A&P Test 2
What is the result of increased venous return
19c
Increased stroke volume
Maintain blood pressure requires:
19c
Cooperation of heart, blood vessels, kidneys and supervision by brain
The main factors influencing blood pressure are...
19c
Cardiac output
Peripheral resistance
Blood Volume
*Changes in one variable are quickly compensated for by changes in other variables
Equation for cardiac output
19c
CO (ml/min) = SV (ml/beat) x HR (beats/min)
Norman CO = 5.0-5.5 L/min
Cardiac Output is determined by
19c
Venous return, neural controls, hormonal controls
During rest, heart rate is maintained by ____________ via _____________
19c
Cardioinhibitory Center via parasympathetic vagus nerves
Stroke volume is controlled by
*During rest
19c
Venous return (EDV)
During Stress, cardioacceleratory center increases __________ and ________ via __________________
19c
increases HEART RATE and STROKE VOLUME via SYMPATHETIC STIMULATION
(During stress) Heart rate _______ via action on _________
19c
INCREASES via action on SA NODE
(During stress) Stroke Volume _______ via enhancement of __________
19c
INCREASES via enhancement of contractility
*ESV decrease (less blood in left ventricle)
What factor does exercise play in enhancing cardiac output
19c
-Increased activity of respiratory pumps (ventral body cavity pressure)
-Increased activity of muscular pump (skeletal muscle)
-Increased sympathetic venoconstriction
Then...
-Increased venous return
Then...
-Increased EDV
Then..
Increased stroke volume
Results in...
-Increased Cardiac output
What factor does the following play a role in enhancing cardiac output
Decreased BP activates cardiac centers in medulla
19c
A)
-Increased sympathetic activity
Then...
-Increased epinephrine in blood
Then..
-Increased contractility of cardiac muscle
Then...
-Decreased ESV
Then..
-Increased Stroke volume
Results in...
-Increased Cardiac output
B)
-Decreased parasympathetic activity
Then...
-Increased heart rate
Results in...
-Increased Cardiac output
What are the 2 processing in Blood pressure regulation
19c
1) Short-term Regulation
2) Long-term Regulation
Short-term Regulation has 2 controls...
19c
1) Neural (nervous) control
2) Hormonal (endocrine) controls
Short-term regulation counteracts fluctuations in blood pressure by:
19c
-Changing peripheral resistance
-Changing cardiac output
Name the control that is involved in long-term regulation
19c
-Renal control
Long-term regulation counteracts fluctuations in blood pressure by
19c
-Changing blood volume
Neural controls alter _________ and ___________ .
19c
Cardiac Output and Peripheral Resistance
In what two ways do neural controls alter cardiac output and peripheral resistance
19c
1) Alter blood vessel diameter
-If blood volume is low, all vessels constrict
-Except those to heart and brain
2) Alter blood distribution to organs
-In response to specific demands
-Blood is shunted from digestive tract to skeletal muscles during exercise
Neural Controls operate via ______
(short term)
19c
Reflex arcs that involve...
-Baroreceptors (stretch receptors)
-Cardiovascular center of medulla oblongata (vasomotor center)
-Autonomic vasomotor fibers to heart and vascular smooth muscle
-Sometime input from chemoreceptors and higher brain centers
There are clusters of ___________ in the medulla oblongata
(short term)
19c
Sympathetic neuron
*Causes changes in CO and blood vessel diameter
The clusters of sympathetic neurons in medulla oblongata consists of...
(short term)
19c
-Cardiac Centers
.Cardioacceleratory (sympathetic)
--> SA node, AV node, myocardium
--> Increases heart rate and force of contraction
.Cardioinhibitory (parasympathetic)
--> Vagus nerve --> SA node, AV node
--> Decreases heart rate
-Vasomotor Center
--> Regulates diameter of blood vessels
Cardiovascular center receives inputs from
19c
Baroreceptors
Chemoreceptors
Higher brain centers
Baroreceptors
19c
(pressure-sensistive mechanoreceptors)
-Respond to changes in arterial pressure and stretch
Chemoreceptors respond to changes in
19c
Blood levels of carbon dioxide, H+, and oxygen
Higher brain centers include the following and respond to ...
19c
Include - Cerebral cortex, limbic system, hypothalamus
respond to exercise, stress, emotions, body temperature
Locations of baroreceptors:
19c
- Carotid Sinuses (dilations in internal carotid arteries --> Major blood supply to brain)
- Aortic Arch
- Walls of large arteries of neck and torax
In what 3 ways do baroreceptor reflexes decrease BP
19c
1) Cause arterioles to dilate
.By inhibiting vasomotor center
.This decreases peripheral resistance
2) Cause veins to dilate
.By inhibiting vasomotor center
.This decreases venous return and cardiac output
3) decrease heart rate and contractile force
.By inhibiting sympathetic (cardioacceleratory) activity and stimulating parasympathetic (cardioinhibitory) activity
.This decreases cardiac output
Chemoreceptors in carotid and aortic bodies detect:
(short term)
19c
Increase in CO2
Decrease in pH
Decrease in O2 (sudden drop)
Chemoreceptor reflexes (short term) increase blood pressure by stimulating
19c
-Cardioacceleratory center
-->Causes increased cardiac output
-Vasomotor center
-->Causes vasoconstriction (sympathetic
Reflexes regulating BP involve
(influence of higher brain centers)
19c
Medulla oblongata
What can modify arterial pressure?
(influence of higher brain centers)
19c
Hypothalamus
Cerebral cortex
Limbic system
-->Via relays to medulla oblongata
Does the hypothalamus increase OR decrease BP during stress?
(influence of higher brain centers)
19c
Increase
Hypothalamus mediates redistribution of _____________ during _________ and what changes?
(influence of higher brain centers)
19c
Mediates redistribution of blood flow during exercise and body temperature changes
What are hormones that cause increased blood pressure?
(hormonal controls of BP - short term)
19c
-Epinephrine/norepinephrine
-Angiotensin II
-Antidiuretic Hormone
How does epinephrine/norepinephrine cause an increase in BP?
19c
Increase CO & vasoconstriction
Released from adrenal medulla during stress
How does angiotensin II cause an increase in BP?
19c
Vasoconstriction
Low BP
Kidneys release renin
How does antidiuretic hormone (ADH) cause an increase in BP?
19c
Kidneys conserve more water causing vasoconstriction when BP falls to dangerously low levels (hemorrhage)
*Released from hypothalamus/posterior pituitary
Hormones causing decreased blood pressure
(hormonal controls of BP - short term)
19c
Atrial Natriuretic Peptide (ANP)
How does Atrial Natriuretic Peptide (ANP) decrease blood pressure
(hormonal controls of BP - short term)
19c
It is released from the heart
Antagonizes aldosterone --> causes kidneys to excrete more sodium and water --> decreases blood volume and BP
*Also causes generalized vasodilation
Kidneys maintain blood pressure by
(Renal Regulation of BP - Long Term)
19c
Regulating blood volume
What are the two methods of renal control?
(Renal Regulation of BP - Long Term)
19c
1. Direct renal mechanism
2. Indirect renal mechanism
---> (Renin-angiotensin-aldosterone mechanism)
Direct Renal mechanism alters blood volume without...
19c
Hormones
Increased BP or blood volume causes...
(Direct Renal Mechanism - Long Term)
19c
Elimination of more urine due to increased filtration --> Decreases blood volume and BP
Decreased BP or blood volume causes...
(Direct Renal Mechanism - Long Term)
19c
Kidneys to conserve water --> increases blood volume and BP
Indirect Renal Mechanism is also known as ...
(Renal Regulation of BP - Long Term)
19c
Renin-angiotensin-aldosterone mechanism
Decreased arterial blood pressure ...
(Indirect Renal Mechanism - Long Term)
19c
--> Release of renin (enzyme) from kidneys
--> Renin causes production of angiotensin II
.Angiotensinogen (plasma protein)
-Renin
.Angiotensin I
-Angiotensin converting Enzyme (ACE)
.Angiotensin II
Angiotensin II increases blood volume (and thus increases BP) by stimulating...
