  • Gastric phase
  • Regulated by short reflexes of ANS
  • i.e.,enteric nervous system (ENS) within
    parasympathetic sytem
  • Involves submucosal and myenteric plexuses
  • Coordinated in stomach wall
  • Intestinal phase
  • Regulated by intestinal hormones (e.g. CCK, GIP,
    secretin) from enteroendocrine cells

53
Cephalic Phase
  • Directed by CNS
  • Prepares stomach to receive food
  • Begins when you see, smell, think about food
  • Exaggerated by anger/hostility
  • Inhibited by anxiety, stress, fear
  • Short duration (minutes)

54
Cephalic Phase
  • Stimulates CNS ? ANS (parasympathetic) ? vagus
    nerve (CN X) ? submucosal plexus of stomach ?
    innervates mucous, parietal, chief, G cells of
    stomach
  • Increases production of gastric juice by
    stimulation of
  • Mucous cells ? mucus
  • Chief cells ? pepsinogen (? pepsin)
  • Parietal cells ? HCl
  • Stimulates G cells ? gastrin

55
Regulation of Gastric Activity
Figure 24-15
56
Gastric Phase
  • Regulated by short reflexes of ENS
  • Begins with arrival of food in stomach
  • Long duration (3-4 hours)
  • Purpose of this phase
  • Enhances secretions started in cephalic stage
  • Homogenizes and acidifies chyme
  • Initiates protein digestion by pepsin
  • 3 mechanisms
  • Neural
  • Hormonal
  • Local

57
Gastric Phase
  • Neural mechanism
  • Short reflexes triggered by
  • Stomach distention that stimulates stretch
    receptors
  • Increased pH of gastric contents that stimulates
    chemoreceptors (also stimulated by proteins,
    alcohol, and caffeines)
  • Receptors stimulate ENS (submucosal and myenteric
    plexuses) which then stimulates
  • Mucous cells ? mucus
  • Chief cells ? pepsinogen
  • Parietal cells ? HCl
  • Mixing waves in muscularis externa

58
Gastric Phase
  • Hormonal mechanism
  • G cells ? gastrin, stimulated by
  • ENS (see previous)
  • Partially digested proteins in chyme
  • Gastrin (via system circulation) stimulates
  • Chief cells ? pepsinogen
  • Parietal cells ? HCL
  • Mixing waves in muscularis externa of stomach and
    intestinal tract

59
Gastric Phase
  • Local mechanism
  • Filling stomach stimulates mast cells in CT of
    lamina propria ? histamine which stimulates
    parietal cells ? HCl

60
Regulation of Gastric Activity
Figure 24-15
61
Intestinal Phase
  • Begins when chyme enters small intestine (after
    several hours of gastric mixing)
  • Long duration (hours)
  • Purpose of this phase
  • Controls rate of gastric emptying (entry of chyme
    into duodenum)
  • Pylorus contracts
  • Small quantity of chyme squirts through pyloric
    sphincter into small intestine
  • Ensures small intestine functions efficiently
    (secretion, digestion, absorption)
  • Triggers events that affect/coordinate activities
    of stomach (generally inhibits its activity),
    intestinal tract, pancreas, liver, gallbladder

62
Intestinal Phase
  • Neural mechanisms
  • Chyme distends duodenum, stimulates
  • Stretch receptors
  • Chemoreceptors
  • Receptors trigger
  • Enterogastric reflex (to myenteric plexus)
  • Inhibits gastrin production and gastric
    contractions
  • Contracts pyloric sphincter
  • Prevents further discharge of chyme into duodenum
  • Local reflexes ? increase mucous production ?
    protects duodenal lining from acids/enzymes

63
Intestinal Phase
  • Hormonal mechanisms
  • Presence of lipids and carbohydrates ? secretion
    of hormones by enteroendocrine cells in duodenum
  • Cholecystokinin (CCK) ? decreases gastric
    acid/enzyme secretion
  • Gastric inhibitory peptide (GIP) ? decreases
    gastric secretions, contraction
  • Partially digested proteins stimulate G cells in
    duodenum ? gastrin ? stomach ? increase acid and
    enzyme production (feedback mechanism)

