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The Functional Anatomy and
Histology of the Gastrointestinal
Tract Including the Liver and the
Pancreas
MBS 232
Dr KB Makhathini
2020
 Digestive System
Provides fuel for body cells’ functioning
Two groups of organs
1. Alimentary canal (gastrointestinal or GI tract)
Digests and absorbs food
Mouth, pharynx, esophagus, stomach, small intestine, and large
intestine
2. Accessory digestive organs
Teeth, tongue, gallbladder
Digestive glands
– Salivary glands
– Liver
– pancreas 2
 Parotid gland
Mouth (oral cavity) Sublingual gland Salivary
Tongue Submandibular
glands
gland

Esophagus Pharynx
Stomach
Pancreas
Liver (Spleen)
Gallbladder
Transverse colon
Duodenum Descending colon
Small Jejunum Ascending colon
intestine Ileum Cecum Large
Sigmoid colon intestine
Rectum
Vermiform appendix
Anus Anal canal
3
Six Functions of the Digestive System
1. Ingestion
– Occurs when food and drink enter mouth

2. Mechanical processing
– Crushing of solid food to make it easier to move along the digestive
tract
– Increases surface area for enzymes to work
– Process begins in oral cavity with teeth and tongue

3. Chemical processing
– Chemical breakdown of food to absorbable size

4
 Six Functions of the Digestive System
4. ​Secretion
– Release of water, acids, enzymes, and buffers into lumen of digestive
tract

5. ​Absorption
– Movement of small organic molecules, electrolytes, and water across
digestive epithelium and into interstitial fluid of digestive tract

6. ​Excretion (defecation)
– Elimination of waste products from digestive tract
– Products are ejected as feces in process called defecation

5
Ingestion
Food
Mechanical
digestion Pharynx
Chewing (mouth) Esophagus
Churning (stomach) Propulsion
Segmentation Swallowing
(small intestine) (oropharynx)
Chemical Peristalsis
digestion Stomach (esophagus,
stomach,
small intestine,
large intestine)
Absorption

Lymph
vessel

Small
intestine
Large Blood
intestine vessel
Mainly H2O
Feces

Defecation Anus

6
 Digestive Tract Lining

Plays defensive role for the body
Protects surrounding tissues from:
– Corrosive effects of digestive acids and enzymes
– Physical abrasion
– Bacteria that are ingested or live in digestive tract

7
Four Histological Layers of the GI Tract

1. Mucosa
2. Submucosa
3. Muscularis externa
4. Serosa

8
 Mucosa
Mucous membrane that forms the inner lining of the digestive
tract
Consists of:
– Mucosal epithelium
– Underlying layer of areolar tissue called the lamina propria
– Muscle layer called the muscularis mucosae
Smooth muscle that helps move mucosa

9
 Mucosal Epithelia
Stratified squamous in high physical stress organs
– Oral cavity, pharynx, esophagus, anus

Rest is simple columnar with surface modifications
Ducts of secretory glands open to surface of epithelium
Circular folds and villi increase surface area for absorption

10
 Submucosa

Layer of dense irregular connective tissue
Binds mucosa to muscularis externa
Contains blood vessels and lymphatics
Outer margin contains:
– Parasympathetic neurons and sensory neurons
– Submucosal plexus
Neural network that can function without CNS
Regulates secretion and motility

11
 Muscularis Externa
Band of smooth muscle arranged in:
– Inner circular and outer longitudinal layer

Function to mix and propel materials
Myenteric plexus between layers of muscle
– Contains parasympathetic ganglia, sensory neurons, interneurons, and
sympathetic postganglionic fibers
– Parasympathetic stimulation increases activity
– Sympathetic stimulation decreases activity

12
 Serosa and Adventitia
Serosa
– Serous membrane covering muscularis externa along GI tract enclosed
by peritoneum
– Also called the visceral peritoneum
– Continuous with the parietal peritoneum, which lines inner surfaces of
body wall

Adventitia
– Layer covering muscularis externa of regions where there is no serosa
Examples: oral cavity, pharynx, esophagus, and rectum
– Attaches GI tract to adjacent structures

13
 Mesenteries
Double sheets of serous membrane (parietal and visceral
peritoneum)
Suspend portions of digestive tract
Provide pathways for blood vessels, lymphatics, and nerves
Help organize and stabilize attached organs

14
Structure of the Digestive Tract

15
16
 The Oral Cavity
Also called the buccal cavity
Part of digestive tract that receives food
Lined by oral mucosa
– Stratified squamous epithelium

Contains tongue, teeth, and gingivae, or gums
– Gingivae are ridges of oral mucosae surrounding base of teeth

17
 Functions of the Oral Cavity
Senses food before swallowing
Mechanically processes food
Lubricates food with saliva and mucus
Begins enzymatic digestion of carbohydrates and lipids

18
 Oral Cavity Boundaries
Lateral walls formed by cheeks
– Supported by pads of fat and buccinator muscle

Anterior boundary
– Labia, or lips, are continuous with cheek
– Vestibule is space between cheeks (or lips) and teeth

Roof formed by hard palate and soft palate
Floor dominated by tongue
– Free edge of tongue is attached to floor with lingual frenulum

Imaginary line dividing oral cavity from oropharynx
– Extends between base of tongue and uvula
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The Oral Cavity

20
 The Tongue
Manipulates food within oral cavity
– Mechanically compresses, abrades, distorts material
– Assists in chewing and preparing food for swallowing
– Provides sensory analysis of touch, temperature, and taste

Lingual tonsils
– Paired lymphoid nodules at base of tongue
– Help resist infection

21
 Tongue
Functions include
– Repositioning and mixing food during chewing
– Formation of the bolus
– Initiation of swallowing, speech, and taste

Intrinsic muscles change the shape of the tongue
Extrinsic muscles alter the tongue’s position
Lingual frenulum: attachment to the floor of the mouth

22
 Tongue
Surface bears papillae
1. Filiform—whitish, give the tongue roughness and provide friction
2. Fungiform—reddish, scattered over the tongue
3. Circumvallate (vallate)—V-shaped row in back of tongue
These three house taste buds
4. Foliate—on the lateral aspects of the posterior tongue

Terminal sulcus marks the division between
– Body: anterior 2/3 residing in the oral cavity
– Root: posterior third residing in the oropharynx

23
 Palate
Hard palate: palatine bones and palatine processes of the
maxillae
– Slightly corrugated to help create friction against the tongue

Soft palate: fold formed mostly of skeletal muscle
– Closes off the nasopharynx during swallowing
– Uvula projects downward from its free edge

24
Epiglottis
Palatopharyngeal
arch
Palatine tonsil
Lingual tonsil
Palatoglossal
arch
Terminal sulcus
Foliate papillae
Circumvallate
papilla
Midline groove
of tongue
Dorsum of tongue
Fungiform papilla
Filiform papilla
25
 The Salivary Glands
Three pairs of glands that secrete into oral cavity
1. Parotid salivary glands
On each side of oral cavity between mandible and skin
Parotid duct empties into vestibule at level of second upper molar

2. Sublingual salivary glands
Under mucous membrane on floor of mouth
Numerous sublingual ducts open on either side of lingual frenulum

3. Submandibular salivary glands
In floor of the mouth along inner surfaces of mandible
Ducts open into mouth behind teeth on either side of lingual frenulum