(Indirect Renal Mechanism - Long Term)
19c
-Adrenal cortex to secrete aldosterone
.Increases reabsorption of sodium/water by kidneys
-Stimulates posterior pituitary to release ADH
.Increases water reabsorption by kidneys
-Stimulates hypothalamic thirst center
.Increases water consumption
Angiotensin II increases blood pressure directly and causes
(Indirect Renal Mechanism - Long Term)
19c
vasoconstriction
--> Increases peripheral resistance
Autoregulation is controlled intrinsically by
19c
Modifying diameter of arterioles feeding capillaries
Organs regulate their own blood flow by
19c
varying resistance of own arterioles
What are the 2 types of auto regulation
19c
1) Metabolic (chemical) controls
-Responds to changing levels of chemicals
2) Myogenic (physical) controls
-Respond to stretch
All info on metabolic (chemical) controls
19c
– Respond to changing levels of chemicals
– Vasodilation of arterioles and relaxation of precapillary sphincters caused by:
• Decreased tissue O2
• Increased H+, CO2, lactic acid, K+, adenosine, prostaglandins
• Inflammatory chemicals (histamine, kinins, prostaglandins)
• Nitric oxide (NO) – major controller of vasodilation
– Released by vascular endothelium (can override sympathetic)
– Vasoconstriction is caused by:
• Endothelins released from endothelium (to prevent blood loss in injury)
All info on myogenic (physical) controls
19c
Keep tissue perfusion constant despite changes in systemic pressure
• Increased intravascular pressure promotes vasoconstriction
– Decreases blood flow to the tissue
• Decreased intravascular pressure promotes vasodilation
– Increases blood flow to the tissue
Long-term auto regulation occurs with
19c
Occurs when short-term autoregulation cannot meet tissue nutrient requirements
Long-term auto regulation develops over
19c
Develops over weeks or months
Angiogenesis
(Long-term auto regulation)
19c
– Number of vessels to region increases
– Existing vessels enlarge
– Common in
• Heart when coronary vessel partially occluded
• Throughout body in people in high-altitude areas
Blood flow to skeletal muscles increases in response to
19c
greater metabolic activity -->
– Increased metabolic activity causes decreased O2 and increased metabolic wastes
– Metabolic controls cause relaxation and dilation
of skeletal muscle arterioles to supply more O2 and nutrients to muscles
Blood flow to digestive and urinary tracts decreases to
19c
divert blood to skeletal muscles
– Sympathetic activity increases with exercise
--> vasoconstriction of digestive/urinary tracts
Circulatory shock is any condition is which
19c
– Blood vessels are inadequately filled
– Blood cannot circulate normally
• Results in inadequate blood flow to meet tissue needs --> cells die
-Hypovolemic shock
-Vascular shock
-Cardiogenic shock
Hypovolemic shock results from
19c
large-scale blood or fluid loss
– Hemorrhage, burns, severe vomiting or diarrhea
Vascular shock results from
19c
extreme vasodilation and decreased peripheral resistance
– Anaphylaxis, septicemia
Cardiogenic shock results when
19c
an inefficient heart cannot sustain adequate circulation
– Myocardial damage
The lymphatic system returns
20
Returns excess interstitial fluid and leaked plasma proteins
back to circulatory system (~3 L per day)
What are the 3 parts of the lymphatic system?
20
• Lymphatic vessels (lymphatics)
• Lymph – fluid in vessels
• Lymph nodes – cleanse lymph as passes
What are the lymphoid organs and tissues?
20
Spleen, thymus, tonsils, Peyer's patches, appendix, and lymphoid tissues
House phagocytic cells and lymphocytes
What do the lymphoid organs and tissues provide
20
Structural basis of immune system
Lymph vessels (lymphatics) include:
20
Lymphatic capillaries
Collecting lymphatic vessels
Lymphatic trunks
Lymphatic ducts
The lymphatic system is a one-way system - meaning...
20
Lymph flows toward the heart
Info on Lymphatic capillaries
20
• Weave between tissue cells and capillaries
• Absent from bones, teeth, bone marrow, and CNS
• Similar to blood capillaries, except:
– Blind-ended
– Very permeable
• Proteins, cell debris, pathogens, cancer cells enter lymphatics
What makes lymphatic vessels so permeable?
20
– Endothelial cells overlap loosely
• Form one-way, flaplike minivalves
– Collagen filaments anchor endothelial cells to surrounding structures
• Prevent collapse of capillaries
• Open minivalves when interstitial fluid volume/pressure increases
Pathogens can travel throughout the body via
20
Lymphatics
--> Lymph nodes serve to "cleanse" and "examine"
What are lacteals?
20
– Specialized lymph capillaries present in
small intestinal villi
– Absorb digested fat and deliver fatty lymph (chyle) to the blood
Lymphatic collecting vessels are similar to veins, except...
– Have thinner walls
– Have more internal valves
– Anastomose more frequently
Collecting vessels in skin travel with
superficial veins
Deep vessels travel with
arteries
Distribution of lymphatic vessels varies between
individuals
Lymphatic trunks are formed by...
Uniion of largest collecting vessels
Lymphatic trunks drain
large areas of the body
Name the "paired lymphatic" trunks
– Lumbar
– Bronchomediastinal
– Subclavian
– Jugular trunks
Name the "single" lymphatic trunk
Intestinal trunk
How many lymphatic ducts are there?
2
Right Lymphatic duct
Thoracic duct
*Lymph is delivered into either of the ducts
The right lymphatic duct drains
Right arm and right side of head and thorax
Thoracic duct drains
rest of body
-Superiorly, it drains left thorax, left arm, and left side of head
The thoracic duct arises as
Cisterna chyli
– Enlarged sac anterior to first two lumbar vertebra
– Collects lymph from legs and digestive organs
Each duct empties lymph into
Venous circulation
– At junction of internal jugular and subclavian veins
– On its own side of body
Lymph is propelled by
– Milking action of skeletal muscle
– Pressure changes in thorax during breathing
– Valves that prevent backflow
– Pulsations of nearby arteries
– Contractions of smooth muscle in walls of lymphatic vessels
Lymphoid cells are aka
lymphocytes
Lymphocytes are...
The main warriors of the immune system
-Arise in red bone marrow
Lymphocytes mature into one of two main varieties
– T cells (T lymphocytes)
– B cells (B lymphocytes)
Lymphoid cells protect against
antigens
– Anything the body perceives as foreign and that provokes an immune response
• Bacteria, bacterial toxins, viruses, cancer cells,
mismatched RBCs
T cells...
– Manage immune response
– Attack and destroy infected cells
B Cells
– Produce plasma cells
• Which secrete antibodies
Macrophages
– Phagocytize foreign substances
– Help activate T cells
Dendritic cells
– Capture antigens
– Deliver them to lymph nodes
Reticular cells (fibroblast-like cells)
– Produce reticular fiber stroma
• Network supporting other cells in lymphoid organs
Lymphoid tissue houses and provides
proliferation site for lymphocytes
lymphoid tissue is a surveillance vantage point for
lymphocutes/macrophages
Lymphoid tissue is composed mainly of what type of tissue?
