Circulation and Respiration PDF

Summary

These notes cover the vascular system, including the path of blood flow throughout the body, the heart chambers and valves, and related topics.

Full Transcript

THE VASCULAR SYSTEM
 Path of blood flow throughout
the body Note: oxygenated
and deoxygenated
blood do not mix
Pulmonary Circuit Systemic Circuit

Pulmonary arteries Capillaries in head,
neck, upper limbs
Capillaries in lungs
Systemic arteries
Pulmonary veins

Start The left atrium
The right atrium
collects blood from
receives blood
the pulmonary
from the systemic
circuit and empties
circuit and passes
it into the left
it to the right
ventricle, which
ventricle, which
pumps blood into
pumps blood into
the systemic circuit.
the pulmonary
circuit.

Systemic veins
2
Capillaries in trunk
and lower limbs

From Visual Anatomy & Physiology, 1e
Martini/Ober/Nath p.595
 8 Capillaries of
Superior
vena cava head, chest, and
arms
Pulmonary Pulmonary
artery artery

Capillaries 9 Aorta Capillaries
of right lung of left lung
2 7
2

3 3

4 5
10
4
Pulmonary Pulmonary
vein 6
1 vein
Right atrium 9 Left atrium

Right ventricle Left ventricle

Inferior Aorta
vena cava

Capillaries of
abdominal region
and legs
8
3
Chambers of the Heart

Right Atrium: Receives
deoxygenated blood from
the superior and inferior Left Atrium: Receives
venae cavae and from the oxygenated blood from
cardiac veins through the the pulmonary circulation;
coronary sinus; sends sends blood to left ventricle
blood to right ventricle

Key:
Left Ventricle: Receives
Oxygen-rich blood blood from the left atrium;
Oxygen-poor blood sends blood to systemic
circulation

Right Ventricle: Receives blood
from the right atrium; sends 4
blood to pulmonary circulation
Myocardial Thickness and function
Very thick wall of left ventricle
generates high force necessary to send
blood through all systemic arteries

Wall of right ventricle is not as
thick since the blood is sent
through the pulmonary arteries 5
 Ascending Pulmonary
aorta trunk

Heart Valves
Superior
vena cava

Aortic arch

The heart valves prevent
the back flow of blood. Left pulmonary veins

They open and close due
to the pressure exerted
by the blood

Right atrioventricular (AV)
valve (tricuspid valve)
located b/w right atrium
and right ventricle
Left atrioventricular (AV)
valve (bicuspid valve)
Inferior located b/w left atrium
vena cava and left ventricle

Pulmonary valve
Aortic valve

From Visual Anatomy & Physiology, 1e 6
Martini/Ober/Nath p.634
 Ascending Pulmonary
aorta trunk

Heart Valves
Superior
vena cava

Aortic arch

As the right atrium contracts, Left pulmonary veins
the force of blood flow pushes the
right AV valve open.

As the left atrium contracts,
Chordae tendineae
the force of blood flow pushes
prevent valves from
the left AV valve open.
opening back into the
atria

As the left ventricle
Inferior contracts, the force of blood
vena cava flow causes the AV valve to
close, and pushes the aortic
valve open.
As the right ventricle contracts,
the force of blood flow causes the
AV valve to close, and pushes the
pulmonary valve open.
From Visual Anatomy & Physiology, 1e 7
Martini/Ober/Nath p.634
 Heart sounds
The sound of a heartbeat comes primarily from the turbulence in
blood flow caused by the closure of the valves, NOT from the
contraction of the heart muscle

The first heart sound (lubb)
– blood turbulence associated with
the closing of the atrioventricular
valves soon after ventricular systole
(contraction)

The second heart sound (dupp)
– blood turbulence associated with the
closing of the semilunar valves
after ventricular diastole (relaxation) 8
8
 The heart contracts and relaxes
rhythmically

the heart passively fills with blood (during
diastole) and actively contracts and ejects the
blood (during systole)