26
The Salivary Glands

27
 Saliva Amount and Contents
About 1.0–1.5 liters produced each day
– During eating, production increases to about 7 mL per minute
– Regulated by autonomic nervous system

Composition
– 99.4 percent water
– Mucins, ions, buffers, waste products, metabolites, and enzymes
Mucins absorb water and form mucus

28
 Functions of Saliva
1. Water lubricates mouth and dissolves chemicals
2. Mucus reduces friction and makes swallowing easier
3. Buffers keep pH near 7.0 and prevent buildup of acids
produced by bacteria
4. Salivary antibodies (IgA) and lysozyme help control bacterial
levels
5. Salivary amylase (an enzyme) begins chemical digestion of
starches (complex carbohydrates)
– Produced primarily by parotid salivary gland
29
 The Teeth
Perform chewing, or mastication
Parts of a tooth
– Neck is boundary between root and crown
– Enamel layer covers crown
Hardest biologically manufactured substance
Requires Ca2+, phosphates, and vitamin D3 for formation
– Dentin makes up most of tooth
– Pulp cavity receives blood vessels and nerves through root canals
– Periodontal ligament, with cementum, binds to bone in tooth socket,
or alveolus
30
Teeth: Structural Components and
Dental Succession

31
 Tooth Decay
Generally result of bacterial action
Bacteria produce matrix, trapping food particles
– Creates deposits called dental plaque
– Plaque can calcify and form hard layer of tartar, or dental calculus

32
 Types of Teeth
Incisors
– Blade-shaped teeth at front of mouth
– Used for clipping or cutting

Cuspids, or canines
– Sharp ridgeline and pointed tip
– Used for tearing or slashing

Bicuspids, or premolars, and molars
– Have flattened crowns with ridges
– Used for crushing, mashing, and grinding

33
Incisors Incisors
Central (6–8 mo) Central (7 yr)
Lateral (8 yr)
Lateral (8–10 mo)
Canine (eyetooth)
Canine (eyetooth)
(11 yr)
(16–20 mo)
Premolars
Molars (bicuspids)
First molar First premolar
(10–15 mo) Deciduous (11 yr)
Second molar (milk) teeth Second premolar
(about 2 yr) (12–13 yr)
Molars
First molar (6–7 yr)
Second molar
(12–13 yr)
Third molar Permanent
(wisdom tooth) teeth
(17–25 yr)

34
 Dental Formulas
A shorthand way of indicating the number and relative
position of teeth
– Ratio of upper to lower teeth for one-half of the mouth
– Primary: 2I,1C, 2M
– Permanent: 2I,1C, 2PM, 3M

35
 Dental Succession
Two sets of teeth form during development
Deciduous teeth are first to appear
– Also called primary, baby, or milk teeth
– Usually 20 in number
– Periodontal ligaments and roots erode during eruption (emergence) of
adult teeth

Secondary dentition, or permanent dentition
– Usually 32 in number
– Third molars, or wisdom teeth, are last to come in

36
 The Pharynx
Commonly called the throat
Serves as common passageway for food, liquid, and air
Food passes through oropharynx and laryngopharynx to
esophagus
Mucosa is stratified squamous epithelium
Lamina propria contains mucous glands and tonsils
Pharyngeal muscles cooperate with oral cavity and
esophageal muscles for swallowing

37
 The Esophagus
Muscular tube (25cm long and 2cm wide) that acts as
passageway from pharynx to stomach
Located posterior to trachea
Enters abdominal cavity through esophageal hiatus in
diaphragm
– Diaphragmatic, or hiatal, hernia involves movement of abdominal
organs upward through the esophageal hiatus

Lined with stratified squamous epithelium
Circular muscles at either end form upper and lower
esophageal sphincters
38
 Lips and Cheeks
Contain orbicularis oris and buccinator muscles
Vestibule: recess internal to lips and cheeks, external to teeth
and gums
Oral cavity lies within the teeth and gums
Labial frenulum: median attachment of each lip to the gum

39
 Upper lip
Gingivae (gums)
Superior labial
Palatine raphe frenulum
Palatoglossal arch
Hard palate
Soft palate Palatopharyngeal
arch
Uvula
Posterior wall
Palatine tonsil
of oropharynx
Tongue
Sublingual fold
Lingual frenulum
with openings of
sublingual ducts Opening of
submandibular duct
Gingivae (gums)
Vestibule
Inferior labial
Lower lip
frenulum
Anterior view
40
 The Stomach

Four primary functions
1. Temporary storage of ingested food
2. Mechanical breakdown of ingested food
3. Chemical digestion by acids and enzymes
4. Production of intrinsic factor needed for vitamin B12 absorption

Chyme is mixture of food and gastric secretions

41
 Regions of the Stomach
J-shaped organ with four main regions
1. Cardia
Where the esophagus connects
2. Fundus
Bulge of stomach superior to cardia
3. Body
Large area between fundus and curve of the J
4. Pylorus
Most distal portion
Connects stomach to small intestine
Pyloric sphincter regulates flow of chyme into small intestine
42
 Internal Features of the Stomach
Rugae
– Folds of mucosa
– Show prominently when stomach is empty
– Flatten out with stomach distention
– Stomach can expand to accommodate up to 1.0–1.5 liters

Muscularis externa
– Has circular, longitudinal, and third oblique layer
– Extra layer strengthens stomach wall and assists in mixing and
churning chyme

43
The Anatomy of the Stomach

44
 Mesenteries Associated with the Stomach

Greater omentum
– Very large peritoneal pouch
– Extends from greater curvature of stomach down over abdominal
viscera

Lesser omentum
– Smaller peritoneal pouch
– Extends from lesser curvature of stomach to liver

45
 The Gastric Wall
Lined by simple columnar epithelium with numerous mucous
cells
Mucous epithelium secretes alkaline mucus that protects
epithelium
Gastric pits
– Shallow depressions that open to gastric surface
– Mucous cells at base, or neck, undergo active mitosis, replacing
mucosal cells every three to seven days

Gastric glands
– Located in fundus, body, and pylorus
– Connected to gastric pits
– Cells produce 1.5 liters/day of gastric juice
46
 The Gastric Gland Cells
Parietal cells secrete:
– Intrinsic factor for vitamin B12 absorption
– Hydrochloric acid (HCl)
Lowers pH of gastric juice to 1.5–2.0
Kills microorganisms and activates enzymes

Chief cells secrete:
– Pepsinogen, activated by HCl, which is converted into proteolytic
enzyme, pepsin
– In infants, also secrete rennin and gastric lipase that are important in
digestion of milk
47
The Anatomy of the Stomach

48
Stomach Histology
Rugae: Folds in stomach
when empty
Gastric pits: Openings for
gastric glands
– Contain cells
Surface mucous cells: Mucus
Mucous neck cells: Mucus
Parietal cells: Hydrochloric
acid and intrinsic factor
Chief cells: Pepsinogen
Endocrine cells: Regulatory
hormones

24-49
Small Intestine
Site of greatest amount of
digestion and absorption
Divisions
– Duodenum
– Jejunum
– Ileum: Peyer’s patches or
lymph nodules
Modifications
– Circular folds or plicae
circulares, villi, lacteal,
microvilli
Cells of mucosa
– Absorptive, goblet, granular,
endocrine

24-50
 Small Intestine Secretions
Mucus
– Protects against digestive enzymes and stomach acids

