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Chapter 13
Cardiovascular System
1
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Introduction
A.
B.
C.
The cardiovascular system consists of the
heart and vessels (arteries, capillaries and
veins.)
A functional cardiovascular system is vital
for supplying oxygen and nutrients to
tissues and removing wastes from them.
Deoxygenated blood is carried by the
pulmonary circuit to the lungs, while the
systemic circuit sends oxygenated blood to
all body cells.
2
Fig13.01
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The systemic circuit delivers oxygen to all
body cells and carries away wastes.
The pulmonary circuit eliminates carbon
dioxide via the lungs and oxygenates the
blood.
Deoxygenated blood
Oxygenated blood
O2
O2
CO2
Oxygenated
blood pumped to
all body tissues
via aorta
O2
CO2
Deoxygenated
blood pumped
to lungs via
pulmonary arteries
CO2
CO2
CO2
O2
CO2
CO2
O2
O2
CO2
O2
Alveolus
O2
Oxygenated blood returns
to heart via pulmonary veins
Deoxygenated blood returns
to heart via venae cavae
Left atrium
Right atrium
Left ventricle
Right ventricle
3
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Structure of the Heart
A.
B.
The heart is a hollow, cone-shaped,
muscular pump within the thoracic cavity.
Size and Location of the Heart
1.
The average adult heart is 14 cm
long and 9 cm wide.
2.
The heart lies in the mediastinum
under the sternum; its apex extends
to the fifth intercostal space and the
base lies beneath the second rib.
4
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C.
Coverings of the Heart
1.
The pericardium encloses the
heart.
2.
It is made of two layers: the outer,
tough connective tissue fibrous
pericardium surrounding a more
delicate visceral pericardium
(epicardium) that surrounds the
heart.
5
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3.
At the base of the heart, the
visceral pericardium folds back to
become the parietal pericardium
that lines the fibrous pericardium.
4.
Between the parietal and visceral
pericardia is a potential space
(pericardial cavity) filled with
serous fluid.
6
Fig13.02
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Right lung
Left lung
Aorta
Superior
vena cava
Pulmonary trunk
Diaphragm
Left auricle
Cut edge of
fibrous pericardium
Right auricle
Right atrium
Cut edge of
parietal pericardium
Heart (covered by
visceral pericardium)
Left ventricle
Right ventricle
Pericardial cavity
7
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D.
Wall of the Heart
1.
The wall of the heart is composed of
three distinct layers.
2.
The outermost layer, the epicardium, is
made up of connective tissue and
epithelium, and houses blood and
lymph capillaries along with coronary
arteries. It is the same as the visceral
pericardium.
8
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3.
4.
The middle layer called myocardium
consists of cardiac muscle and is
the thickest layer of the heart wall.
The inner endocardium is smooth
and is made up of connective tissue
and epithelium, and is continuous
with the endothelium of major
vessels joining the heart.
a.
The endocardium contains the
Purkinje fibers.
9
Fig13.04
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Pericardial
cavity
Parietal
pericardium
Fibrous
pericardium
Endocardium
Myocardium
Coronary
blood vessel
Epicardium
(visceral pericardium)
10
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E.
Heart Chambers and Valves
1.
The heart has four internal
chambers: two atria on top and two
ventricles below.
a.
Atria receive blood returning to
the heart and have thin walls
and ear-like auricles projecting
from their exterior.
b.
The thick-muscled ventricles
pump blood to the body.
11
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2.
A septum divides the atrium and
ventricle on each side. Each also
has an atrioventricular (A-V) valve
to ensure one way flow of blood.
a.
The right A-V valve (tricuspid)
and left A-V valve (bicuspid or
mitral valve) have cusps to
which chordae tendinae
attach.
12
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b.
Chordae tendinae are, in turn,
attached to papillary muscles
in the inner heart wall that
contract during ventricular
contraction to prevent the
backflow of blood through the
A-V valves.