64
Intestinal Phase
  • Hormonal mechanisms (continued)
  • pH lt 4.5 stimulates enteroendocrine cells ?
    secretin ?
  • Inhibits chief cells
  • Inhibits parietal cells
  • Stimulates pancreas ? buffers that protect
    duodenum by neutralizing acid in chyme (inc pH)
  • Stimulates liver ? bile secretion

65
Regulation of Gastric Activity
Figure 24-15
66
Digestion in Stomach
  • At pH gt 4.5 (first 1-2 hours post meal)
  • Proteins preliminary digestion by pepsin
  • Carbohydrates (by salivary amylase) and lipids
    (by lingual lipase) digestion permitted until
    pHlt4.5
  • At pH lt 2
  • Pepsin increases ? protein digestion begun but
    not completed (limited time)
  • Complex proteins ? smaller peptides and
    polypeptide chains

67
Absorption in Stomach
  • No nutrients
  • Epithelial cells covered in mucous, so not
    directly exposed to chyme
  • Epithelial cells lack specialized transport
    mechanisms
  • Gastric lining impermeable to water
  • Digestion not completed
  • Alcohol
  • Lipid soluble diffuses through mucous, enters
    lipid membranes of epithelial cells
  • Some drugs
  • Aspirin - lipid soluble
  • Prolonged use ? gastric bleeding

68
Small Intestine
  • Plays key role in
  • Digestion
  • Nutrient absorption
  • Water absorption

69
Small Intestine
  • Digestion
  • Completed in SI (small intestine)
  • Starts in mouth (lipids and CHOs) and stomach
    (proteins)
  • Most enzymes for digestion come from accessory
    organs
  • Pancreas ? digestive enzymes and buffers
  • Liver ? bile buffers and bile salts (emulsify
    lipids and facilitate digestion/absorption of
    lipids) ? stored in gallbladder ? SI

70
Small Intestine
  • Nutrient absorption
  • SI absorbs 90 of nutrients (remainder absorbed
    in LI)
  • Epithelial surface adapted for absorption
  • Surface area increased 600X by
  • Plicae (transverse folds)
  • Villi with microvilli
  • Extensive capillary network in villi
  • ? Hepatic portal circulation ? liver
  • Adjusts nutrient concentrations of blood before
    it reaches systemic circulation

71
Intestinal Villi
  • Fingerlike projections of mucosa
  • Covered by simple columnar epithelium with
    microvilli (brush border)
  • Interior contains
  • Lamina propria
  • Capillary network originates in vascular network
    in submucosa
  • Nerve endings
  • Lacteals (lymphatic capillaries)
  • Transport materials that cannot enter blood
    capillaries (i.e., FAs)
  • Smooth muscle cells
  • Move back and forth
  • Exposed to liquefied intestinal contents by
    contractions of
  • Smooth muscle cells in villi
  • Muscularis mucosae in mucosa
  • Movement also squeezes lacteals and helps move
    lymph out of villi

72
Figure 24-17
73
Small Intestine
  • Surface characteristics
  • Vary over length of SI and parallel absorptive
    activity
  • Duodenum
  • Receives chyme, neutralizes acids, primary site
    for digestion
  • Few plicae, small villi
  • Jejunum
  • Primary site for absorption
  • Prominent plicae and villi
  • Plicae and villi gradually decrease in size
    distally
  • Ileum
  • Little/no nutrient absorption
  • No plicae

74
Intestinal Secretions/Structures
  • Intestinal juice
  • Watery fluid
  • Source
  • Osmosis of water out of mucosa into concentrated
    chyme
  • Secreted by intestinal cells/glands
  • Functions
  • Moistens chyme
  • Assists in buffering acids
  • Liquefies digestive enzymes from pancreas and
    products of digestion

75
Intestinal Secretions/Structures
  • Goblet cells
  • Unicellular exocrine structures
  • Interspersed between columnar epithelial cells
  • Secrete mucins onto intestinal surfaces
  • Intestinal glands
  • At base of villi
  • Contain enteroendocrine cells ? hormones that
    coordinate digestive functions