Digestive enzymes
– Disaccharidases: Break down disaccharides to monosaccharides
– Peptidases: Hydrolyze peptide bonds
– Nucleases: Break down nucleic acids

Duodenal glands
– Stimulated by vagus nerve, secretin, chemical or tactile irritation
of duodenal mucosa

51
Duodenum and Pancreas

52
Duodenum Anatomy and Histology

53
 Functions of the Liver
Bile production
– Salts emulsify fats, contain pigments as bilirubin

Storage
– Glycogen, fat, vitamins, copper and iron

Nutrient interconversion
Detoxification
– Hepatocytes remove ammonia and convert to urea

Phagocytosis
– Kupffer cells phagocytize worn-out and dying red and white blood cells, some
bacteria

Synthesis
– Albumins, fibrinogen, globulins, heparin, clotting factors 54
Liver
Lobes
– Major: Left and right
– Minor: Caudate and quadrate
Ducts
– Common hepatic
– Cystic
From gallbladder
– Common bile
Joins pancreatic duct at
hepatopancreatic ampulla

24-55
Duct System

56
 Gallbladder
Bile is stored and concentrated
Stimulated by cholecystokinin and vegal stimulation
Dumps into small intestine
Production of gallstones possible
– Drastic dieting with rapid weight loss

57
 Pancreas
Anatomy Secretions
– Endocrine – Pancreatic juice (exocrine)
Pancreatic islets produce Trypsin
insulin and glucagon Chymotrypsin
– Exocrine Carboxypeptidase

Acini produce digestive Pancreatic amylase

enzymes Pancreatic lipases

– Regions: Head, body, tail Enzymes that reduce DNA
and ribonucleic acid

58
The Pancreas

59
 Large Intestine

Extends from ileocecal junction to anus
Consists of cecum, colon, rectum, anal canal
Movements sluggish (18-24 hours) 24-60
 Large Intestine
Cecum
– Blind sac, vermiform appendix attached

Colon
– Ascending, transverse, descending, sigmoid

Rectum
– Straight muscular tube

Anal canal
– Internal anal sphincter (smooth muscle)
– External anal sphincter (skeletal muscle)
– Hemorrhoids: Vein enlargement or inflammation

61
Histology of Large Intestines

62
The Digestion and Absorption
of Carbohydrates, Fats and
Proteins

MBS 232
Dr KB Makhathini
2020
 Introduction
Balanced diets include all ingredients needed to maintain
homeostasis
– Carbohydrates, proteins, lipids
Broken down into absorbable forms by enzymes
– Process called hydrolysis
Used by cells to generate ATP or build complex carbohydrates,
proteins, lipids
– Water, electrolytes (minerals), vitamins
No processing, but require special transport mechanisms
 Carbohydrate Digestion and
Absorption
Begins in mouth during mastication
– Salivary amylase breaks down complex carbohydrates into di- or
trisaccharides
Pancreatic amylase continues process
Brush border enzymes on intestinal microvilli complete
breakdown into monosaccharides
Monosaccharides absorbed through facilitated diffusion or
cotransport
Transported into capillaries by diffusion
 Carbohydrates
Consist of starches, glycogen, sucrose, lactose, glucose,
fructose
Polysaccharides broken down to monosaccharides
Monosaccharides taken up by active transport or facilitated
diffusion and carried to liver
Glucose is transported to cells requiring energy
– Insulin influences rate of transport
 Chemical Digestion and
Absorption of Carbohydrates
Digestive enzymes
– Salivary amylase
– Pancreatic amylase
– Brush border enzymes
Dextrinase
Glucoamylase
Lactase
Maltase
Sucrase
 Salivary and Pancreatic enzymes
Enzymes: Salivary amylase and Pancreatic alpha amylase
PH 6.7 – 7.5
Begins in mouth during mastication mixed with salivary
amylase (parotid and submandibular salivary gland)
Breaks down starches (complex carbohydrates) into
disaccharides (2 simples sugars) and trisaccharides
Salivary amylase continues (1-2h) until stomach acids renders
the enzyme inactive
 Pancreatic phase
Duodenum: remaining carbohydrates are digested by
pancreatic alpha amylase.
No disaccharides, trisaccharides produced through digestion
Any in the food is further digested.
 Carbohydrates: Duodenal phase –
brush border
Disaccharides and tri-saccharides broken down into mono-
saccharides by the brush border enzymes of the intestinal
microvilli
Enzyme,
– Maltase: Split bond between 2 glucose molecules of Maltose
– Sucrase: Breaks sucrose into glucose and fructose
– Lactase: Breaks Lactose into glucose and galactose
 Carbohydrate digestion
Lactose (milk) – NB in infancy and childhood
Lactose intolerant
– Intestinal mucosa stops producing lactase
 Absorption of Monosaccaharides
Intestinal epithelium
– Diffusion
Passive or facilitated
– Co-transport
Difference:
– Facilitated Diffusion:
1 molecule/ion across membrane
No ATP
NOT if opposing gradient
– Co-transport:
>1 molecule
Down the concentration gradient for at least 1
Expend ATP – maintain homeostasis (Na+ in – out)
Carbohydrates
 Digestion and Absorption of Lipids
Lipid molecules contain carbon, hydrogen, and oxygen
– In different proportions than carbohydrates
Triglycerides are the most abundant lipid in the body
Lipid Catabolism (also called lipolysis)
– Breaks lipids down into pieces that can be
Converted to pyruvic acid
Channeled directly into TCA cycle
– Hydrolysis splits triglyceride into component parts
One molecule of glycerol
Three fatty acid molecules
 Digestion and Absorption of Lipids
Cells require lipids
– To maintain plasma membranes
Steroid hormones must reach target cells in many different
tissues
Solubility
– Most lipids are not soluble in water
Special transport mechanisms carry lipids from one region of body to
another

Circulating Lipids
– Most lipids circulate through bloodstream as lipoproteins
– Free fatty acids are a small percentage of total circulating lipids
Digestion and Absorption of Lipids
Involves lingual lipase from glands under tongue and
pancreatic lipase from pancreas
Triglycerides enter duodenum in large fat droplets
– Bile salts emulsify droplets
– Pancreatic lipase breaks apart triglycerides
Digestion and Absorption of Lipids
Triglycerides are broken into fatty acids and monoglycerides
– These combine with bile salts to form micelles
Micelles diffuse into epithelial cells and are converted into
triglycerides
– Coated with proteins to form chylomicrons
– Secreted by exocytosis into interstitial fluids
– Absorbed into lacteals (lymphatic vessels – small intestine) and
transported through lymphatic system to left subclavian vein
Digestion and Absorption of Lipids
Free Fatty Acids
– Come from catabolized adipose tissue
– Are an important energy source
During periods of starvation
When glucose supplies are limited
– Liver cells, cardiac muscle cells, skeletal muscle fibers, and so
forth
Metabolize free fatty acids
 Free Fatty Acids (FFAs)
Are lipids
Can diffuse easily across plasma membranes
In blood, are generally bound to albumin (most abundant
plasma protein)
Sources of FFAs in blood
– Fatty acids not used in synthesis of triglycerides diffuse out of
intestinal epithelium into blood
– Fatty acids diffuse out of lipid stores (in liver and adipose tissue) when
triglycerides are broken down
 Lipoproteins
Are lipid–protein complexes
Contain large insoluble glycerides and cholesterol
Five classes of lipoproteins
– Chylomicrons
– Very low-density lipoproteins (VLDLs)
– Intermediate-density lipoproteins (IDLs)
– Low-density lipoproteins (LDLs)
“ Bad cholesterol” deposited in arterial plaques
– High-density lipoproteins (HDLs)
“Good cholesterol” transports cholesterol to liver
 Fat globule