Blood flows through the right side and the left
side of the heart at the same time

Oxygenated and deoxygenated blood never mix
9
 The heart contracts and relaxes
rhythmically

during diastole:
– the entire heart is relaxed,
and blood flows from the
veins into the atria
– the atrioventricular (AV)
valves are open

10
 The heart contracts and relaxes
rhythmically
during systole:
– atrial systole – contraction of
the atria that completely fills
the ventricles with blood
– ventricular systole –
ventricles contract and blood
is sent out into large arteries
(from left ventricle into aorta to
systemic circulation; from right
ventricle into pulmonary trunk
to pulmonary circulation) 11
 Coronary Arteries
Just like every organ of your body, the cells of your
heart require oxygen and nutrients to function properly

Coronary arteries are the blood vessels that bring
oxygen- and nutrient-rich blood to your heart cells
Superior Aorta
Vena cava
Left
Pulmonary coronary
artery artery
Right
coronary
artery
Blockage

Dead
12
muscle
Figure 23.8A
tissue
 What is a heart attack?

a heart attack occurs when a blockage prevents the
delivery of oxygen and nutrients to your heart cells (the
cells die)
a stroke occurs when a blockage prevents the brain
cells to get fresh blood Superior Aorta
Vena cava
Left
Pulmonary coronary
artery artery
Right
coronary
artery
Blockage

Dead
13
muscle
Figure 23.8A
tissue
 a heart attack or stroke most often results from the
gradual obstruction of the arteries (disease called
atherosclerosis)
plaques form and restrict the blood flow. At some
point, complete blockage can happen.

Connective Smooth Plaque
tissue muscle
Epithelium

LM 160 

LM 60 
14
Figure 23.8B
Three major daily activities can influence
the prevalence of cardiovascular diseases

smoking can double the risk
regular exercise can reduce the risk
diet low in saturated fat, trans fat and
cholesterol can help reduce the risk

15
 Balloon Narrowed
Some Solutions: Atherosclerotic lumen
plaque of artery Coronary
artery
angioplasty
Balloon catheter with uninflated balloon is
threaded to obstructed area in artery

When balloon is inflated, it stretches arterial
wall and squashes atherosclerotic plaque

After lumen is widened, balloon is deflated
16
and catheter is withdrawn
Some Solutions:
stent
Stent

Lumen
of artery
(c) Stent in an artery

17

(d) Angiogram showing a stent in the
circumflex artery
Some Solutions:
coronary bypass
Ascending
aorta

Grafted
vessel

18
Obstruction
(a) Coronary artery bypass grafting (CABG)
 Treatments of cardiovascular diseases
drugs
To dissolve clots
To lower cholesterol and/or blood pressure

surgical
Angioplasty – a balloon is inserted in the artery to
compress plaques and widen clogged arteries
Stents – a small wire mesh tube prop arteries open
Bypass – blood vessels taken from the leg are sewn
into the heart to shunt blood around clogged arteries
19
– Cardiac output
– Amount of blood/minute pumped into systemic
circuit

– Heart rate
– Number of beats/minute

20
Copyright © 2009 Pearson Education, Inc.
 Conduction system of the heart
1. The SA Node (pacemaker) is a cluster of cells
situated in the wall of the right atrium that generates
electrical signals Pacemaker
(SA node)

Right
atrium

1 Pacemaker
generates
signals
to contract

ECG
21
 Conduction system of the heart
2. The electrical signals spread quickly through both atria,
making them contract in unison and send the blood to the
ventricles
The signals also pass through a relay point called the AV
node, in the wall between the right atrium and the right
ventricle. This causes a delay (0.1 sec) ensuring that the atria
contract and empty before the ventricles contract
Pacemaker
(SA node) AV node

Right
atrium

1 Pacemaker 2 Signals spread
generates through atria
signals and are delayed
to contract at AV node
22
ECG
 Conduction system of the heart
3. Specialized cardiac muscle fibers relay the signals to the
walls of the ventricles
down towards the apex of the heart (the region at the
bottom of the heart) …