Reticular connective
– Macrophages live on fibers
– Lymphocytes squeeze through postcapillary venules, rest in lymphoid spaces, then return to blood
• Movement allows lymphocytes to reach infected or damaged tissues
What are the 2 main types of lymphoid tissue
1. Diffuse lymphoid tissue
2. Lymphoid follicles
Info on diffuse lymphoid tissue
– Scattered lymphoid cells and reticular fibers
• In ~ every body organ
– Larger collections in lamina propria of mucous membranes (digestive tract)
Info on lymphoid follicles (nodules)
– Solid, spherical bodies
• Of tightly packed lymphoid cells and reticular fibers
– Germinal centers of proliferating B cells
• Plasma cells --> antibodies
– May form part of larger lymphoid organs or nodes
– Isolated aggregations in intestinal wall (Peyer's patches) and in appendix
What are the principal lymphoid organs of the body
Lymph nodes
Lymph nodes are embedded in
connective tissue
Lymph nodes are clustered along
lymphatic vessels
3 regions of lymph nodes
Inguinal region
Axillary region
Cervical region
Functions of lymph nodes
Filtration
– Filter lymph as it is transported
– Macrophages destroy microorganisms and debris so they don’t enter bloodstream
Immune system activation
– Lymphocytes become activated and mount
attack against antigens
Structure of lymph node
• Bean shaped
• External fibrous capsule
• Trabeculae (connective tissue strands)
extend inward
– Divide node into compartments
• Two histologically distinct regions
– Cortex
– Medulla
The cortex contains
- Lymphoid follicles with germinal centers (with dividing B cells)
- Dendritic cells surround follicles
– Rest of cortex is primarily T cells in transit
• T cells circulate continuously among blood, lymph nodes, and lymph
Medullary cords extend inward from the
Cortex
The medulla contains what kind of cells
B Cells
T Cells
Plasma Cells
Lymph sinuses in the medulla contain
macrophages
Lymph enter via
afferent lymphatic vessels
Lymph travels through
large subcapsular sinus and smaller sinuses to medullary sinuses
Lymph extis at hilum via
efferent lymphatic vessels
What does having fewer efferent vessels do
Stagnates flow which allows lymphocytes and macrophages time to function
Which lymphoid organ is not composed of reticular connective tissue?
Thymus
The spleen, thymus, tonsils, peyer's patches and appendix help with what?
They help protect the body but do not filter lymph
-Have efferent lymphatics
-No afferent lymphatics
Info on spleen
• Largest lymphoid organ
• Structure
– Fibrous capsule and trabeculae
– White pulp - contains lymphocytes
– Red pulp – contains macrophages, many old erythrocytes
• Served by splenic artery and vein (enter/exit at its hilum)
Functions of spleen
– Site for lymphocyte proliferation
– Immune surveillance and response
– Cleanses blood of:
• Aged/defective blood cells and platelets
• Debris and foreign matter
– Removed by macrophages
Additional functions of the spleen
• Stores breakdown products of RBCs
– For later reuse
– Iron to make more hemoglobin
• Stores blood platelets and monocytes
– For release into blood when needed
• May be site of fetal erythrocyte production (normally ceases before birth)
The thymus is important during
early in life
– T lymphocyte presursors mature into immunocompetent lymphocytes
Thymus is found in
inferior of neck
– Extends into mediastinum
– Partially overlies heart
The thymus is prominent in
Newborns
– Increases in size during first year
– Most active during childhood
– Gradually atrophies after puberty
• Becomes fibrous and fatty tissue
– Still produces immunocompetent cells, though slowly
Other info on thymus
• Bilobed
• Thymic lobules - outer cortex, inner medulla
• Most thymic cells are lymphocytes
• Cortex contains rapidly dividing lymphocytes and scattered macrophages
• Medulla contains fewer lymphocytes and
thymic corpuscles
– Concentric whorls of keratinized epithelial cells
– Involved in development of regulatory T cells (prevent autoimmunity)
How does the thymus differ from other lymphoid organs
• Has no follicles because it lacks B cells
• Does not directly fight antigens
– Functions only in T lymphocyte maturation
• Blood thymus barrier
• Keeps bloodborne antigens out of thymus to prevent premature activation of lymphocytes
• Stroma made of epithelial cells
(not reticular fibers)
What does MALT stand for
Mucosa-Associated Lymphoid Tissue
Info on MALT
• Lymphoid tissues in mucous membranes
• Protects from pathogens trying to enter body
• Largest collections of MALT in
– Tonsils
– Peyer's patches – Appendix
• Also in mucosa of respiratory and genitourinary organs and rest of digestive tract
What is the simplest lymphoid organs
tonsils
Tonsils from a ring of what type of tissue around pharynx
lymphatic
Location of palatine tonsils
At posterior end of oral cavity
Location of lingual tonsils
At base of tongue
Location of pharyngeal tonsils
in posterior wall of nasopharynx
• “Adenoids”
Location of tubal tonsils
surround openings of auditory tubes into pharynx
What are the tonsils role with pathogens
They gather and remove pathogens in food or air
Other info on tonsils
• Follicles with germinal centers
• Not fully encapsulated
• Overlying epithelium invaginates forming tonsillar crypts
– Trap and destroy bacteria and particulate matter
– Immune cells build memory for pathogens
• Fighting pathogens in childhood leads to increased immunity later in life
Where are groups of lymphoid follicles
Peyers patches and appendix
Where are groups of lymphoid follicles in the peyer's patches
-In wall of distal small intestine (ileum)
Where are groups of lymphoid follicles in the appendix
– Tubular appendage at beginning of large
intestine
What do peyer's patches and the appendix do with the aggregates of lymphoid follicles
– Destroy bacteria, preventing them from breaching intestinal wall
– Generate "memory" lymphocytes
What is the function of the the Lymphatic System
To return excess interstitial fluid and leaked plasma proteins back to circulatory system and allow the tissue fluid to be filtered by the lymph nodes
What is contained in lymph
Fluid
List the major components of the lymphatic system and some accessory lymphoid organs.
Provide structural basis of immune system
House phagocytic cells and lymphocytes
Include spleen, thymus, tonsils, and other lymphoid tissues
How does flow in the lymphatic system differ from flow in the circulatory system?
One-way system – lymph flows to the heart
Why are lymphatic capillaries so permeable?
Endothelial cells overlap loosely → form one-way, flaplike minivalves
Collagen filaments anchor endothelial cells
What molecules can pass through lymphatic capillaries but not through blood capillaries?
Pathogens
Name four tissues where lymphatic capillaries are absent.
Bones, teeth, bone marrow and CNS
Define lacteals. What is their function?
Specialized lymph capillaries present in small intestinal villi
They absorb digested fat and deliver fatty lymph (chyle) to the blood
Lymphatic collecting vessels are similar to what blood vessel? Compare them.
Similar to veins, except:
-Have thinner walls
-Have more internal valves
-Anastomose more frequently
Collecting vessels in skin travel with superficial veins
Deep vessels travel with arteries
Distribution of lymphatic vessels varies between individuals
Name the lymphatic trunks that are paired
Lumbar
Bronchomedialstinal
Subclavian
Jugular Trunks
Name the single lymphatic trunks
Intestinal Trunk
Name the lymphatic ducts and state which body regions are drained by each duct.
Right lymphatic duct
Drains right arm and right side of head and thorax
Thoracic duct
Drains rest of body
Where do T lymphocytes and B lymphocytes mature?
Thymus
Describe the histologic composition of lymphoid tissue.
What are the functions of lymphoid tissue?
Houses and provides proliferation site for lymphocytes
Surveillance vantage point for lymphocytes/macrophages
Composed mainly of reticular connective tissue
Two main types:
Diffuse lymphoid tissue
Lymphoid follicles
Differentiate between diffuse lymphoid tissue and lymphoid follicles (nodules).
What type cell predominates in follicles?
- Diffuse lymphoid tissue:
Scattered lymphoid cells and reticular fibers
In apporoximately every body organ
Larger collections in lamina propria of mucous membranes
- Lymphoid Follicles (nodules)
Solid, spherical bodies of tightly packed lymphoid cells and reticular fibers
May form part of larger lymphoid organs or nodes
What are the principle lymphoid organs of the body? Where are they located?
Spleen, thymus, tonsils
Name three areas where clusters of lymph nodes can be palpated near the body surface.
Inguinal region
Axillary Region
Cervical Region
Describe the functions of lymph nodes.
Filtration
Immune system activation
Describe the gross and histological structure of lymph nodes.
Bean shaped
External fibrous capsule
Two histologically distinct regions:
Cortex
Medulla
What is the benefit of having fewer efferent than afferent lymphatic vessels in lymph nodes?
Allows lymphocytes and macrophages time to function
Which lymphoid organ is the only one that filters and cleanses lymph?
Lymph Nodes
What is the largest lymphoid organ? Describe its structure and cells.
Spleen
Structure:
Fibrous capsule and trabeculae
White pulp – contains lymphocytes
Red pulp – contains macrophages, may old erythrocytes
Served by by splenic artery and vein (enter/exit at its hilum)
List the functions of the spleen.