76
Intestinal Secretions/Structures
  • Duodenal glands
  • Produce
  • Mucus
  • Protects epithelium from enzymes and acidity of
    chyme
  • Contains buffers that elevate pH of chyme (over
    length of duodenum, pH goes from 1-2 to 7-8)
  • Urgastrone
  • Inhibits gastric acid production by stomach
  • Stimulates division of epithelial stem cells of
    digestive tract epithelial cells replaced every
    3-7 days

77
Intestinal Secretions/Structures
  • Brush border enzymes
  • Membrane proteins on surface of intestinal
    microvilli
  • Break down materials that come in contact with
    brush border
  • Released into lumen by disintegrated epithelial
    cells that shed at intestinal surface
  • e.g., enterokinase ? activates key pancreatic
    proenzyme, trypsinogen

78
Intestinal Movements
  • Stimulation of stretch receptors in stomach
    accelerates movement along/through SI
  • Chyme moved through duodenum by short, local
    reflexes
  • Gastroenteric reflex
  • Stimulates motility and secretion along entire SI
  • Gastroileal reflex
  • Triggers relaxation of ileocecal valve (at
    entrance to large intestine)
  • Digestive tract hormones enhance or suppress
    reflexes

79
Emesis (Vomiting)
  • Chemical or mechanical irritation (of pharynx,
    esophagus, stomach, proximal small intestine)
  • Increases digestive fluid secretion, including
    saliva (buffers stomach acid, protects teeth)
  • Triggers vomiting reflex (vomiting center in
    medulla oblongata)
  • Intestinal contents eliminated as quickly as
    possible
  • Pylorus relaxes
  • Contents of duodenum and proximal jejunum
    discharged into stomach by strong peristaltic
    waves toward the stomach (rather than toward the
    ileum)
  • Vomiting occurs as stomach regurgitates its
    contents through esophagus and pharynx

80
Glandular Organs Associated With Small Intestine
  • Pancreas
  • Liver
  • Gall bladder

81
Pancreas
  • Endocrine (1)
  • Cells located in pancreatic islets
  • Alpha cells ? glucagon ? increase blood glucose
  • Beta cells ? insulin ? decrease blood glucose
  • Exocrine (99)
  • Acinar cells ? pancreatic enzymes
  • Epithelial cells ? water and ions that assist in
    diluting and buffering acids in chyme
  • Enzymes water ions pancreatic juice

82
Pancreas Exocrine Secretory Activity
  • Controlled by duodenal hormones triggered by
    chyme
  • Secretin ? pancreatic secretion of watery, buffer
    solution (pH 7.5 8.8) that helps raise pH
  • CCK ? production and secretion of pancreatic
    enzymes
  • (also occurs during cephalic stage before food
    reaches stomach head start important so enzymes
    can be synthesized before chyme reaches duodenum)

83
Pancreas Exocrine Secretory Activity
  • Pancreatic enzymes
  • Pancreatic amylase
  • Breaks down starches (similar to salivary
    amylase)
  • Pancreatic lipase
  • Breaks down complex lipids ? FAs that can be
    absorbed (similar to lingual lipase)
  • Nucleases
  • Break down nucleic acids (DNA, RNA)
  • Proteolytic enzymes
  • 70 of pancreatic enzymes
  • Digest proteins attack peptide bonds
  • Proteases break apart large protein complexes
  • Peptidases break small peptide chains into
    individual amino acids

84
Pancreatic Proteolytic Enzymes
  • Secreted as inactive proenzymes
  • Proenzymes converted to active enzymes after they
    reach small intestine
  • Protects secretory cells from destruction by own
    enzyme products

85
Pancreatic Proteolytic Enzymes
Proenzyme Enzyme Catalyst Active Enzyme
Trypsinogen Enterokinase (brush border of duodenum) Trypsin
Chymotrypsinogen Trypsin Chymotrypsin
Procarboxypeptidase Trypsin Carboxypeptidase
Proelastase Trypsin Elastase
86
Liver
  • Cant live without your liver
  • gt200 functions!
  • 3 General functions
  • Metabolic regulation
  • Hematological regulation
  • Bile production