13
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3.
The superior and inferior vena
cavae bring blood from the body to
the right atrium.
4.
The right ventricle has a thinner wall
than does the left ventricle because
it must pump blood only as far as
the lungs, compared to the left
ventricle pumping to the entire body.
14
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5.
At the base of the pulmonary trunk
leading to the lungs is the pulmonary
valve, which prevents a return flow of
blood to the ventricle.
6.
The left atrium receives blood from
four pulmonary veins. Blood passes
from the left atrium into the left
ventricle through the mitral valve.
7.
The left ventricle pumps blood into
the entire body through the aorta,
guarded by the aortic valve that
prevents backflow of blood into the
ventricle.
15
Fig13.05
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Superior vena cava
Aortic valve
Right pulmonary
artery
Right pulmonary
veins
Right atrium
Opening of coronary
sinus
Tricuspid valve
Right ventricle
Inferior vena cava
Aorta
Left pulmonary
artery
Pulmonary trunk
Left pulmonary
veins
Left atrium
Mitral (bicuspid)
valve
Chordae tendineae
Left ventricle
Papillary muscle
Interventricular
septum
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F.
Skeleton of the Heart
1.
Rings of dense connective tissue
surround the pulmonary trunk and
aorta to provide attachments for the
heart valves and fibers.
2.
These tough rings prevent dilating of
tissue in this area.
17
Fig13.06a
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© The McGraw -Hill Companies,Inc./University of Michigan Biomedical Communications
(a)
Fig13.06b
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Pulmonary valve
Aortic
valve
Opening of
left coronary
artery
Tricuspid
valve
Mitral valve
Fibrous skeleton
(b)
Posterior
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G.
Path of Blood Through the Heart
1.
Blood low in oxygen returns to the
right atrium via the venae cavae and
coronary sinus.
2.
The right atrium contracts, forcing
blood through the tricuspid valve
into the right ventricle.
20
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3.
The right ventricle contracts, closing
the tricuspid valve, and forcing
blood through the pulmonary valve
into the pulmonary trunk and
arteries.
4.
The pulmonary arteries carry blood
to the lungs where it can rid itself of
excess carbon dioxide and pick up a
new supply of oxygen.
21
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5. Freshly oxygenated blood is returned to
the left atrium of the heart through the
pulmonary veins.
6. The left atrium contracts, forcing blood
through the left bicuspid valve into the
left ventricle.
7. The left ventricle contracts, closing the
bicuspid valve and forcing open the
aortic valve as blood enters the aorta for
distribution to the body.
22
Fig13.07
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Systemic
capillaries
Tissue cells
CO2
Superior
vena cava
O2
Pulmonary
artery
Alveolus
CO2
CO2
Alveolar
capillaries
O2
O2
Alveolar
capillaries
Alveolus
Pulmonary
veins
Right atrium
Tricuspid valve
Pulmonary valve
Right ventricle
Inferior vena cava
Left atrium
Mitral valve
Left ventricle
Aortic valve
Aorta
CO2
Systemic
capillaries
O2
Tissue cells
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H.
Blood Supply to the Heart
1.
The first branches off of the aorta,
which carry freshly oxygenated
blood, are the right and left coronary
arteries that feed the heart muscle
itself.
2.
Branches of the coronary arteries
feed many capillaries of the
myocardium.
24
Fig13.08
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Aorta
Part of
aorta
removed
Aortic
valve
cusps
Right coronary
artery
Opening of
left coronary
artery
25
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3.
4.
The heart muscle requires a
continuous supply of freshly
oxygenated blood, so smaller
branches of arteries often have
anastomoses as alternate pathways
for blood, should one pathway
become blocked.
Cardiac veins drain blood from the
heart muscle and carry it to the
coronary sinus, which empties into
the right atrium.