Pacemaker
(SA node) AV node Specialized
muscle fibers

Right
atrium

Apex
1 Pacemaker 2 Signals spread 3 Signals relayed
generates through atria to apex of heart
signals and are delayed
to contract at AV node

23
ECG
 Conduction system of the heart
4. … and up through the walls of the ventricles
The signal triggers the strong contraction that drives the blood
out of the heart
Pacemaker
(SA node) Specialized
AV node
muscle fibers

Right
atrium

Apex
1 Pacemaker 2 Signals spread 3 Signals relayed 4 Signals spread
generates through atria to apex of heart through
signals and are delayed ventricle
to contract at AV node

ECG 24
 Conduction system of the heart
Pacemaker
(SA node) Specialized
AV node
muscle fibers

Right
atrium

Apex
1 Pacemaker 2 Signals spread 3 Signals relayed 4 Signals spread
generates through atria to apex of heart through
signals and are delayed ventricle
to contract at AV node

ECG

25
Abnormal rhythms may occur in a heart attack

External defibrillator can restore rhythm

Implanted artificial
pacemakers can trigger
normal rhythms

Heart

26
Blood Vessels
Veins: convey
blood from the
tissues back to
Venules: convey the heart
blood from the
tissues into veins

Arteries: carry
Capillaries: site of
exchange between blood from the
the blood and body heart to the
tissues tissues
Arterioles: small
arteries that
connect to
Capillaries: site of capillaries
exchange between
the blood and
body tissues

Note: large blood vessels have their own vessel supply (called
27 Vasa vasorum), because their wall is too thick for nutrients to 27
diffuse from the blood flowing through them.
 Arteries and Veins

Artery

Vein

(a) Artery

LM x 60 28
From Visual Anatomy & Physiology, 1e
Martini/Ober/Nath p.596
(b) Vein
 epithelial cells form the endothelium
smooth muscle in walls can reduce blood flow
elastic fibers permit recoil after stretching
Capillary
Epithelium Basal lamina Valve

Epithelium
Epithelium
Smooth
Smooth
muscle
muscle
Connective Connective
tissue tissue

Artery Vein

Arteriole Venule
29
 arteries carry blood
Capillary
to organs Epithelium Basal lamina Valve

Epithelium
Epithelium
Smooth Smooth
muscle muscle
Connective Connective
tissue tissue
Artery Vein

Arteriole Venule

arteries and arterioles have thicker layers of
connective tissue and smooth muscle (suitable for
strength and elasticity against high pressure and rapid
flow of blood) 30
 veins carry blood
Capillary
to the heart
Epithelium Basal lamina Valve

Epithelium
Epithelium
Smooth Smooth
muscle muscle
Connective Connective
tissue tissue
Artery Vein

Arteriole Venule

blood flows at low velocity and pressure
flaps of tissue act as one-way valves 31
Normal valve
varicose veins
occur when valves
are malfunctioning.

www.itiva.com

blood accumulates in veins
causing distension and
inflammation (mostly in lower
leg, eosophagus, and anal
32 32
canal (hemorrhoids). www.omahaveinspecialists.com
 Capillaries
thin walls – a single layer of epithelial cells
narrow – red blood cells flow in a single file

Red
blood
cell

Capillary

33
Copyright © 2009 Pearson Education, Inc.
Gas, nutrient and waste exchange
takes place in capillaries

Capillary

Interstitial Diffusion of
fluid molecules

Tissue
cell
34
 Gas, nutrient and waste exchange
takes place in capillaries
When blood gets to the Relative sizes and
capillaries, the velocity numbers
of blood
is at its lowest, vessels

enhancing the

Velocity (cm/sec)
exchange of substances 50
40
between blood and 30
interstitial fluid 20
10
0