Removes old and damaged RBCs
Site for lymphocyte proliferation
Immune surveillance and response
What is the only function of the thymus?
Development of T cells
What is the main cell found in the thymus?
Lymphocytes
Compare the histological structure of the thymus to other lymphoid organs
Thymus has no follicles because it lacks B cells
Does not directly fight antigens
Stroma made of epithelial cells
Define MALT. What is its function? Where are the largest collections of MALT found in the human body?
Mucosa-Associated Lymphoid Tissues
Lymphoid tissues in mucous membranes
Protects from pathogens trying to enter body
Largest collections of MALT:
Tonsils
Peyer’s Patches
Appendix
Name the four tonsils.
Palatine Tonsils – At posterior end of oral cavity
Lingual Tonsils – At base of tongue
Pharyngeal Tonsils – in posterior wall of nasopharnyx (adenoids)
Tubal Tonsils – Surrond opening of auditory tissues into pharynx
What are tonsillar crypts and what are their functions?
- Trap and destroy bacteria and particulate matter
- Immune cells build memory for pathogens (fighting pathogens in childhood leads to increased immunity later in life)
How do the tonsils help to strengthen immunity later in life?
- Trap and destroy bacteria and particulate matter
- Immune cells build memory for pathogens (fighting pathogens in childhood leads to increased immunity later in life)
Where are Peyer’s Patches located?
In wall of distal small intestine (ileum)
Where is the appendix?
Tubular appendage at beginning of large intestine
List the functions of Peyer’s Patches and the appendix.
- Destroy bacteria, preventing them from breaching intestinal wall
- Genterate “memory” lymphocytes
What 2 organs does the digestive system consist of?
Alimentary Canal - Gastroentestinal (GI) tract
Accessory Digestive Organs
What are the accessory digestive organs?
Teeth
Tongue
Gallbladder
Digestive glands
-Salivary Glands
-Liver
-Pancreas
Describe the Alimentary Canal
– Muscular tube from mouth to anus
– Digests food and absorbs nutrients
– Mouth, pharynx, esophagus, stomach, small intestine, large intestine, anus
What are the 6 essential activities of the digestive processes
1. Ingestion
2. Propulsion
3. Mechanical Breakdown
4. Digestion
5. Absorption
6. Defecation
Describe ingestion
taking food into digestive tract via the mouth
Describe propulsion
movement of food through GI tract
Describe mechanical breakdown
reduction of food to smaller pieces to increase surface area for digestion
Describe digestion
chemical breakdown of food by enzymes
Describe absorption
active or passive transport of nutrients, vitamins, minerals, and water from GI tract lumen into blood or lymph
Describe defecation
elimination of indigestible substances from the body via the anus in the form of feces
Peristalsis
Adjacent segments of alimentary tract organs alternately contract and relax, moving food along the tract distally. Major means of propulsion.
Segmentation
Nonadjacentsegments of alimentary tract organs alternately contract and relax, moving food forward then backward. Food mixing and
slow food propulsion occurs
GI Tract Regulatory Mechanisms
Mechanoreceptors and Chemoreceptors
Intrinsic and extrinsic controls
Where are mechanoreceptors and chemoreceptors located
In the walls of GI tract
Mechanoreceptors and chemoreceptors respond to
Stretch
Changes in osmolarity and pH
Presence of substrate and end products of digestion
Mechanoreceptors and chemoreceptors initiate reflexes that
• Activate or inhibit digestive glands
• Stimulate smooth muscle to mix and move contents
Describe intrinsic and extrinsic controls
– Nerve plexuses (“gut brain”) respond to stimuli in GI tract to regulate GI tract activity via short reflexes
– CNS centers and autonomic nerves respond to stimuli inside or outside GI tract via long reflexes
– Stomach and small intestine release hormones
that stimulate target cells in same or different organs, causing them to secrete or contract
describe the peritoneum
– Serous membrane of abdominal cavity
– Visceral peritoneum covers external surfaces of most digestive organs
– Parietal peritoneum lines body wall
Describe Peritoneal cavity
– Narrow space between the two peritoneums
– Serous fluid lubricates organs
Describe the mesentery
- double layer of peritoneum
– Extends from body wall to digestive organs
– Routes for blood vessels, lymphatics, and nerves
– Holds organs in place
– Stores fat
Describe the Retroperitoneal organs
- partially surrounded
– Lie against posterior abdominal wall
– Pancreas, duodenum, part of large intestine
Describe the Intraperitoneal (peritoneal) organs
– Completely surrounded by peritoneum
Some organs...
lose their mesentery and move,
becoming retroperitoneal, during development.
What are the parts of the mesentery
Greater Omentum
Lesser Omentum
Falciform ligament
Mesentery Proper
Mesocolon
Describe the greater omentum
“fatty apron”
– Extends from greater curvature of stomach
– Covers most abdominal organs
Describe the lesser omentum
– Connects lesser curvature of stomach and proximal duodenum to liver
Describe the falcofrom ligament
- Attaches the lier to the anterior abdominal wall
Describe the mesentery proper
– Fan-shaped peritoneum that suspends jejunum and ileum from posterior abdominal wall
Describe the mesocolon
– Attaches large intestine to posterior abdominal wall
Blood supply - The splanchnic circulation
• Arteries
– Hepatic, splenic, left gastric arteries
• Branches of celiac trunk
• Supply corresponding organ
– Inferior mesenteric artery
• Supplies small intestine
– Superior mesenteric artery
• Supplies large intestine
• Hepatic portal circulation
– Drains nutrient-rich blood from digestive organs
– Delivers it to the liver for processing
Four basic layers (tunics) of the alimentary canal
– Mucosa
– Submucosa
– Muscularis externa
– Serosa
Describe the mucosa
• Innermost layer that lines the lumen
• Functions
– Secretes mucus, digestive enzymes, hormones
– Absorbs end products of digestion
– Protects against infectious disease
What are the 3 sub layers of the mucosa
-Epithelium
-Lamina Propria
-Muscularis mucosae
Describe the Epithelial layer of the mucosa
– Simple columnar epithelium with mucus-secreting cells
– Exception – stratified squamous in mouth, esophagus, anus
– Mucus protects from enzymes and eases food passage
– May synthesize and secrete enzymes and hormones
• Stomach and small intestine
Describe the lamina propria layer of the mucosa
– Loose areolar connective tissue
– Capillaries for nourishment and absorption of nutrients
– Lymphoid follicles (part of MALT) defend against pathogens
Describe the muscularis mucosae of the mucosa
– Thin layer of smooth muscle
Describe the submucosa
• Areolar connective tissue
• Rich supply of:
– Blood vessels
– Lymphatic vessels
– Lymphoid follicles
– Nerve fibers
– Elastic fibers (in stomach for stretching)
Describe the muscularis extern (muscularis)
• Composed of two layers of smooth muscle
– Inner circular
• Thickens in some areas to form sphincters
– Outer longitudinal layer
• Responsible for segmentation and peristalsis
Describe the serosa
• Visceral peritoneum
• Areolar connective tissue
– Covered with mesothelium in most organs
• Simple squamous epithelium
• Replaced by adventitia in esophagus
– Fibrous connective tissue
The enteric nervous system of the alimentary canal
• Intrinsic nerve supply of alimentary canal regulates digestive system activity - enteric neurons
• Linked to CNS via afferent visceral fibers
• Long ANS fibers synapse with enteric plexuses
– Sympathetic impulses inhibit digestive activities
– Parasympathetic impulses stimulate digestive activities
Submucosal nerve plexus
– In submucosa
– Regulates glands and smooth muscle in mucosa
Myenteric nerve plexus
– Between circular and longitudinal layers of muscularis
– Controls GI tract motility
info on mouth = oral (buccal) cavity
• Bounded by lips, cheeks, palate, tongue
• Oral orifice is anterior opening
• Lined with stratified squamous epithelium
– Produces defensins – antimicrobial peptides
Lips (labia) and checks
– Orbicularis oris (lips) and buccinator (cheeks) muscles
– Vestibule - recess bounded externally by lips and cheeks, internally by teeth and gums (gingiva)
– Labial frenulum – median fold that attaches lip to gum
The oral cavity proper lies within
teeth and gums
Palets from the .....