87
Liver Metabolic Regulation
  • Liver primary organ involved in regulating
    composition of blood
  • All blood leaving absorptive surfaces of
    digestive tract ? hepatic portal system ? liver
  • Liver cells adjust blood composition before it
    reaches systemic circulation
  • Extract toxins
  • Extract/replenish nutrients (e.g., CHOs, lipids)
  • Excess removed and stored (glucose ? glycogen,
    TGs and FAs ? lipids)
  • Deficiencies corrected by
  • Mobilizing stored reserves (glycogen ? glucose,
    lipids ? FAs and TGs
  • Performing synthetic activities (e.g. glucose
    from AAs gluconeogenesis)

88
Liver Metabolic Regulation
  • CHO metabolism
  • Hepatocytes stabilize blood glucose levels
  • When blood glucose decreases
  • Breaks down glycogen ? glucose
  • Synthesizes glucose from lipids or amino acids
    (gluconeogenesis)
  • When blood glucose increases
  • Glucose removed from blood
  • Stored as glycogen
  • Used to synthesize lipids, stored in liver or
    other tissues
  • Regulated by hormones (insulin, glucagon from
    pancreas)

89
Liver Metabolic Regulation
  • Lipid metabolism
  • Hepatocytes regulate circulating TGs, FAs,
    cholesterol
  • When TGs and FAs decrease
  • Breaks down lipid reserves and releases them into
    bloodstream
  • When TGs and FAs increase
  • Removed for storage

90
Liver Metabolic Regulation
  • Amino acid metabolism
  • Hepatocytes remove excess amino acids from
    bloodstream
  • Converted to lipids or glucose and stored
  • Used to synthesize proteins
  • Drug inactivation
  • Removes and metabolizes circulating drugs limits
    duration of effects
  • Storage of fat soluble vitamins (D, E, A, and K)
    and B12

91
Liver Metabolic Regulation
  • Removal of waste products
  • Toxins, various waste products removed from blood
    for inactivation, storage, excretion
  • e.g., when amino acids used to make CHOs or
    lipids ? NH2 creates ammonia (NH3, toxic waste
    product) liver converts to urea (harmless and
    excreted at kidneys)
  • Conversion of Iron to ferretin (a protein-iron
    complex) and storage

92
Liver Hematological Regulation
  • Liver largest blood reservoir in body receives
    25 of cardiac output of blood
  • Performs several hematological functions
  • Removes old/damaged RBCs, cellular debris,
    pathogens from bloodstream
  • Synthesizes plasma proteins (e.g., for clotting,
    transport)
  • Removes/metabolizes circulating hormones
  • Removes antibodies
  • Removes or stores lipid-soluble toxins (e.g., DDT)

93
Liver Bile Production
  • Bile
  • Primarily water, minor amounts of
  • Ions
  • Bilirubin pigment derived from hemoglobin
  • Cholesterol
  • Bile salts
  • Combination of bile, FAs, and lipids
  • Synthesized from cholesterol in the liver
  • Emulsifying agents that break down lipids
  • Excreted into
  • Gallbladder (in absence of chyme)
  • Lumen of duodenum (in presence of chyme)

94
Liver Bile Production
  • Bile excretion
  • Chyme enters duodenum
  • Triggers production of intestinal hormone CCK
  • CCK
  • Relaxes hepatopancreatic sphincter
  • Stimulates contractions in walls of gallbladder
  • Pushes bile through common bile duct into
    duodenum

95
Function of Bile
  • Emulsification
  • Mechanical processing in stomach creates large
    drops containing lipids (because lipids not
    water-soluble)
  • Pancreatic lipase not lipid-soluble
  • Can only interact with lipids at surface of
    droplet, not inside
  • Bile salts
  • Break droplets apart emulsification
  • Increases surface area available for enzymes
  • Facilitate interaction between lipids and
    pancreatic lipase
  • Promote lipid absorption by ileum
  • Enter hepatic portal circulation and recycle
    through liver (enterohepatic circulation liver
    ? intestine ? liver)