Arteries

Arterioles
Aorta

Venules

Veins

Venae cavae
Capillaries
35
 Blood Pressure

Blood pressure is the force blood exerts against
the walls of the vessels

Depends on cardiac output and the resistance of
vessels
cardiac output is: how much blood is being
ejected from the left ventricle every minute
resistance is: how hard is it for the blood to travel
through the blood vessels

36
 Blood Pressure Pressure in Pressure in
arteries veins
Blood pressure drives

Pressure (mm Hg)
120
blood from the heart 100
Systolic
pressure
through arteries 80
60 Diastolic
40 pressure
20

As the blood flows from
0

the aorta to arteries to Relative sizes and
numbers
arterioles, a greater of blood
vessels
surface area is
encountered, increasing

Arteries

Venules

Veins
Aorta

Venae cavae
Capillaries
Arterioles
the resistance to flow;
this causes the pressure
to drop

37
 Blood Pressure Pressure in Pressure in
arteries veins

Pressure (mm Hg)
120 Systolic
Once blood reaches the 100
80
pressure

venules, the pressure 60
40
Diastolic
is almost at zero; how 20
pressure
0
can the blood make its
way back to the heart? Relative sizes and
numbers
of blood
vessels

Arteries

Venules

Veins
Aorta

Venae cavae
Capillaries
Arterioles
38
 Direction of
blood return blood flow
in vein

veins are squeezed between Valve
muscles; contractions of (open)
skeletal muscles (by walking Skeletal
and moving) will move the muscle
blood toward the heart

large veins have one-way Valve
valves that allow the blood to (closed)
flow only toward the heart

39
 Pressure in Pressure in
arteries veins

Pressure (mm Hg)
120 Systolic
100 pressure
80
60 Diastolic
40 pressure
20
Notice how velocity 0

does not necessarily Relative sizes and
numbers
correlate with pressure of blood
vessels

Velocity (cm/sec)
50 Velocity does not
necessarily correlate
40
with pressure
30
20
10
0

Arteries
Aorta

Venules

Veins

Venae cavae
Capillaries
Arterioles
40
 Blood distribution
blood is not found in all capillaries of the body at
one given time (dependent on the needs of a
specific organ)

blood flow and distribution is controlled by
constriction and relaxation of smooth muscles of
the arterioles i.e. vasoconstriction and
vasodilation

41
Remember thermoregulation in the skin?

42
 Blood distribution
Precapillary sphincters

blood is not found in all
capillaries of the body at one
given time (dependent on the
needs of a specific organ)
Capillaries
Arteriole Venule

in addition, blood flow and 1 Sphincters relaxed

distribution is controlled by Thoroughfare
channel
constriction and relaxation of
precapillary sphincters

Arteriole Venule
43
2 Sphincters contracted
Figure 23.11
 Exchange of Solutes Between
Blood and Interstitial Fluid

The exchange of solutes between the blood and
the interstitial fluid occurs by:
diffusion through epithelial cells
endo/exocytosis
Water will move out of capillaries by
leakage through the cleft between two epithelial
cells of the capillary wall
44
 Exchange of Solutes Between
Blood and Interstitial Fluid
Two kinds of pressure in the capillaries
drive the flow of fluid:
Blood pressure and osmotic pressure
Tissue cells

Osmotic Osmotic
Arterial Venous
pressure pressure
end of end of
capillary capillary
Blood Blood
pressure pressure

Interstitial Net fluid Net fluid
fluid movement out movement in
45
Figure 23.11B
 Blood pressure (hydrostatic pressure): drives the fluid
out of the capillaries at the arterial end

Osmotic pressure: drives the fluid in the
capillaries at the venous end – this is due to the
high concentration of proteins in the blood
Tissue cells

Osmotic Osmotic
Arterial Venous
pressure pressure
end of end of
capillary capillary
Blood Blood
pressure pressure