Roof of the mouth
Hard palate – anterior part
– Formed by palatine bones and palatine processes of maxillae
– Midline ridge - raphe
– Mucosa is slightly corrugated to create friction against tongue during chewing
Soft palate - posterior part
– Fold formed mostly of skeletal muscle
– Rises and closes nasopharynx during swallowing
– Uvula projects downward from its free edge
The tongue is composed of
Skeletal muscle
Functions tongue
– Positioning of food between teeth
– Mixing of food with saliva
– Formation of bolus (compact mass of food) – Initiation of swallowing
– Speech production
– Taste
What is lingual frenulum
– Attaches tongue to floor of mouth and limits posterior movements
Structure of the tongue and list the 4 types of papillae
Surface bears papillae (peglike projections of underlying mucosa)
-Filiform papillae
-Fungiform papillae
-Circumvallate (vallate) papillae
-Foliate Papillae
Describe the filiform papillae
– smallest and most numerous
– Contain keratin – stiffens and makes tongue whitish
– Roughens tongue surface/provides friction to manipulate foods
– Do not contain taste buds
Describe fungiform papillae
- reddish, mushroom shaped
– Scattered over tongue
– Contain taste buds
Describe circumvallate (vallate) papillae
– ten to twelve
– V-shaped row at back of tongue
– Contain taste buds
Describe Foliate papillae
– pleatlike, on lateral aspect of posterior tongue
– Contain taste buds that function only in infants and children
Where is the terminal sulcus
on the tongue
Describe the terminal sulcus
– Just posterior to vallate papillae
– Groove that marks division between
• Body - anterior 2/3 tongue in oral cavity
• Root - posterior third of tongue in oropharynx
– Mucosa covering root of tongue lacks papillae
• Bumpy due to lingual tonsil deep to mucosa
Describe lingual lipase
– Secreted by serous cells beneath foliate and vallate papillae
– Fat-digesting enzyme that becomes functional in acid of stomach
Major or extrinsic salivary glands lie outside the
Oral cavity
Major or extrinsic salivary glands empty secretions into the oral cavity via
ducts
These salivary glands produce the most saliva
- Parotid
- Submandibular
- Sublingual
Minor or intrinsic salivary glands are ______ throughout ___________________.
Are scattered though out oral cavity mucosa
Minor or intrinsic salivary glands augment
salivary output
Functions of saliva
– Cleanses the mouth
– Dissolves food chemicals for taste
– Moistens food
– Compacts food into bolus
– Begins chemical breakdown of starch
Controls of salivation
– Parasympathetic nervous system
• Stimulates secretion of saliva
– Sympathetic nervous system
• Inhibits secretion of saliva
Info on parotid gland
– Anterior to ear and external to masseter muscle
– Parotid duct parallels zygomatic arch
• Duct opens into vestibule next to second upper molar
– Facial nerve branches run through parotid gland
• Parotid surgery may cause facial paralysis
– Mumps virus causes inflammation of parotid glands
Info on submandibular glands
– Medial to body of mandible
– Duct opens at base of lingual frenulum
Info on sublingual gland
– Anterior to submandibular gland under tongue
– Opens via 10–12 ducts into floor of mouth
Composition of saliva
• Mostly water and slightly acidic
– Electrolytes (Na+, K+, Cl–, PO4 2–, HCO3–) – Salivary amylase
– Lingual lipase
– Mucin – forms mucus in water
• Lubricates oral cavity and hydrates food
– Metabolic wastes (urea and uric acid)
– Lysozyme – bacteriocidal enzyme
• Inhibits bacterial growth and prevents tooth decay
– IgA antibodies
– Defensins
Teeth _______ and ________ food for ______
Teeth TEAR and GRIND food for digestion
Primary and permanent dentitions are formed by age
21
Teeth are served by branches of
maxillary artery and trigeminal nerve (cranial nerve V)
what are incisors
– Chisel shaped for cutting
What are canines
(cuspids or eye-teeth) – Fanglike teeth that tear or pierce
What are premolars (bicuspids)
– Broad crowns, rounded cusps – grind/crush
What are molars
– Broad crowns, rounded cusps – best grinders
Structure of crown
- exposed part above gum (gingiva)
– Covered by enamel—hardest substance in body
– Calcium salts and hydroxyapatite crystals
Structure of root
- portion embedded in jawbone
– Connected to crown by neck (constricted region)
Structure of cement
- calcified connective tissue
– Covers root
– Attaches tooth to periodontal ligament
Structure of periodontal ligament
– Forms fibrous joint called gomphosis
– Anchors tooth in bony socket (alveolus)
Structure of gingival sulcus
- groove where gingiva borders tooth
Structure of dentin
- bonelike material under enamel
– Maintained by odontoblasts of pulp cavity
• Produced throughout life
Structure of pulp cavity
- Surrounded by dentin
Structure of pulp
-connective tissue, blood vessels, nerves
Structure of root canal
– extension of pulp cavity into root
Structure of apical foramen
- at proximal end of root
– Entry for blood vessels and nerves
How many roots do the canine, incisor and premolars have
One root
-First upper premolar often has two
How many roots do the first two upper molars have
Three roots
How many roots do the first two lower molars have
Two roots
How many roots do the third molars have
It varies
-Usually single fused root
Describe Dental Cavities
Demineralization of enamel and dentin from bacterial action
– Dental plaque adheres to teeth
• Film of sugar, bacteria, and debris
– Bacterial metabolism produces acids that dissolve calcium salts
– Bacterial enzymes digest organic matter
– Prevention - daily flossing and brushing
Describe gingivitis
- red, swollen, sore, bleeding gums
– Plaque calcifies to form calculus (tartar)
• Disrupts seal between gingivae and teeth
– Anaerobic bacteria infect gums
– Infection reversible if calculus removed
Describe periodontitis (periodontal disease)
neglected gingivitis
– Immune cells attack intruders and body tissues
• Destroy periodontal ligament
• Activate osteoclasts
How does food pass from the mouth
Mouth --> Oropharynx --> Laryngopharynx
The pharynx is a common passageway for
Food, fluids, and air
What cells are in the pharynx
• Stratified squamous epithelium (inner lining)
– Mucus-producing glands
What skeletal muscle layers are involved in the pharynx
– Inner longitudinal
– Outer pharyngeal constrictors
• Contractions propel food into esophagus
Describe the esophagus
• Flat muscular tube
• From laryngopharynx to stomach
• Pierces diaphragm at esophageal hiatus • Joins stomach at cardial orifice
• Gastroesophageal (cardiac) sphincter
– Surrounds cardial orifice
– Reinforced by presence of diaphragm
What happens during heartburn
– Stomach acid regurgitates into esophagus
– Excess food/drink, extreme obesity, pregnancy, running
– Hiatal hernia - structural abnormality
• Part of stomach protrudes above diaphragm
–Weakened gastroesophageal sphincter
• May lead to esophagitis, esophageal ulcers, esophageal cancer
What type of cells is the mucosa made of
- stratified squamous epithelium
– Changes to simple columnar at stomach
What type of cells is the submucosa - esophageal glands
– Secrete mucus to aid in bolus movement
Areolar connective tissue
What type of cells is the muscularis externa
– Skeletal muscle in superior 1/3
– Mixture of skeletal and smooth in middle
– Smooth muscle in last 1/3
-Has a circular layer and longitudinal layer
what type of cells is the adventitia
fibrous connective tissue– Instead of serosa
Digestive process - Mouth to esophagus
• Mouth
– Ingestion
– Mechanical digestion (breakdown)
• Chewing (mastication)
– Propulsion
• Swallowing (deglutition)
– Chemical digestion
• Salivary amylase - begins digestion of carbohydrates
• Lingual lipase (activated by stomach acid)
– No absorption occurs in mouth (except for few drugs)
• Pharynx and esophagus
– Sole function is propulsion of food
• Transport of food from mouth to stomach
Deglutition
=Swallowing
Involves 22 muscles
Describe the buccal phase during deglutition
- Voluntary
- Occurs in mouth
- Tongue contracts to force bolus into oropharynx
During the buccal phase, the upper esophageal sphincter is contracted.