96
Liver Damage or Disease
  • Serious threat to life
  • Liver has limited ability to regenerate after
    injury depends on normal vascular pattern being
    established
  • Cirrhosis
  • Replacement of lobules by fibrous tissue
  • Hepatitis
  • Caused by viral infections

97
Gallbladder
  • 2 Major functions
  • Bile storage
  • When bile cannot enter common bile duct (when
    hepatopancreatic sphincter closed) it enters
    cystic duct and is stored in gallbladder
  • Bile modification
  • While stored, much of water absorbed, bile salts
    become more concentrated

98
Gallbladder
  • Gallstones
  • Form when bile is too concentrated ? crystals on
    insoluble minerals and salts
  • If get too large can damage gallbladder wall or
    block cystic or common bile duct
  • Gallbladder
  • May become infected, inflamed, perforated and
    need to be surgically removed (cholecystectomy)
  • ? Dilute bile

99
Coordination of Digestive Glands
  • Centered around duodenum
  • Where acids neutralized and enzymes added)
  • Involves combination of neural and hormonal
    mechanisms
  • Neural mechanisms
  • Prepare digestive tract for activity, or
  • Inhibit gastrointestinal activity
  • Coordinate movement of materials through
    digestive tract (via enterogastric,
    gastroenteric, gastroileal reflexes)

100
Coordination of Digestive Glands
  • Hormonal mechanisms
  • gtgtgt(see Figure 24-23 on slide 101, Table 24-2 on
    slide 102)
  • Hormones important to regulation of intestinal
    and glandular function
  • Gastrin
  • Cholecystokinin (CCK)
  • Gastric inhibitory peptide (GIP)
  • Secretin
  • Produced by duodenal enteroendocrine cells

101
Figure 24-23
102
(No Transcript)
103
Coordination of Absorption
  • Transit time through SI approx 5 hours (lunch
    entering when breakfast leaving)
  • Absorption enhanced by movement of mucosa
  • Microvilli moved by microfilaments
  • Villi moved by smooth muscle cells
  • Groups of villi moved by muscularis externa
  • Plicae moved by muscularis mucosae and muscularis
    externa
  • These movements
  • Stir and mix intestinal contents
  • Constantly change environment around each
    epithelial cell
  • Enhance absorption

104
  • Today in class we will
  • Conclude our discussion on the major functions of
    the organs, regions and anatomical structures of
    the digestive tract
  • Large intestine
  • Histological features
  • Movements
  • Defecation reflex
  • Adverse conditions/diseases
  • Discuss nutrients, nutrient digestion and
    nutrient absorption
  • Malabsorption of nutrients
  • Trace the chemical events in digestion
  • Effects of aging on the digestive system

105
Large Intestine
  • Minor function (10)
  • Absorption of nutrients
  • Major functions
  • Absorption of water
  • Absorption of useful compounds
  • Organic molecules
  • Bile salts reabsorbed in cecum, transported in
    blood to liver
  • Vitamins generated by bacteria
  • Vitamin K blood clotting factors
  • Biotin glucose metabolism
  • Vitamin B5 synthesis of steroid hormone and
    neurotransmitters

106
Large Intestine
  • Major functions (continued)
  • Compaction of intestinal contents into feces
  • Reduced almost 90 (from 1400 mL to 150 mL)
  • Feces
  • 75 water, 5 bacteria, 20 indigestible
    materials, inorganic matter, remains of
    epithelial cells
  • Storage of fecal material prior to defecation

107
Large Intestine
  • Histologic features
  • Thinner walls than SI
  • Lacks villi
  • Many goblet cells
  • Distinctive intestinal glands
  • Deeper than in small intestine
  • Dominated by goblet cells
  • Mucosa does not produce enzymes any digestion
    results from enzymes introduced in SI or from
    bacterial action
  • Mucus provides lubrication (as fecal matter
    becomes less moist and more compact)
  • Muscularis externa longitudinal layer reduced to
    3 muscular bands of taeniae coli