Interstitial Net fluid Net fluid
fluid movement out movement in
46
Figure 23.11B
 Structure and Function of Blood
~ 5 L of blood in a person
Blood consists of cells floating around in plasma
ions maintain osmotic balance, keep the pH stable
(7.4), are necessary for cell functions (such as
muscle and nerve cells)
proteins maintain osmotic balance, act as buffers, or
have specific functions in coagulation (clotting) or
immunity (defense)
plasma also contains substances in transition from
one part of the body to another (O2, CO2, nutrients,
wastes, hormones, heat) 47
 Blood Cells
Red Blood Cells carry
oxygen to our tissues – will
be discussed in the chapter White Blood Cells fight
on the respiratory system infections – will be
discussed in the chapter
on the immune system

Blood plasma

Platelets are involved in
hemostasis; a sequence of
responses that stops
LM 400x bleeding when blood
Blood smear
vessels are damaged
(to prevent hemorrhages) 48
 Structure and Function of Blood
Blood consists of cells floating ~ 5 L of blood in
around in plasma a person
~ 45%
red blood cells (RBC) (erythrocytes) carry
oxygen
~ 25 trillion red blood cells Cellular elements (45%)

Cell type Number Functions

~ 250 million molecules of per µL (mm3) of blood

Erythrocytes
hemoglobin /RBC (red blood cells) 5–6 million Transport of
oxygen (and
Centrifuged carbon dioxide)
blood
~ 1 billion molecules of O2 carried sample

Leukocytes Defense and
in one RBC (white blood cells)5,000–10,000 immunity

White blood cells (WBC) defend the Basophil
Lymphocyte

body against infections and cancer Eosinophil

Neutrophil Monocyte

platelets are involved in blood clotting Platelets
Figure 23.13 250,000– 49
Blood clotting
400,000
 ABO Blood Groups

BLOOD TYPE TYPE A TYPE B TYPE AB TYPE O

A antigen B antigen Both A and B antigens Neither
A nor B antigen
Red blood
cells

50
 ABO Blood Groups
BLOOD TYPE TYPE A TYPE B TYPE AB TYPE O

Neither
A antigen B antigen Both A and B antigens
A nor B antigen

Red blood
cells

Plasma

Anti-B Anti-A Neither Both anti-A and
antibody antibody antibody anti-B antibodies

51
 RH blood groups
People who are Rh+ have the D antigen on surface
of their RBC

Normal plasma contains no anti-Rh antibodies
If Rh- person receives blood from Rh+ donor, anti-
Rh antibodies will be formed
– ok for the first transfusion, but danger upon 2nd
exposure to the antigen

Safe
– Rh+ to Rh+
– Rh- to Rh+ 52
– Rh- to Rh-
 CONNECTION
Anemia
Is an abnormally low amount of functional hemoglobin
or red blood cells
The hormone erythropoietin
Is produced by the kidneys when
tissues do not receive enough O2
– it regulates red blood cell
production

Some athletes
Artificially increase their red blood

Colorized SEM 3,400
cell production, a dangerous
practice because the blood can get
too thick
53
Figure 23.14
 Hemostasis
(NOT to be confused with homeostasis!)

1. Platelets first stick to exposed collagen
fibers from wall of damaged vessel

54
 Hemostasis
2. Platelets get activated and grow extensions
to attach to one another
– Platelets release substances to activate
neighbouring platelets (what type of feedback
mechanism is this?)