The tongue presses against the hard palate and contracts, forcing the food bolus into the oropharynx.
Describe the Pharyngeal-esophageal phase during deglutition
– Involuntary – begins when tactile receptors in posterior pharynx are stimulated by bolus
– Controlled by medulla and pons
– Vagus nerve transmits motor impulses from swallowing center to muscles of pharynx and esophagus
The pharyngeal-esophageal phase begins as the uvula and larynx rise and the epiglottis bends to prevent food from entering respiratory passageways. The tongue blocks off the mouth. Upper esophageal sphincter relaxes, allowing food to enter the esophagus.
The constrictor muscles of the pharynx contract, forcing food into the
the esophagus inferiorly. The upper esophageal sphincter contracts (closes) after food enters.
Peristalsis moves food through the
esophagus to the stomach
The gastroesophageal sphincter surrounding the
cardial oriface opens, and food enters the stomach
Describe the locations and functions of the stomach
• Located in upper left quadrant
• Functions:
– Food storage
– Begins digestion of proteins – Converts food into chyme
What does the cardinal part of the stomach surround
Cardial orifice
The cardinal orifice of the stomach is the entry from the
esophagus
The fundus of the stomach is a ___________________ beneath the
Dome-shaped region beneath the diaphram
Describe the body of the stomach
midportion
Describe the pyloric part of the stomach
– funnel-shaped region near duodenum
– Pyloric antrum (superior portion) --> pyloric canal --> pylorus
– Pyloric sphincter - controls stomach emptying
Describe the greater curvature of the stomach
- Convex lateral surface
Describe the lesser curvature of the stomach
- Concave medial surface
Describe the arterial supply of the stomach
Branches of celiac trunk
The veins of the stomach empty into what vein
hepatic portal vein
What is Rugae in the stomach
Folds of lining seen when stomach is empty
Mesenteries associated with the stomach
-Lesser omentum
– From liver to lesser curvature
-Greater momentum
– From greater curvature
--> drapes anteriorly over small intestine
--> wraps spleen & transverse colon
--> blends with mesocolon
- Contains fat deposits & lymph nodes
Four tunics of the stomach
mucosa, submucosa, muscularis, serosa
-Muscularis and mucosa modified
Describe the muscularis externa of the stomach
– Three layers of smooth muscle (instead of two)
– Inner oblique layer allows stomach to churn, mix, move, and physically break down food
Describe the mucosa of the stomach
– Simple columnar epithelium
• Composed of mucous (goblet) cells
– Dotted with gastric pits --> gastric glands
• Gastric glands produce gastric juice
Describe the 2 types of chief cells in the stomach
– Pepsinogen - activated to pepsin by HCl & by pepsin itself (a positive feedback mechanism)
– Lipases - digest lipids
Mucosal barrier protects the stomach from _____ and ______
acids and enzymes
The mucosal layer protects the stomach from acids and enzymes by
• Thick layer of bicarbonate-rich mucus
• Tight junctions between epithelial cells
– Prevent juice seeping underneath tissue
• Damaged epithelial cells are quickly replaced by division of stem cells
– Surface cells replaced every 3–6 days
Describe gastritis
– Inflammation of stomach wall caused by anything that breaches mucosal barrier
Describe peptic ulcers
– Erosions of stomach wall
• Can perforate --> peritonitis and hemorrhage
– Most caused by Helicobacter pylori bacteria
Digestive processes in the stomach
• Physical digestion
• Denaturation of proteins by HCl
• Enzymatic digestion of proteins by pepsin
– Protein digestion begins in the stomach
• Lingual lipase becomes activated and digests some triglycerides before it is digested
• Delivers chyme to small intestine
– Chyme – partially digested food and gastric juice
Regulation of gastric secretion
• Neural and hormonal mechanisms
• Vagus nerve stimulation-->secretion increases
• Sympathetic stimulation --> ecretion decreases
• Hormonal control is mainly gastrin
– Stimulates enzyme and HCl secretion
– Stimulates most small intestine secretions - gastrin antagonists
What are the 3 phases of gastric secretion
1. Cephallic (reflex) phase
2. Gastric Phase
3. Intestinal phase
Describe Cephallic (reflex) phase
*before food enters stomach
– Conditioned reflex triggered by sight, smell, taste, or thought of food
– Sensory receptors --> hypothalamus --> medulla oblongata --> vagus nerve --> enteric neurons --> stimulates glands
Describe the gastric phase
– lasts 3–4 hours (2/3 gastric juice released)
– Stimulated by distension, peptides, low acidity (high pH), gastrin (major stimulus)
– Caffeine, peptides, rising pH (from ingested proteins) stimulate enteroendocrine G cells to release gastrin
– Gastrin stimulates parietal cells to release HCL
– HCL digests proteins
What are the 2 components of the intestinal phase
-Stimulatory component
-Inhibitory component
Describe the Stimulatory component of the intestinal phase
• Partially digested food enters duodenum
• Duodenum releases intestinal (enteric) gastrin
– To blood --> stomach
– Stimulates gastric glands to continue secretions
Describe the Inhibitory component (enterogastric reflex) of the intestinal phase
• Intestine distends with chyme
– Chyme contains H+, fats, peptides, irritating substances
• Distension of intestine
– Inhibits gastric activity
» To protect small intestine from excessive acidity
– Causes pyloric sphincter to tighten
» To prevent further food entry
Three chemicals are necessary for maximum HCl secretion:
– Acetylcholine (ACh)
• Released by parasympathetic nerve fibers
– Gastrin
• Secreted by G cells in stomach
– Histamine
• Released by enteroendocrine cells of glands
–In response to gastrin
• Antihistamines block histamine receptors of parietal cells --> decrease HCl --> decrease ulcers
Peristalsis begins near what?
gastroesophageal sphincter
--> gentle rippling
Peristaltic waves ______ and move toward ______ at a rate of __ per _______
Peristaltic waves STRENGTHEN and move toward PYLORUS at rate of 3 per MINUTE
How is the contractile rhythm set during peristaltic waves?
Contractile rhythm set by enteric pacemaker cells located in longitudinal smooth muscle layer
What are pacemaker cells linked by?
Gap junctions --> entire muscularis contracts
Distension of stomach and gastrin secretion increase
force of contractions
Chyme is delivered in
3 ml spurts to duodenum
List the 3 steps during peristaltic waves in the stomach
1) Propulsion: Peristaltic waves move from the fundus toward the pylorus.
2) Grinding: The most vigorous peristalsis and mixing action occur close to the pylorus.
3) Retropulsion: The pyloric end of the stomach acts as a pump that delivers small amounts of chyme into the duodenum, simultaneously forcing most of its contained material backward into the stomach.