1 Large fat globules are emulsified
Bile salts (physically broken up into smaller fat
droplets) by bile salts in the duodenum.
2 Digestion of fat by the pancreatic
enzyme lipase yields free fatty acids and
monoglycerides. These then associate
Fat droplets with bile salts to form micelles which
coated with “ferry” them to the intestinal mucosa.
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 lipoid substances and proteins
to form chylomicrons.
4 Chylomicrons are extruded from the
Epithelial epithelial cells by exocytosis. The
cells of chylomicrons enter lacteals. They are
Lacteal
small carried away from the intestine by lymph.
intestine
Digestion and Absorption of Lipids
Fat digestion
Enzyme(s) Site of
Foodstuff and source action Path of absorption

Unemulsified Fatty acids and monoglycerides
fats enter the intestinal cells via
Emulsification by Small diffusion.
the detergent intestine Fatty acids and monoglycerides
action of bile are recombined to form
salts ducted triglycerides and then
in from the liver combined with other lipids and
proteins within the cells, and
the resulting chylomicrons are
Pancreatic Small
extruded by exocytosis.
lipases intestine
The chylomicrons enter the
lacteals of the villi and are
transported to the systemic
circulation via the lymph in the
Monoglycerides Glycerol thoracic duct.
and fatty acids and Some short-chain fatty acids
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.
Digestion and Absorption of Lipids
 Digestion and Absorption of Proteins
The body synthesizes 100,000 to 140,000 proteins
– Each with different form, function, and structure

All proteins are built from the 20 amino acids
Cellular proteins are recycled in cytosol
– Peptide bonds are broken
– Free amino acids are used in new proteins
When glucose and lipid reserves are inadequate, liver cells
– Break down internal proteins
– Absorb additional amino acids from blood
Amino acids are deaminated
– Carbon chains broken down to provide ATP
 Digestion and Absorption of
Proteins
Amino Acid Catabolism
– Removal of amino group by transamination or deamination
Requires coenzyme derivative of vitamin B6 (pyridoxine)

Transamination
– Attaches amino group of amino acid
To keto acid
– Converts keto acid into amino acid
That leaves mitochondrion and enters cytosol
Available for protein synthesis
 Digestion and Absorption of
Proteins
Deamination
– Prepares amino acid for breakdown in TCA cycle
– Removes amino group and hydrogen atom
Reaction generates ammonium ion
Chemical Digestion and Absorption of
Nucleic Acids
Enzymes
– Pancreatic ribonuclease and deoxyribonuclease

Absorption
– Active transport

Transported to liver via hepatic portal vein
 Chemical Digestion and
Absorption of Proteins
Enzymes: pepsin in the stomach
Pancreatic proteases
– Trypsin, chymotrypsin, and carboxypeptidase

Brush border enzymes
– Aminopeptidases, carboxypeptidases, and dipeptidases

Absorption of amino acids is coupled to active transport of
Na+
 Lumen of Amino acids of protein fragments
intestine Brush border enzymes
Apical membrane (microvilli)
Pancreatic
proteases 1 Proteins and protein fragments
Na+ are digested to amino acids by
pancreatic proteases (trypsin,
chymotrypsin, and carboxy-
peptidase), and by brush border
Na+ Absorptive enzymes (carboxypeptidase,
epithelial aminopeptidase, and dipeptidase)
cell of mucosal cells.

2 The amino acids are then
absorbed by active transport into
the absorptive cells, and move to
their opposite side (transcytosis).
Amino
acid
carrier

3 The amino acids leave the
villus epithelial cell by facilitated
Active transport Capillary diffusion and enter the capillary
Passive transport via intercellular clefts.
Protein digestion
Enzyme(s) Site of
Foodstuff and source action Path of absorption

Protein Amino acids are absorbed
Pepsin
by cotransport with
(stomach glands) Stomach sodium ions.
in presence
Some dipeptides and
Large polypeptides of HCl
tripeptides are absorbed
Pancreatic via cotransport with H++
Small
enzymes and hydrolyzed to amino
intestine
Small polypeptides, (trypsin, chymotrypsin, acids within the cells.
small peptides carboxypeptidase) Amino acids leave the
Brush border epithelial cells by
Small
enzymes facilitated diffusion, enter
Amino acids intestine
(aminopeptidase, the capillary blood in the
(some dipeptides carboxypeptidase, villi, and are transported
and tripeptides) and dipeptidase) to the liver via the hepatic
portal vein.
Absorption of Minerals
and Vitamins
MBS 232
Dr KB Makhathini
2020
1
 Vitamins
Vitamins are organic molecules essential to metabolic
reactions.
Function as coenzymes in enzymatic reactions.
Two groups:
– Fat-soluble vitamins:
Dissolves in lipids.
A, D, E, and K.
– Water-soluble vitamins:
Dissolves in water.
B vitamins and C.
2
Vitamins

3
Vitamin Absorption and Storage

4
 Vitamin Absorption and Storage
 Water-soluble vitamins
Absorbed with water and enter directly into the
blood stream.
Most absorbed in the duodenum and jejunum.
Most are not stored in the body.
Excess intake excreted through the urine.
Important to consume adequate amounts daily.
Dietary excesses can be harmful.

5
Absorbing Vitamins

6
 Absorption of Vitamins
Fat-soluble vitamins: A, D, E, and K
– Absorbed in micelles along with lipids.
– Vitamin K also produced in colon by bacteria.
Water-soluble vitamins: B vitamins and C
– All but B12 are easily absorbed by digestive epithelium.
B12 requires intrinsic factor (protein secreted by parietal cells of
stomach) for absorption.
– Bacteria in gut are also source of water-soluble vitamins.

7
 Water-Soluble Fat-Soluble
Vitamins Vitamins
Absorbed in the Small Intestine Small Intestine
Hydrophobic or
Hydrophilic Hydrophobic
Hydrophilic
Absorbed into the Blood Lymph

Stored in the body Not Generally Yes

Can build up and
Not Generally Yes
become toxic
Need to consume
Yes No
daily
8
 Absorption of Vitamins
Bacteria in colon make three key vitamins
1. Vitamin K:
Needed for production of clotting factors.
2. Biotin:
Essential for glucose metabolism.
3. Vitamin B5 (pantothenic acid):
Required for synthesis of neurotransmitters and steroid hormones.

9
 Absorption of Vitamins
In small intestine:
– Fat-soluble vitamins (A, D, E, and K) are carried by micelles and
then diffuse into absorptive cells.
– Water-soluble vitamins (vitamin C and B vitamins) are absorbed
by diffusion or by passive or active transporters.
– Vitamin B12 binds with intrinsic factor, and is absorbed by
endocytosis (ileum).

10
 Absorption of Vitamins
In large intestine:
- Vitamin K and B vitamins from bacterial metabolism are
absorbed.

11
 Fat-Soluble Vitamins

Vitamins A, D, E, and K.
Vitamins A, E, and K absorbed from the digestive tract along
with lipid contents of micelles.
Vitamin D3 can be synthesized by skin exposed to sunlight.
Can be stored easily in cells.
Body contains significant reserves.