108
Figure 24-25
109
Large Intestine
  • Movements
  • Reflexes move materials into cecum while you eat
  • Peristaltic waves move material through colon
  • Movement from cecum to transverse colon very
    slow allows hours for water absorption
  • Segmentation movements (haustral churning)
  • Mix LI contents

110
Large Intestine
  • Mass movements
  • Powerful peristaltic contractions
  • Move contents from transverse colon through rest
    of large intestine
  • Occur 1-2 times per day
  • Stimulus distention of stomach and duodenum
    relayed over intestinal nerve plexuses
  • Force feces into empty rectum ? distension of
    rectal wall (stretch receptors) ? defecation
    reflex
  • Involuntary (ANS)
  • Defecation reflex ? conscious urge to defecate
  • Relaxation of internal anal sphincter (smooth
    muscle, controls movement of feces into anorectal
    canal)
  • Voluntary (CNS)
  • Contraction of external anal sphincter (skeletal
    muscle)

111
Figure 24-25
112
Large Intestine
  • Elimination of feces requires
  • Both internal and external anal sphincters must
    be relaxed
  • Conscious activities
  • Opening external anal sphincter (except when
    internal pressure sufficiently high)
  • Increasing intra-abdominal pressure so fecal
    material forced out of rectum

113
Large Intestine
  • Adverse conditions/diseases
  • Diarrhea
  • Frequent, watery bowel movements
  • Causes
  • Colon mucosa cant maintain normal levels of
    absorption
  • Rate of fluid entry into colon exceeds absorptive
    capacity
  • Bacterial, viral, protozoan infection of colon or
    small intestine
  • May be life threatening due to fluid and ion loss
  • Constipation
  • Infrequent defecation
  • Feces become dry,hard, compact, difficult to
    move, highly abrasive
  • Cause fecal materials move through colon so
    slowly excessive reabsorption of water occurs
  • Related to inadequate dietary fiber and fluids,
    lack of exercise

114
Large Intestine
  • Adverse conditions/diseases (continued)
  • Diverticulosis
  • Pockets (diverticula) form in mucosa (generally
    sigmoid colon)
  • Get forced outward (during defecation), push
    through weak points in muscularis externa ?
    subject to recurrent infection/inflammation
    (diverticulitis)
  • Colon and rectal cancers
  • Best defense early detection and prompt
    treatment
  • Screening test blood in feces
  • Definitive evaluation visual inspection of
    lumen (colonoscopy)

115
Nutrient Digestion
  • Digestion
  • Breakdown of large organic molecules into small
    fragments that can be absorbed
  • Occurs via hydrolysis with aid of digestive
    enzymes
  • Source of digestive enzymes
  • Secreted by salivary glands, tongue, stomach,
    pancreas, and mixed into ingested material as it
    passes along digestive tract
  • Brush border enzymes attached to intestinal
    microvilli

116
Carbohydrates
  • Sugars and starches
  • Building blocks
  • Simple sugars (monosaccharides)
  • Made up of 3-7 carbon atoms
  • Combine via dehydration synthesis to form
    disaccharides, trisaccharides, polysaccharides
  • Digestion is reverse process

117
Simple Sugars
Figure 211
118
Formation and Breakdown of Complex Sugars
Figure 212
119
Polysaccharides
  • Chains of many simple sugars, e.g., glycogen

Figure 213
120
Carbohydrate Digestion
  • Polysaccharides (glycogen, starch)
  • In presence of salivary and pancreatic amylases ?
  • Tri- and disaccharides
  • In presence of brush border enzymes
  • e.g., maltase, sucrase, lactase ?
  • Monosaccharides
  • e.g., glucose ?
  • Intestinal capillaries

121
Lipids
  • Fats, oils, waxes
  • Building blocks
  • Glycerol fatty acids (FAs)
  • Combine via dehydration synthesis to form
    monoglycerides, diglycerides, triglycerides
  • Digestion is reverse process