55
55
www.cafepress.com/+activated_platelets_sem_large_poster,664799442
 Hemostasis
3. Activated platelets stick together to form a
platelet plug, which temporarily stops the
blood from leaking out

56 56
sciencephoto.com
 Hemostasis
NOTE: Plug is temporary, and needs to be
reinforced by fibrin threads formed during
the clotting process (next process)

www.sanger.ac.uk

57
 4. Clotting (coagulation)
1) Prothrombinase is
formed in the blood, with
the help of substances
released either from the
damaged tissue or from
factors in the blood 3) Thrombin converts
soluble fibrinogen into
insoluble fibrin; fibrin
traps red blood cells
at the site of damage to
2) Prothrombinase form a clot
converts prothrombin
(inactive) into
thrombin (active);
Ca2+ necessary for this
activation

Plug reinforced by fibrin threads 58
formed during clotting process
Platelets and clot formation
1 Platelets adhere to exposed 2 Platelet plug forms 3 Fibrin clot traps
connective tissue blood cells

Epithelium

Connective
tissue

Platelet
Platelet plug

Figure 23.15A

Colorized SEM 3,400
59
Figure 23.15B
The Respiratory System

60
Functions of the respiratory
system
1. Exchange of oxygen
and carbon dioxide
2. Regulation pH
3. Smell
4. Filtration
5. Resonate Sound
6. Heat and Water
exchange
 What is Gas Exchange?
Gas exchange is the interchange of
O2 and CO2 between an organism and its
environment
– It is also called respiration

Gas exchange is essential because energy
metabolism requires O2 and produces CO2
Structure of the Respiratory System
The respiratory system can be functionally divided into
conducting airways and respiratory airways:

Conducting Airways
−Nasal passages
−Mouth
−Pharynx
−Larynx
−Trachea
−Bronchi
−Bronchioles

* Conducting airways do not participate in gas exchange
Structure of the Respiratory System
The respiratory system can be functionally divided into
conducting airways and respiratory airways:

Respiratory Airways
−Respiratory Bronchioles
−Alveolar Structures

* Respiratory airways do participate in gas exchange
Airway Wall
Structure

Mucous blanket Simple
epithelium Squamous
Cilia epithelium
Pseudostratified epithelium

Smooth muscle
Mucous gland ≤5µm

Cartiliage
 Lobule = smallest functional unit
of the lung
Consists of:
−Branch of terminal bronchiole
−Alveolar structures
−Arteriole (carries blood into lung)
−Pulmonary capillaries (wrap around
alveoli)
−Venule (carries blood away from
lung)
 each bronchiole ends in
grape-like clusters of air
sacs – each “grape” is
Oxygen-rich
called an alveolus
blood Oxygen-poor
blood

Bronchiole
each of our lungs
contains millions of
Alveolar alveoli
Sac

the inner surface of each
alveolus is lined with a
Blood
capillaries squamous epithelium
which forms the
respiratory surface: this
is where gas exchange
takes place
67
 Alveoli
Type I
alveolar cells
− Alveolar
structure
Type II
alveolar cells
− Surfactant
production

Surfactant decreases surface tension and allows for
greater ease of alveolar inflation
 Alveolar expansion =  lung expansion
 the part of an animal where gases are
exchanged with the environment is called the
respiratory surface

respiratory surfaces are made up of living
cells; their plasma membranes must be wet to
function properly

gases must be dissolved in water before they
can diffuse across membranes

69
Air enters through the
nasal cavity (or the
oral cavity)

Air then goes through
the pharynx (throat)

then the larynx (voice box) -- air
can make the vocal cords vibrate

The large tube that brings the air
to the lungs is the trachea
-- Rings of cartilage maintain the
shape of the trachea and prevent it
from collapsing
-- epithelial cells secrete mucus to
trap debris from air
-- mucus swept up by cilia, which
beat in sync 70
the trachea divides into
two bronchi, one going
to each lung

each bronchus divides
repeatedly into finer
and finer tubes called
bronchioles

71
Oxygen-rich
blood Oxygen-poor
blood Total surface area of
Bronchiole alveoli is very large ~ 70
square meters, about ¼
the size of a tennis court
Alveoli

Notice how alveoli are
surrounded by blood
vessels – this is where
Blood the gas exchange takes
capillaries
place

O2 diffuses from the
alveoli into the blood

CO2 diffuses out of the
blood into the alveoli
72
Respiration Requires Three Main
Components

Pulmonary Ventilation (movement of gases into
and out of lungs)

Perfusion (movement of blood through the lungs)

Diffusion (of gases between lungs and blood and
blood and tissue)
 Pulmonary Ventilation (movement of
gases into and out of lungs)

How does air move into and out of the lungs?