12
Fat-Soluble Vitamins

13
 Vitamin A absorption

Capability for the de novo synthesis of compounds with
vitamin A activity is limited to plants and microorganisms.
Higher animals must obtain vitamin A from the diet, either
as the preformed vitamin or as a pro-vitamin carotenoids
such as ß-carotene.
In the intestinal mucosa, carotene is converted (via two
enzymatic steps) to retinol.
The major dietary forms of preformed vitamin A are long-
chain fatty acids (contains >12 C atoms) of retinol esters.
14
 Vitamin A absorption
Retinol esters (RE) must be hydrolyzed prior to intestinal
absorption.
Hydrolysis of the esters can be catalyzed both by enzymes
secreted by the pancreas into the intestinal lumen and by
those associated directly with intestinal cells.
Following the hydrolysis of dietary REs, the free retinol is
then taken up by the mucosal cell, where it is re-esterified
with long-chain, mainly saturated fatty acids by the
enzyme lecithin: retinol acyltransferase (LRAT), which is
membrane bound. 15
 Vitamin A absorption

The resulting REs are incorporated with other neutral lipid
esters (i.e., triacylglycerols and cholesteryl esters) into
chylomicrons and absorbed via the lymphatics.
In the vascular compartment, much of the chylomicron
triacylglycerol is hydrolyzed by lipoprotein lipase in
extrahepatic tissues, resulting in the production of a
“chylomicron remnant” that contains most of the newly
absorbed REs.

16
 Vitamin A absorption
Under conditions of adequate vitamin A nutriture, the
liver is the main site of vitamin A storage, with more than
95% of the total neutral retinoid being present as REs,
predominately retinyl palmitate and stearate.
Although chylomicron remnants (and the REs they
contain) initially are taken up exclusively by the
hepatocytes in liver, the REs are then transferred largely to
the perisinusoidal stellate cells. In both cell types the REs
are stored in cytoplasmic lipid droplets along with other
neutral lipids. 17
 Vitamin A

Vitamin E – prevents the oxidation of vitamin A (antioxidant).
Bile is essential for fat soluble vitamin absorption.
Released form the liver – transported by retinol binding
protein (RBP).

18
Fat-Soluble Vitamins

19
 Water-Soluble Vitamins
Most are components of coenzymes.
Easily absorbed from digestive tract.
Excess readily excreted in urine.

20
Water-soluble Vitamins

21
Water-Soluble Vitamins

22
 Hypovitaminosis and Hypervitaminosis

Hypovitaminosis, or vitamin deficiency disease:
– Rarely occurs with fat-soluble vitamins since they are easily stored.
– Intestinal bacteria help prevent deficiency.
Produce five of nine water-soluble vitamins and vitamin K.

Hypervitaminosis:
– Occurs when dietary intake exceeds ability to store, use, or excrete
vitamin.
– Most often involves fat-soluble vitamins.
– Only occurs with water-soluble vitamins if person is taken in large
doses of vitamin supplements.
23
 Electrolyte Absorption
Mostly along the length of small intestine.
Iron and calcium are absorbed in duodenum.
– Na+ is coupled with absorption of glucose and amino acids.
– Ionic iron is stored in mucosal cells with ferritin.
– K+ diffuses in response to osmotic gradients.
– Ca2+ absorption is regulated by vitamin D and parathyroid
hormone (PTH).

24
 Minerals
Inorganic ions released by dissociation of electrolytes.
Important for three reasons:
1. Ions such as Na+ and Cl– determine osmotic concentration of
body fluids.
2. Various ions needed in physiological processes, such as:
maintaining membrane potential, muscle contraction,
generating action potentials, buffers, etc.
3. Ions function as cofactors in enzymatic reactions.

25
 Potassium (K+)

Simple diffusion.
Water absorption – rise – increase in luminal K+ concentration.
Diarrhoea – loss of K+.

26
 Calcium (Ca+)
Absorption strongly controlled by reflexes – changes in plasma
calcium.
Regulation is mediated by Vitamin D.
Decreases in plasma calcium – increases active Vitamin D.
Enhancement of calcium active transport across intestinal
epithelium.

27
 Fe; Fe2+; Fe3+
Ferrous (Fe2+) and
to a lessor extent ferric (Fe3+) are actively transported into
the intestinal epithelium.
Incorporated into Ferritin.
Transported out of enterocyte by ferroportin (Hepcidin –
mediated).
Hepcidin is a protein which is a key regulator of the entry
of iron into the circulation in mammals.
Released into bloodstream and bound to transferrin.
Controlled by body stores. 28
Minerals

29
 Water
Daily requirement averages 2500 mL/day (roughly 40 mL/kg
body weight).
– May need more or less based on activity and body temperature.
– Most obtained through consumed food and water.
– Small amount produced in mitochondria by electron transport
system:
Called metabolic water.
Accounts for about 300 mL of water per day.

30
 Water Absorption
95% is absorbed in the small intestine by osmosis.
Net osmosis occurs whenever a concentration gradient is
established by active transport of solutes.
Water uptake is coupled with solute uptake.

31
Water and Ions
Water:
– Can move in either
direction across wall of
small intestine depending
on osmotic gradients.

Ions:
– Sodium, potassium,
calcium, magnesium,
phosphate are actively
transported.
32
 Malabsorption of Nutrients
Causes
– Anything that interferes with delivery of bile or pancreatic juice.
– Damaged intestinal mucosa (e.g., bacterial infection).

33
 Malabsorption of Nutrients
Gluten-sensitive enteropathy (celiac disease):
– Gluten damages the intestinal villi and brush border.
– Treated by eliminating gluten from the diet (all grains but rice
and corn).

34
Digestive System Age-Related Changes

Division rate of epithelial stem cells declines:
– More susceptible to damage by abrasion, acids, enzymes.
– Peptic ulcers more likely.
Smooth muscle tone decreases:
– Slows rate of peristalsis, leads to constipation.
– Straining leads to hemorrhoids.
– Weakening muscular sphincters can lead to more frequent
“heartburn”.
Cumulative damage becomes apparent:
– Tooth loss due to dental caries (“cavities”) or gingivitis.
– Cirrhosis or other liver disease.

35
Digestive System Age-Related Changes

Increase in cancer rate:
– Rates of colon and stomach cancers rise with age.
– Oral, esophageal, pharyngeal cancers more common in smokers.

Dehydration:
– Osmoreceptor sensitivity declines.

Aging of other systems affects digestive tract:
– Loss in bone mass and calcium can lead to tooth loss.
– Loss of taste and olfactory sensations changes diets.