Describe the regulation of gastric emptying
• As chyme enters duodenum
– Receptors respond to stretch and chemical signals
– Enterogastric reflex and enterogastrones inhibit gastric secretion and duodenal filling
• Enterogastrones = secretin, cholecystokinin, vasoactive intestinal peptide
• Stomach usually empties completely within four hours after a meal
• Carbohydrate-rich chyme moves quickly through duodenum
• Fatty chyme remains in stomach 6 hours or more
What is the major organ of digestion and absorption
The small intestine
What supplies blood to the small intestine
superior mesenteric artery
Describe venous drainage of the small intestine
Veins --> superior mesenteric vein --> hepatic portal vein --> liver -->
inferior vena cava --> heart
What are the subdivisions of the small intestine
– Duodenum (retroperitoneal)
– Jejunum (attached posteriorly by mesentery)
– Ileum (attached posteriorly by mesentery)
• Joins large intestine at ileocecal valve
Describe the duodenum
• Shortest part – 25 cm (10 inches)
• Curves around head of pancreas
• Bile duct (from liver) and pancreatic duct (from pancreas)
– Join at hepatopancreatic ampulla
– Enter duodenum at major duodenal papilla
– Hepatopancreatic sphincter controls entry of bile and pancreatic juice (Sphincter of Odi)
Describe the anatomy of the small intestine
• Highly adapted for absorbing nutrients
• Wall has three structural modifications to increase surface area for absorption (primarily in proximal part)
– Circular folds (plicae circulares)
– Villi
– Microvilli
Describe circular folds
Circumferential --> force chyme to slowly spiral through lumen (speed bumps)
Describe Villi
– Fingerlike projections (~1 mm high) of mucosa
– Capillary bed and lacteal in center of each villus
Describe Microvilli (brush border)
– Extensions of plasma membrane of columnar epithelial cells lining small intestine
– Contain brush border enzymes that complete digestion of carbohydrates and proteins
Describe the mucosa in the small intestine (microscopic)
– Simple columnar epithelium
• Absorptive cells = enterocytes
• Goblet cells secrete mucus
• Studded with pits between villi
-->tubular glands called intestinal crypts
– Lamina propria
• Capillary and lacteal extend into each villus
– Muscularis mucosa
• Thin layer of smooth muscle
Describe Peyer's patches
MALT
– Located in lamina propria of mucosa
• May protrude into submucosa
– Prominent in ileum
– Protect against bacteria entering bloodstream
Describe Duodenal (Brunner's) glands
– In submucosa of duodenum
– Secrete alkaline (bicarbonate-rich) mucus to neutralize acidic chyme
Describe intestinal Juice
• Secreted by epithelial cells of intestinal crypts
– In response to distension or irritation of mucosa
• Slightly alkaline (7.4-7.8)
– Isotonic with blood plasma
• Mainly water with some mucus from mucosa goblet cells and duodenal Brunner’s glands
– Enzyme-poor
(enzymes of small intestine only in brush border)
• Facilitates transport & absorption of nutrients
Describe the liver
• Largest gland in body (weighs 3 lbs)
• Four lobes—right, left, caudate, quadrate
• Many metabolic functions
– Important – processes nutrient-laden venous blood from digestive organs
• Only digestive function is bile production
– Bile – fat emulsifier
• Breaks down fats to smaller particles that are more readily digestible
Describe the falciform ligament of the liver
– Separates larger right and smaller left lobes
– Suspends liver from diaphragm and anterior abdominal wall
Describe the round ligament (ligamentum teres) of the liver
– Remnant of fetal umbilical vein
– Along inferior edge of falciform ligament
The liver is enclosed by the
visceral peritoneum
- Except bare area which touches diaphragm
Bile ducts of the liver
– Common hepatic duct leaves liver
– Cystic duct leaves gallbladder
– Bile duct formed by union of common hepatic and cystic ducts
Hypatocyte functions
• Produce bile (900 ml per day)
• Process bloodborne nutrients
– Store glucose as glycogen
– Use amino acids to make plasma proteins
• Store fat-soluble vitamins
• Perform detoxification
• Participate in Vitamin D synthesis
Describe Bile
• Yellow-green, alkaline solution containing
– Bile salts - cholesterol derivatives that function in fat emulsification and absorption
– Bilirubin - pigment formed from heme
• Bacteria in small intestine break down to stercobilin --> brown color of feces
– Cholesterol
– Triglycerides
– Phospholipids
– Electrolytes
Some substances secreted in bile leave body in feces but ______ ______ do not
Bile salts
Describe enterohepatic circulation
– Recycles bile salts (3-5 times per meal)
– Bile salts --> duodenum --> reabsorbed from ileum --> hepatic portal blood --> liver secreted into newly formed bile
Describe the Gallbladder
• Thin-walled muscular sac on ventral surface of liver
• Stores and concentrates bile by absorbing water and ions
• Releases bile into cystic duct, which flows into bile duct
Bile in the gallbladder
• Bile is major means of cholesterol excretion from body
• Bile salts keep cholesterol dissolved in bile
• High cholesterol or too few bile salts
--> cholesterol crystalizes
--> gallstones (biliary calculi)
• Gallbladder contracts against crystals --> pain
• Gallstones obstruct bile flow
--> may cause obstructive jaundice
Describe the location of the pancreas
• Mostly retroperitoneal
• Deep to greater curvature of stomach
Describe the regions of the pancreas
• Head - encircled by duodenum
• Tail - touches the spleen
• Body – mid portion of gland
• Uncinate process – folded posteriorly
Importance of the pancreas
Produces enzymes that break down all food categories
What is the endocrine function of the pancreas
– Pancreatic islets = Islets of Langerhans
• Secrete insulin and glucagon
What is the exocrine function of the pancreas
– Acini secrete pancreatic juice
• Acini - clusters of secretory acinar cells
• Zymogen granules of acini cells contain inactive digestive enzymes (proenzymes)
– Pancreatic juice empties into the duodenum via main pancreatic duct
Pancreatic juice is secreted by
acinar cells
Info on pancreatic juice
• Watery alkaline solution (pH 8)
– Neutralizes acidic chyme that enters duodenum
– Optimal environment for intestinal & pancreatic enzymes
• Electrolytes (primarily HCO3– , --> raises pH)
• Enzymes
– Secreted in active form
• Amylase – digests starch
• Lipase – digests fats
• Nuclease - digests nucleic acids
– Secreted in inactive form and activated in duodenum
• Proteases - digest proteins
– Trypsinogen --> trypsin -->
» Chymotrypsinogen --> chymotrypsin
» Procarboxypeptidase --> carboxypeptidase
During active digestion (after a meal) the most important stimulus for bile secretion is
increased bile salts* in enterohepatic circulation
• Causes liver to produce more bile
The liver also produces more bile in response to
• Secretin released from intestinal cells (duodenum)
–Exposed to acidic fatty chyme
Other functions of secretin:
• Stimulates pancreatic release of HCO3 rich juice
• Inhibits gastric secretions and motility
Hepatopancreatic sphincter is closed unless
digestion is active
The liver produces and releases bile
continuously
Bile backs up to _________ when sphincter is ______
Bile backs up to GALLBLADDER when sphincter CLOSED
--> bile stored in gallbladder
Bile is released to small intestine only when
gallbladder contracts
Gallbladder contraction is stimulated by
Cholecystokinin (cck)***
• Released from intestinal cells in response to acidic, fatty chyme entering duodenum
– Parasympathetic vagal stimulation (minor)
Other functions of cholecystokinin
– Stimulates secretion of enzyme-rich pancreatic juice
– Relaxes hepatopancreatic sphincter
• Allows bile & pancreatic juice to enter duodenum
– Inhibits gastric secretion and motility
Steps of the mechanisms promoting secretion and release of bile and pancreatic juice
1. Chyme entering duodenum causes duodenal enteroendocrine cells to release cholecystokinin (CCK) and secretin.
2. CCK (red dots) and secretin (yellow dots) enter the bloodstream.
3. CCK induces secretion of enzyme-rich pancreatic juice. Secretin causes secretion of HCO3− -rich pancreatic juice.
4. Bile salts and, to a lesser extent, secretin transported via bloodstream stimulate liver to produce bile more rapidly.
5. CCK (via blood stream) causes gallbladder to contract and hepatopancreatic sphincter to
relax. Bile enters duodenum.