122
Glycerides
  • Glycerides
  • Fatty acids attached to a glycerol molecule
  • Triglyceride
  • 3 Fatty-acids
  • Storage molecule

Figure 216
123
Combination Lipids
Figure 218a, b
124
Formation and Breakdown of Triglycerides
Figure 216
125
Lipid Digestion
  • Lipids (TGs)
  • In presence of lingual and pancreatic lipases ?
  • Monoglycerides, FAs
  • Bile salts emulsify ? micelles lipid-bile salt
    complex ?
  • TGs proteins ? chylomicrons ?
  • Lacteals

126
Proteins
  • Most abundant, most important organic component
    in human body
  • gt2M different proteins, 20 of BW
  • Perform essential functions, e.g., support,
    metabolism, movement, etc.
  • Building blocks
  • Amino acids (AAs)
  • Form peptide bonds
  • Combine via dehydration synthesis to form
    di-/tripeptides, polypeptides, proteins
  • Digestion is reverse process

127
Amino Acid
Figure 2-19
128
Formation and Breakdown of Peptides
Figure 220
129
Protein Digestion
  • Proteins
  • In presence of pepsin ?
  • Polypeptides
  • In presence of other enzymes, e.g.,
  • Trypsin, chymotripsin, elastase, carboxypeptidase
  • ?
  • Short peptides
  • In presence of brush border enzymes (peptidases)
  • ?
  • Amino acids ?
  • Intestinal capillaries

130
Figure 24-27
131
Nutrient Absorption
  • Absorbed nutrients
  • Broken down to provide energy for synthesis of
    ATP
  • Used to synthesize CHOs, lipids, proteins

132
Water Absorption
  • By small and large intestines
  • Involves rapid, but passive flow of H2O along
    osmotic gradients
  • As intestinal cells absorb nutrients and ions
  • Solute concentrations increase
  • H20 moves into cells and surrounding tissues
  • 9L/day enters intestinal tract, but only 150 mL
    lost in feces remainder is absorbed

133
Digestive Secretion and Absorption of Water
Figure 2428
134
Ion Absorption
  • Each ion handled individually
  • Rate of intestinal absorption of each is tightly
    controlled
  • Absorption transport mechanisms include
    diffusion, active transport, carrier-mediated
    transport
  • Some absorption requires hormones
  • Ca2 - calcitriol, PTH
  • Na - aldosterone

135
Vitamin Absorption
  • Vitamins organic compounds required in very
    small quantities
  • Fat-soluble vitamins (D, E, A, K)
  • Easily absorbed by diffusion across digestive
    epithelium
  • Water-soluble vitamins (9)
  • e.g., B vitamins, C
  • All except B12 easily absorbed by diffusion
  • Required for synthesis of bone proteins and
    hematopoiesis
  • Must be bound to intrinsic factor (glycoprotein
    secreted by parietal cells of stomach) then can
    be absorbed by active transport

136
Malabsorption
  • Abnormal nutrient absorption
  • Results from
  • Damage to
  • Accessory glands (pancreatitis, cirrhosis)
  • Intestinal mucosa (radiation, toxic compounds-
    chemotherapeutic agents, infection)
  • Duct blockage
  • Bile duct biliary obstruction
  • Pancreatic pancreatic obstruction
  • Genetic inability to produce gastric or
    intestinal enzymes (lactose intolerance)

137
Effects of Aging
  • Epithelial stem cell division rate decreases
  • Stratified epithelium (mouth, esophagus, anus)
    becomes thinner, more fragile
  • Digestive epithelium more susceptible to damage
    (e.g. ulcers)
  • Tissue repair less efficient
  • Smooth muscle tone decreases
  • Weakened muscular sphincters ? esophageal reflux
  • Motility decreases, peristaltic contractions
    weaker promotes constipation
  • Sagging colon ? diverticulosis
  • Straining to defecate ? hemorrhoids (swollen
    rectal varicose veins)
  • Cancer rates increase (colon, stomach oral,
    pharyngeal among smokers)
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