36
Control of GIT secretion and GIT
movements, and the flux of GIT
content analward

MBS 232
Dr KB Makhathini
 GI tract regulatory mechanisms
1. Mechanoreceptors and chemoreceptors
– Respond to stretch, changes in osmolarity and pH, and
presence of substrate and end products of digestion
– Initiate reflexes that
 Activate or inhibit digestive glands
 Stimulate smooth muscle to mix and move lumen
contents

2
 GI tract regulatory mechanisms
2. Intrinsic and extrinsic controls
– Enteric nerve plexuses (gut brain) initiate short reflexes in response
to stimuli in the GI tract
– Long reflexes in response to stimuli inside or outside the GI tract
involve CNS centers and autonomic nerves
– Hormones from cells in the stomach and small intestine stimulate
target cells in the same or different organs

3
 External stimuli
(sight, smell, taste, Central nervous system
thought of food) and extrinsic autonomic nerves

Long reflexes
Afferent impulses Efferent impulses

Internal Chemoreceptors, Local (intrinsic) Effectors:
(GI tract) osmoreceptors, or nerve plexus Smooth muscle
stimuli mechanoreceptors (“gut brain”) or glands

Short reflexes
Response:
Gastrointestinal
Change in
wall (site of short
contractile or
reflexes)
secretory activity
Lumen of the
alimentary canal

4
 Salivary Glands
Extrinsic salivary glands (parotid, submandibular, and
sublingual)
Intrinsic (buccal) salivary glands are scattered in the oral
mucosa
Secretion (saliva)
– Cleanses the mouth
– Moistens and dissolves food chemicals
– Aids in bolus formation
– Contains enzymes that begin the breakdown of starch

5
Tongue
Teeth
Parotid
Ducts of
gland
sublingual
gland Parotid duct
Masseter muscle
Frenulum
of tongue Body of
Sublingual mandible (cut)
gland Posterior belly
Mylohyoid of digastric
muscle (cut) muscle
Submandibular
Anterior belly of Submandibular duct
digastric muscle gland Mucous Serous cells
(a) cells forming
(b) demilunes

6
Figure 23.9
 Composition of Saliva
There are three salivary glands
Secreted by serous and mucous cells
97–99.5% water, slightly acidic solution containing
– Electrolytes—Na+, K+, Cl–, PO4 2–, HCO3–
– Salivary amylase and lingual lipase
– Mucin
– Metabolic wastes—urea and uric acid
– Lysozyme, IgA, defensins, and a cyanide compound protect against
microorganisms

7
 Control of Salivary Secretions
By autonomic nervous system
– Parasympathetic and sympathetic innervation
Parasympathetic accelerates secretion by all salivary glands

Salivatory nuclei of medulla oblongata influenced by:
– Other brain stem nuclei
– Activities of higher centers

8
 Control of Salivation
Intrinsic glands continuously keep the mouth moist
Extrinsic salivary glands produce secretions when
– Ingested food stimulates chemoreceptors and mechanoreceptors in
the mouth
– Salivatory nuclei in the brain stem send impulses along
parasympathetic fibers in cranial nerves VII and IX

Strong sympathetic stimulation inhibits salivation and results
in dry mouth (xerostomia)

9
 Swallowing
Also called deglutition
– Complex process
– Can be initiated voluntarily or involuntarily
– Proceeds automatically once begun
– Tongue forms food into bolus, or small mass
Compression of bolus against hard palate initiates swallowing process

10
 Three Phases involved in the process of
swallowing (deglutition)
1. Buccal phase
– Voluntary phase
– Movement of bolus into back of oral cavity
and into oropharynx
– Soft palate closes over nasopharynx
2. Pharyngeal phase
– Epiglottis folds over larynx
– Food and liquid are directed past closed
glottis
– Uvula and soft palate block nasopharynx
3. Esophageal phase
– Bolus is pushed into esophagus and toward
stomach
– Pharyngeal and esophageal phases are
11
involuntary due to swallowing reflex
 Movement of Digestive Materials
Pacesetter cells in smooth muscle of
digestive tract trigger contraction
Peristalsis
– Involuntary contraction and relaxation of
intestinal smooth muscles that propels
foods forward
– Waves of contraction initiated by circular
layer, followed by longitudinal layer
– Propels bolus (food mass) down tract

Segmentation
– A mixing action with no propulsion
12
 The Stomach

Four primary functions
1. Temporary storage of ingested food
2. Mechanical breakdown of ingested food
3. Chemical digestion by acids and enzymes
4. Production of intrinsic factor needed for vitamin B12 absorption

Chyme is mixture of food and gastric secretions

13
 Regulation of Gastric Activity
Production of acid and enzymes
– Controlled by central nervous system
– Regulated by reflexes involving stomach wall
– Regulated by hormones of digestive tract

Involves three overlapping phases
1. Cephalic phase
2. Gastric phase
3. Intestinal phase

14
 Cephalic Phase
Triggered by sight, smell, taste, thought of food
Prepares stomach to receive food
Parasympathetic stimulation of gastric cells increases
production of gastric juice
– Rates up to 500 mL/hour

Generally only lasts short period

15
Regulation of Gastric Activity

16
 Gastric Phase
Begins when food enters stomach
Stretch reflexes increase myenteric stimulation of mixing
waves
Submucosal plexus
– Stimulates parietal and chief cells
– Stimulates G cells to produce gastrin
– Results in rapid increase in gastric juice production

Phase may continue for several hours

17
Regulation of Gastric Activity

18
 Intestinal Phase
Begins when chyme enters small intestine
Mostly inhibitory controls, slowing gastric emptying
– Enterogastric reflex inhibits gastrin production
– Intestinal hormones secretin, cholecystokinin (CCK), and gastric
inhibitory peptide (GIP) reduce gastric activity

Ensures efficient intestinal functions
– Secretion, digestion, and absorption

19
Regulation of Gastric Activity

20
 Digestion in the Stomach
Pepsin initiates protein digestion to small peptides
Salivary amylase will digest carbohydrates until pH falls below
4.5
– Generally active for one to two hours after a meal

No nutrients are absorbed in the stomach
– Mucosa covered in alkaline mucus
– Epithelial cells lack transport mechanisms
– Gastric lining is impermeable to water
– Digestion is incomplete, nutrients are still complex

21
 Intestinal Movements
Weak peristaltic contractions move chyme toward jejunum
– Local reflexes not under CNS control

Gastroenteric reflex
– Initiated by distention of stomach
– Increases glandular secretion and peristaltic contractions along length
of small intestine
– Empties duodenum

Gastroileal reflex
– Triggered by gastrin
– Relaxes ileocecal valve
– Material pushed from ileum into large intestine
22
 From
Intestinal Movements
mouth

(a) Peristalsis: Adjacent segments of (b) Segmentation: Nonadjacent segments
alimentary tract organs alternately contract of alimentary tract organs alternately
and relax, which moves food along the tract contract and relax, moving the food
distally. forward then backward. Food mixing and
slow food propulsion occurs.
23
 Coordination of Secretion and
Absorption
Neural and Hormonal Mechanisms
– Coordinate activities of digestive glands
– Regulatory mechanisms center around duodenum
Where acids are neutralized and enzymes added

Neural Mechanisms of the CNS
– Prepare digestive tract for activity (parasympathetic innervation)
– Inhibit gastrointestinal activity (sympathetic innervation)
– Coordinate movement of materials along digestive tract (the
enterogastric, gastroenteric, and gastroileal reflexes)
– Motor neuron synapses in digestive tract release neurotransmitters
24
 Intestinal Secretions
Intestinal juice produced at rate of about
1.8 liters/day
Moistens intestinal contents
Helps buffer acids
Provides liquid environment for intestinal contents
Composed mostly of water from mucosa
– Moves into lumen by osmosis

Rest is secreted by intestinal glands
– Stimulated by touch and stretch receptors in intestinal wall
– Also respond to signals in cephalic phase
25
 Six Hormones of Duodenal
Enteroendocrine Cells
Coordinate digestive functions
– Gastrin
– Secretin
– Cholecystokinin (CCK)
– Gastric inhibitory peptide (GIP)
– Vasoactive intestinal peptide (VIP)
– Enterocrinin