Chyme from stomach contains
– Partially digested carbohydrates and proteins
– Undigested fats
• 3–6 hours in small intestine
– Most water and virtually all nutrients absorbed
Digestion Requires
• Digestion requires:
– Slow delivery of acidic, hypertonic chyme
– Delivery of bile, enzymes, and bicarbonate ions from liver, gallbladder, and pancreas
– Mixing
What influence does the small intestine have one digestion
• Most substances needed for SI digestion originate outside the SI & are delivered to the SI
– Bile
– Digestive enzymes (most)
– Bicarbonate ions
• Brush border enzymes of SI microvilli complete digestion of carbohydrates, proteins, & nucleic acids
* Anything that impairs liver, gallbladder, or pancreatic function or delivery of their substances hinders digestion
Describe the motility of the small intestine
• Smooth muscle activity in small intestinal wall has three primary functions:
– Mixes chyme with accessory gland secretions
– Brings chyme in contact with brush border
of mucosa
– Propels contents toward large intestine
• Accomplished by segmentation & peristalsis
Describe segmentation of the small intestine
– Most common motion of small intestine*
– Initiated by intrinsic pacemaker cells
– Mixes chyme with digestive secretions
– Helps bring chyme in contact with mucosa
– Moves contents toward ileocecal valve
– Intensity altered by long & short reflexes and by hormones
• Parasympathetic increases ; Sympathetic decreases
– Wanes in late intestinal (fasting) phase
Describe peristalsis of the small intestine
– Initiated by rise in motilin hormone
• Released by duodenal mucosa
• In late intestinal phase (after most nutrients absorbed)
• Starts in proximal duodenum every 90–120 minutes
– Each successive wave starts distal to previous
• Migrating motor complex (MMC)
– Propels meal remnants, bacteria, and debris to large intestine
• “Housekeeping function” --> sweeps to LI
– From duodenum to ileum ~ 2 hours
The ileocecal sphincter is usually
constriced
What 2 mechanism cause the sphincter to relax and admit chyme into cecum
– Gastroileal reflex (triggered by stomach activity) increases force of segmentation in ileum
– Gastrin (released by stomach) increases motility of ileum
Ileocecal valve flaps _____ when chyme exerts __________ _________
Ileocecal valve flaps CLOSE when chyme exerts BACKWARD PRESSURE
– Prevents regurgitation into ileum
What are the functions of the large intestine
• Absorbs water (not absorbed by SI)
• Absorbs vitamins produced by bacterial flora
• Absorbs electrolytes (mainly Na+ and Cl-)
• Temporarily stores digestive residues
• Eliminates indigestible material from body as feces
• The colon is not essential for life
List some of the unique features of the large intestine
• Teniae coli
– Three bands of longitudinal smooth muscle in
muscularis (act like elastic)
• Haustra
– Pocketlike sacs caused by tone of teniae coli
• Epiploic appendages
– Fat-filled pouches of visceral peritoneum that
hang from surface (unknown significance)
What are the subdivisions of the large intestine
Cecum
Appendix
Colon
Rectum
Anal Canal
Describe the cecum
(“blind pouch”) – first part of LI – Ileocecal valve
Describe the appendix
– fingerlike projection attached to posteromedial surface of cecum
– Contains masses of lymphoid tissue
• Part of MALT of immune system
– Bacterial storehouse
--> recolonizes gut when necessary
– Structure allows enteric bacteria to accumulate and multiply --> appendicitis
Describe the colon
– Ascending colon (right side)
- Right colic (hepatic) flexure
– Transverse colon
- Left colic (splenic) flexure
– Descending colon (left side)
– Sigmoid colon (S-shaped in pelvis)
– Ascending colon and descending colon are retroperitoneal
– Transverse and sigmoid colon are intraperitoneal and anchored to posterior abdominal wall by mesocolons
Describe the rectum
– Joins sigmoid colon at level of third sacral vertebra
– Three rectal valves stop feces from being passed with gas (flatus)
Describe the anal canal
- last segment of large intestine
– Lies external to abdominopelvic cavity
– Opens to body exterior at anus
– Two sphincters
• Internal anal sphincter - smooth muscle, involuntary
• External anal sphincter - skeletal muscle, voluntary
What type of tissue is in the large intestine
Simple columnar epithelium
– Except in anal canal (stratified squamous – abrasion)
Randomness about LI
• No circular folds or villi
• No cells that secrete digestive enzymes
– Because food is digested and absorbed before reaching large intestine
• Abundant deep crypts with GOBLET CELLS***
– Mucus eases passage of feces and protects mucosa
from irritating bacterial acids and gases
• Superficial venous plexuses (hemorrhoidal veins) of anal canal form hemorrhoids if inflamed
Describe bacterial flora of the large intestine
• Most bacteria are killed before enter LI
• Enter from small intestine or anus
– Colonize colon
– Synthesize B complex vitamins and vitamin K
– Ferment indigestible carbohydrates (cellulose)
– Release irritating acids and gases (flatus)
• Prevented from breaching mucosal barrier by IgA response of MALT
What is inflammatory Bowel Disease (IBD)
• Periodic inflammation of intestinal wall
• Abnormal immune response to normal bacterial antigens
• Linked to newly discovered helper T cell and deficits of
lysozymes, defensins etc secreted by gut mucosa
• Symptoms – cramping, diarrhea, weight loss, bleeding
• Two subtypes:
– Ulcerative colitis – shallow inflammation, mainly rectum
– Crohn’s disease – more serious, with deep ulcers and fissures in entire intestine, but mostly terminal ileum
What is the treatment for IBD
diet, antibiotics, anti-inflammatory drugs, immunosuppressant drugs, stress reduction
Describe defecation
Mass movements force feces toward rectum
Muscles of rectum contract to expel feces
Assisted by Valsalva's maneuver
Describe chemical digestion
• Digestion
– Catabolic process that breaks down large molecules to monomers small enough to be absorbed
• Uses enzymes secreted by intrinsic and accessory glands
• Enzymatic breakdown occurs by hydrolysis – Water is added to break bonds
***Most digestion and absorption occurs in the small intestine
Describe carbohydrate digestion
• Carbohydrates must be broken down to monosaccharides to be absorbed
– Glucose, fructose, galactose
• Begins in mouth
– Salivary amylase
• Continues in small intestine
– Pancreatic amylase
– Brush border enzymes of small intestine
Describe protein digestion
• Proteins digested include
– Dietary proteins, enzymes, and mucosal cells
• Begins in stomach
– Pepsinogen secreted by chief cells of stomach is activated to pepsin (by HCl and pepsin itself)
• Inactivated by high pH of duodenum
• Continues in small intestine
– Pancreatic enzymes
• Trypsin, chymotrypsin, carboxypeptidase
– Brush border enzymes
Describe lipid digestion
• Very small amount (10%) of fat is digested by lingual lipase after it is activated in stomach
**Small intestine is primary site of lipid digestion**
– Pancreatic lipase
• Fats must be emulsified for efficient digestion
– Broken down in duodenum to smaller fat droplets by bile salts contained in bile from liver
Emulsification and absorption of fats
• Does not break chemical bonds
• Reduces attraction between fat molecules
• Disperses fat molecules
• Increases exposure to pancreatic lipases
• Fatty acids and monoglycerides associate with bile salts
to form micelles
Nucleic Acid Digestion
• Occurs in small intestine
• Pancreaticnucleases
– Ribonuclease & deoxyribonuclease
– Hydrolyze to nucleotide monomers
• Intestinal brush border enzymes
– Nucleosidases and phosphatases
• Break nucleotides apart to release
–Nitrogenous bases
–Pentose sugars
–Phosphate ions
Describe absorption
***Almost all food, 80% electrolytes, and 95% water are absorbed in small intestine
***Most absorption complete before chyme reaches ileum
• All that remains at end of ileum is
– Small amount of water
– Indigestible food materials (cellulose)
– Bacteria!!!
***Ileum’s major absorptive role is to reclaim bile salts
to be recycled back to liver
– Enterohepatic circulation
Absorption of nutrients
• Most nutrients are absorbed by active transport
– Enter villus capillaries
– Transported by hepatic portal vein to liver (processed)
– Empties into inferior vena cava
• Exception – lipids
– Absorbed by passive diffusion
– Enter lacteals in villi of small intestine
– Enters blood at junction of left internal jugular vein and subclavian vein
Malabsortion of Nutrients
• Gluten-sensitive enteropathy (celiac disease)
– Immune reaction to gluten
• Protein in all grains except corn and rice
– Gluten complexes with immune system molecules
• Immune complexes attack intestinal lining
–Damage intestinal villi and brush border
– Bloating, diarrhea, pain, malnutrition
– Treated by eliminating gluten from diet
Absorption of Vitamins
• Most dietary vitamins absorbed by small intestine
• Large intestine absorbs some of Vitamin K and B vitamins made by its enteric bacteria
• Fat-soluble vitamins (A, D, E, K) dissolve in dietary fats and are absorbed by passive diffusion
– Enter lacteals
– Thus must eat fatty food to absorb these vitamins
• Vitamin B12 absorption requires intrinsic factor produced by the stomach