As the size of a closed Boyle’s Law (P=1/V)
container decreases, the
pressure inside the
container increases

Liquids and gases move
from an area of high
pressure to an area of
low pressure
 Pulmonary Ventilation (movement of
gases into and out of lungs)
During breathing, the pressure within the lungs
changes, driving the movement of air in and out of the
lungs

For air to move inside the lungs, the pressure must
be lower inside the lungs than outside
− Must increase the size of the lungs

For air to move out of the lungs, the pressure must
be higher inside the lungs than outside
− Must decrease the size of the lungs
 Inhalation

Volume
Pressure

Contraction of the diaphragm flattens the dome and
increases the vertical dimension of the chest
Contraction of the external intercostal muscles
makes the ribs move upward
 Exhalation

Volume
Pressure

Quiet exhalation is a passive process
Relaxation of the diaphragm and external intercostal muscles,
as well as elastic recoil of chest wall and lungs, cause a
reduction in the size of the intrathoracic cavity
78
Besides the difference in air pressure, three other
factors influence pulmonary ventilation (how easy it is
to breathe):

1. Surface tension of alveolar fluid
Water molecules are attracted to each other and
cause alveoli to collapse

Surfactant is a mixture of phospholipids and
lipoproteins that reduces surface tension
− Note: Respiratory distress syndrome (RDS) in infants is
due to a lack of surfactant
2. Compliance of the lungs (how easily the lungs
expand)
Compliance results from high elasticity and low
surface tension
− Scarring of lung tissue replaces elastic fibers with
collagen fibers = decreased compliance

3. Airway resistance (diameter of airways)
Contraction/relaxation of smooth muscles in
airways
− Note: Asthma is due to constriction and inflammation of
airways
Perfusion: Pulmonary Circulation
 Hemoglobin
Hemoglobin in red blood cells is responsible for transporting
oxygen
Hemoglobin is a protein with 4 subunits, each of which is
attached to a heme group (non-protein), at the center of which
is an iron atom
Each iron atom can carry one O2 molecule – thus, every
hemoglobin can carry up to 4 oxygen molecules
Iron atom

O2 loaded
O2
in lungs

O2 unloaded O2
in tissues
Figure 22.10
Heme group 82
Polypeptide chain
 Hemoglobin
98.5% of O2 is transported
via hemoglobin

O2 reversibly binds to
hemoglobin

O2 binding is effected by:
− Partial pressure of O2
− pH
− Temperature
− CO2 concentration
Note: CO2 is primarily transported as bicarbonate ions in
the plasma
 Diffusion: Factors affecting the
exchange of O2 and CO2
The diffusion of gases across a membrane occurs
independently for each gas
− O2 diffuses down its own partial pressure gradient
(independently of CO2)

The rate of diffusion is influenced by several
factors
1. Partial pressure difference
2. Surface area available for gas exchange
3. Diffusion distance
4. Solubility of the gases
Diffusion:
pH [O2]
Factors
affecting the Temp. [CO2]

exchange of
O2 and CO2

[O2] pH
[CO2] Temp.
 Breathing is automatically
controlled

Breathing control
centers are located in
the pons and medulla
of the brain
These automatic
controls keep
breathing in tune with
body needs
 Breathing is automatically controlled
Breathing control centers control contracting of breathing
muscles and set certain rate.
– 10-14 breaths / min at rest

CO2 and O2 sensors in the body sense CO2 and O2 levels in
the blood

breathing control centers in the brain (pons and medulla)
respond to CO2 levels (decreases in pH) in the blood

when CO2 levels are too high (pH is low), the brain sends
signals to the diaphragm and the rib muscles to contract (i.e.
you inhale)
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