26
 Intestinal Hormones
Intestinal tract secretes peptide hormones with multiple effects
– In several regions of digestive tract
– In accessory glandular organs
Gastrin released in response to incompletely digested proteins
– Promotes stomach motility
– Stimulates production of acid and enzymes
Secretin released in response to acidic chyme
– Increases secretion of bile and buffers by liver and pancreas
Cholecystokinin (CCK) released in response to high-fat chyme
– In pancreas, increases enzyme production
– In gallbladder, causes the ejection of bile
27
 Intestinal Hormones cont.
Gastric inhibitory peptide (GIP) released in response to high-
fat and high-glucose chyme
– Inhibits gastric activity
– Causes release of insulin
Vasoactive Intestinal Peptide (VIP)
– Stimulates secretion of intestinal glands
– Dilates regional capillaries
– Inhibits acid production in stomach
Enterocrinin
– Is released when chyme enters small intestine
– Stimulates mucin production by submucosal glands of duodenum
28
29
Activities of Major Digestive Tract Hormones

30
 Digestion in the Small Intestine
Most important digestive processes are completed in small
intestine
Final products of digestion absorbed here
Most enzymes and buffers come from pancreas and liver
– Small intestine enzymes produced by brush border cells

31
 Control of Pancreatic Secretions
About 1000 mL of pancreatic juice secreted each day
Regulated by hormones
– Secretin released from duodenum in response to presence of acidic
chyme entering from stomach
Triggers pancreas to release watery, alkaline (pH 7.5–8.8) fluid
One of primary buffers in fluid is sodium bicarbonate
Increases pH of chyme to optimal pH for digestive enzymes
– Cholecystokinin (CCK) stimulates production and release of pancreatic
enzymes

32
 Pancreatic Enzymes
Classified by substances they help break down
– Carbohydrases (general term) digest sugars and starches
Pancreatic amylase breaks down carbohydrates
– Pancreatic lipase breaks down lipids, or fats
– Nucleases break down nucleic acids
– Pancreatic proteases break down proteins
Make up 70 percent of total pancreatic enzyme production
Examples: trypsin, chymotrypsin, carboxypeptidase
Secreted as inactive proenzymes and activated after reaching small
intestine

33
 Metabolic Regulation by the Liver
Liver has primary role in regulating composition of circulating
blood
Blood flows from absorptive areas of digestive tract through
liver where hepatocytes:
– Extract nutrients and toxins from blood
Store and synthesize nutrient molecules
Fat-soluble vitamins (A, D, E, and K) are stored
– Monitor and adjust circulating levels of organic nutrients
High blood glucose triggers synthesis of glycogen
Low blood glucose triggers breakdown of glycogen and release of glucose

34
Hematological Regulation by the Liver
Largest blood reservoir in the body
– Receives about 25 percent of cardiac output

Phagocytic Kupffer cells remove old or damaged RBCs, debris,
and pathogens from blood
Hepatocytes synthesize plasma proteins
– Determine osmotic pressure of plasma
– Function as nutrient transporters
– Key elements of clotting and complement cascades

35
 Movement in Large Intestines
Mass movements
– Common after meals

Local reflexes in enteric plexus
– Gastrocolic: Initiated by stomach
– Duodenocolic: Initiated by duodenum

Defecation reflex
– Distension of the rectal wall by feces

Defecation
– Usually accompanied by voluntary movements to expel feces through
abdominal cavity pressure caused by inspiration

36
Movements of the Large Intestine
Gastroileal and gastroenteric reflexes move material into
cecum
Transit time through large intestine very slow
– Allows for water reabsorption

Mass movements
– Powerful peristaltic contractions
– Occur a few times per day
– Triggered by distention of stomach and duodenum
– Forces feces into rectum, producing urge to defecate

37
 Secretions of Large Intestine

Mucus provides protection
– Parasympathetic stimulation increases rate of goblet cell secretion

Pumps
– Exchange of bicarbonate ions for chloride ions
– Exchange of sodium ions for hydrogen ions

Bacterial actions produce gases called flatus

38
 Two Positive Feedback Loops
Short reflex
Triggers peristaltic contractions in rectum

Long reflex
Coordinated by sacral parasympathetic system
Stimulates mass movements

39
 Defecation Reflex
Involves two positive feedback loops
1. Shorter loop
Stretch receptors in rectal walls stimulate local peristalsis
Moves feces toward anus, distends rectum
2. Longer loop
Stretch receptors stimulate parasympathetic reflex in sacral spinal cord
Stimulate increasing peristalsis and increased distention in rectum

40
 Defecation Reflex
Rectal Stretch Receptors
– Also trigger two reflexes important to voluntary control of defecation
A long reflex
– Mediated by parasympathetic innervation in pelvic nerves
– Causes relaxation of internal anal sphincter
A somatic reflex
– Motor commands carried by pudendal nerves
– Stimulates contraction of external anal sphincter (skeletal muscle)

41
 Defecation Process
Internal anal sphincter relaxes involuntarily
Conscious relaxation of external sphincter required for
defecation
Other conscious actions help force fecal material into rectum
– Tensing abdominal muscles or elevating intra-abdominal pressure
– Valsalva maneuver
Attempting to forcibly exhale with a closed glottis
Repeated bouts of straining to defecate permanently distends veins in the
anal canal, producing hemorrhoids

42
Defecation
Reflex

43
 Control of Digestive Functions
(Local, Neural and hormonal)
Local Factors
– Prostaglandins, histamine, and other chemicals released into
interstitial fluid
May affect adjacent cells within small segment of digestive tract
– Coordinate response to changing conditions
For example, variations in local pH, chemical, or physical stimuli
– Affect only a portion of tract

44
 Control of Digestive Functions
(Local, Neural and hormonal)
Neural Mechanisms
– Control
Movement of materials along digestive tract
Secretory functions
– Motor neurons
Control smooth muscle contraction and glandular secretion
Located in myenteric plexus

45
 Control of Digestive Functions
(Local, Neural and hormonal)
Neural Mechanisms
– Short reflexes
Are responsible for local reflexes
Control small segments of digestive tract
Operate entirely outside of CNS control
– Sensory neurons
– Motor neurons
– Interneurons

46
 Control of Digestive Functions
(Local, Neural and hormonal)
Neural Mechanisms
– Long reflexes
Higher level control of digestive and glandular activities
Control large-scale peristaltic waves
Involve interneurons and motor neurons in CNS
May involve parasympathetic motor fibers that synapse in the myenteric
plexus
– Glossopharyngeal, vagus, or pelvic nerves

47
 Control of Digestive Functions
(Local, Neural and hormonal)
Hormonal Mechanisms
– At least 18 peptide hormones that affect:
Most aspects of digestive function
Activities of other systems
– Are produced by enteroendocrine cells in digestive tract
– Reach target organs after distribution in bloodstream

48
49
 The effect of short bowl
syndrome on GIT function, and
the health of an individual.

MBS 232
Dr KB Makhathini
2020
 Small Intestine
Healthy and intact GIT is essential for maintenance of
health.
GIT digests and absorbs nutrients.
Small intestine is completely formed by 20 weeks of
gestation.
Most intestinal growth prior to birth occurs in the third
trimester.
Before 27 weeks of gestation, the average length of the
small intestine is 115 cm.
2
 Small Intestine
This length increases to approximately 250 cm with a
diameter of 1.5 cm after 35 weeks of gestation.
The mucosal surface area increases with age:
– Infants have 950 cm2
– Adults have 7500 cm2

3
 Small Intestine
Nutrients, vitamin B12, calcium, iron, and bile acids are

absorbed through the cells of the intestinal lining.
The mucus covers the surface of the mucosa cells and acts

as a trap to hold nutrients in contact with the cell surface.
The mucus also acts as a bacterial barrier.

The most crucial factor is the length of the intestine.

The removal of the stomach, jejunum, or colon is better

tolerated than removal of the ileum.

4
 Short bowl syndrome
Definitions:
– Malabsorpative state that may require massive resection of the small
intestine
– Inadequate intestine to maintain normal nutrition by eating.
– State of malabsorption and malnutrition that occurs following massive
anatomical or functional loss of the small intestine.

5
 Short bowl syndrome
Average length of the small bowel is:
– Neonatal 250-300cm in length
– Adult 750-800cm in length

50% or more of the small bowel resected is considered short
bowel syndrome
Infants have more favorable long term prognosis outcomes,
over adult prognosis outcomes

6
 Etiology
The majority of SBS involves anatomical loss of segments of the

small intestine caused by surgical resection.

Functional loss, is a state of decreased motility and resultant

decreased absorption.

7
 Etiology
SBS can be congenital or acquired
Congenital causes of SBS include:
– Intestinal atresia (complete intestinal obstruction / blockage)
– Gastroschisis (congenital defect)
– Omphalocele (congenital defect)
– Hirschsprung’s disease (involves the large intestine - defecation difficulty)

Acquired causes of SBS include:
– Necrotizing Enterocolitis (NEC) (damage to the inner lining of the small or large intestine –
bacterial infection)
– Mid-Gut volvulus (intestinal twisting)
– Ischemic injury (diminished or absent blood flow)
– Crohn’s disease (IBD)
– Radiation enteritis (inflammation of the small or large intestine – radiation treatment)

8
 Pathophysiology
Markedly decreased mucosal surface area due to resection.
Loss of trophic hormones.
Loss of peptide hormones that regulate motility.
Abnormal transit.
Malabsorption of protein, fat, carbohydrate, vitamins,
electrolytes, and trace elements, depending on site of
resected intestine.

9
5 Types of Small Bowel Resections
1. Duodenal Resection
2. Jejunal Resection
3. Ileal Resection
4. Loss of the ileocecal valve
5. Colon

10
 Duodenal Resection
Resection of the Duodenum results in the following deficits:
Protein, Carbohydrates, fat malabsorption
Calcium, Magnesium, Iron, Folate malabsorption
Fat soluble vitamin deficiencies

11
 Jejunum Resection
Jejunum is the site of absorption of most nutrients and
minerals, such as calcium, magnesium, and iron.
With removal of the jejunum, there is loss of some of the
enzymes that break down carbohydrates, which decreases
carbohydrate absorption.
Unfortunately, bacteria can use these unabsorbed
carbohydrates and produce lactic acid.
The absorption of the increased lactic acid can lead to
increased acid in the bloodstream.
12
 Jejunum Resection
Fat and protein digestion may be reduced if the jejunum is
resected.
Calcium and magnesium loss is also increased
Jejunum resection can cause:
– Carbohydrate malabsorption
– Water soluble vitamin deficiencies

13
 Ileum Resection
Carbohydrate, protein, fluid, and electrolytes are also
absorbed in the ileum.
The ileum is the principal source of absorption of bile salts;
vitamin B12; and the fat- soluble vitamins A, D, E, and K.
Removal of most of the ileum results in vitamin B12 and fat-
soluble vitamin deficiencies and diarrhea.
Diarrhea is from both the large volume of fluid passed into
the colon, and the unabsorbed bile salts can cause the
colon to release water.

14
 Ileum Resection
Loss of these bile salts can also result in a decrease in fat
absorption since the bile salts help the intestine to absorb
fats.
The ileocecal valve slows the progress of intestinal fluids
into the colon.
It also increases the pressure gradient between the ileum
and the colon to prevent the colon fluids with high
concentrations of bacteria from moving back up into the
small intestine.
15
 Loss of Ileocecal Valve
Ileocecal Valve or ICV is the filter between the small and large
bowel, located at the end of the ileum.
Patients without an ICV are more at risk of:
– Bacterial Overgrowth or Small Bowel Bacterial Overgrowth (SIBO)
Allows bacteria to reflux from the colon back into the ileum,
Which can result in infection, acidosis, or behavioral changes
– Rapid transit time that exacerbates malabsorption
Loss of ICV may result in rapid transit from the small intestine to large
intestine, which can limit the time for adequate absorption to occur.
Rapid transit results in chronic diarrhea, which at times is watery or non-
formed. For patients with no ICV chronic diarrhea is their normal cycle.
16
 Colon Resection
Colon is the site of absorption of fluid and sodium and the
excretion of potassium and bicarbonate.
Removal of the large intestine has minimal effect on
digestion and absorption.
In SBS, the presence of the colon is of importance because
it increases the absorption of fluids and electrolytes and
decreases diarrhea

17
3 Phases of Short Bowel Syndrome
1. Active Phase
2. Adaptation Phase
3. Maintenance Phase

18
 Active Phase
Starts immediately after bowel resection and lasts 1-3 months
Output is greater than 5 liters per day
– This includes ostomy output if patient has an ostomy (artificially
created via a stoma) – provide examples of ostomies.
Life threatening dehydration and electrolyte imbalances
Extremely poor absorption of all nutrients
Reliant solely on parenteral (intravenous tube) and enteral
(feeding tubes) nutritional feeds for adequate nutrition

19
 Adaptation Phase
Begins 12-24 hours after resection and lasts up to 1-2 years
90% adaptation occurs during this phase
Villus hyperplasia and increased crypt depth occurs resulting
in increased absorptive area
Nutrition is essential for adaptation and should be started as
soon as possible
Parenteral nutrition (intravenous) is essential throughout this
period.

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 Maintenance phase
Absorptive capacity is at a maximum at this phase
Patients start to become more educated about their condition
– Start playing a bigger role in their healthcare.
– Intestinal Rehab is a TEAM effort and not just “doctor’s orders”.
– Come prepared with ideas, options, and questions about how to best
benefit with or manage SBS.

In order to achieve the best results, the patient and the
physician, nutrition specialist and gastroenterologist must be
able to listen to each other, and consider new treatment
options or therapies.
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Diagnosing Short Bowel Syndrome
Multiple different ways for diagnosis of SBS include:
– Lab studies (blood tests, fecal-fat test)
– Microbiology
– Radiology
– Nutrition
– Surgical
– Computerised tomography (CT) scan

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 Surgical Care
Small Bowel Resections
Line Placement/Replacements
Gastrostomy Tube Placement/Replacements (endoscopy)
Non-Transplant Procedures
– Serial Transverse Enteroplasty (STEP) (intestinal cuts)
– Bianchi Procedure (longitudinal incision to the intestine)

Small Intestinal Transplantation
– Isolated Small Bowel Transplant
– Multivisceral Transplant (Stomach, Small, Large, Colon, Liver)
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