26
Fig13.09a
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Aorta
Superior vena cava
Left pulmonary artery
Right pulmonary
artery
Pulmonary trunk
Left pulmonary veins
Right pulmonary
veins
Left auricle
Left coronary artery
Right auricle
Great cardiac vein
Anterior interventricular artery
(left anterior descending artery)
Right coronary
artery
Anterior cardiac vein
Small cardiac vein
Inferior vena cava
Left ventricle
Right ventricle
(a)
Apex of the heart
Fig13.09b
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Superior vena cava
Right pulmonary
artery
Aorta
Left pulmonary artery
Left pulmonary
veins
Right pulmona
Left auricle
Circumflex artery
Left atrium
Cardiac vein
Right atrium
Inferior vena cava
Coronary sinus
Middle cardiac vein
Left ventricle
Posterior interventricular
artery
Right ventricle
(b)
Apex of the heart
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Heart Actions
A.
The cardiac cycle consists of the atria
beating in unison (atrial systole) followed by
the contraction of both ventricles,
(ventricular systole) then the entire heart
relaxes for a brief moment (diastole).
29
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B.
Cardiac Cycle
1.
During the cardiac cycle, pressure
within the heart chambers rises and
falls with the contraction and
relaxation of atria and ventricles.
2.
When the atria fill, pressure in the
atria is greater than that of the
ventricles, which forces the A-V
valves open.
30
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3.
Pressure inside atria rises further as
they contract, forcing the remaining
blood into the ventricles.
4.
When ventricles contract, pressure
inside them increases sharply,
causing A-V valves to close and the
aortic and pulmonary valves to open.
a.
As the ventricles contract,
papillary muscles contract,
pulling on chordae tendinae
and preventing the backflow of
blood through the A-V valves.
31
Fig13.10
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Pulmonary
valve closed
Aortic
valve closed
Pulmonary
valve open
RA
Aortic
valve open
LA
Atrial systole
Atrial diastole
Tricuspid
and mitral
valves open
(a)
LV
RV
Ventricular
diastole
Tricuspid
and mitral
valves closed
Ventricular
systole
(b)
32
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C.
Heart Sounds
1.
Heart sounds are due to vibrations
in heart tissues as blood rapidly
changes velocity within the heart.
2.
Heart sounds can be described as a
"lubb-dupp" sound.
The first sound (lubb) occurs as
ventricles contract and A-V valves
are closing.
3.
4.
The second sound (dupp) occurs as
ventricles relax and aortic and
pulmonary valves are closing.
33
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D.
Cardiac Muscle Fibers
1.
A mass of merging fibers that act as
a unit is called a functional
syncytium; one exists in the atria
(atrial syncytium) and one in the
ventricles (ventricular syncytium).
34
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E.
Cardiac Conduction System
1.
Specialized cardiac muscle tissue
conducts impulses throughout the
myocardium and comprises the
cardiac conduction system.
2.
A self-exciting mass of specialized
cardiac muscle called the sinoatrial
node (S-A node or pacemaker),
located on the posterior right atrium,
generates the impulses for the
heartbeat.
35
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3.
Impulses spread next to the atrial
syncytium, it contracts, and
impulses travel to the junctional
fibers leading to the atrioventricular
node (A-V node) located in the
septum.
a.
Junctional fibers are small,
allowing the atria to contract
before the impulse spreads
rapidly over the ventricles.
36
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4.
Branches of the A-V bundle give
rise to Purkinje fibers leading to
papillary muscles; these fibers
stimulate contraction of the papillary
muscles at the same time the
ventricles contract.
37
Fig13.11
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Interatrial septum
Left
bundle
branch
SA node
AV node
AV bundle
Right bundle
branch
Purkinje fibers
Interventricular
septum
38
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F.
Electrocardiogram
1.
An electrocardiogram (ECG) is a
recording of the electrical changes
that occur during a cardiac cycle.
2.
The first wave, the P wave,
corresponds to the depolarization of
the atria.
3.
The QRS complex corresponds to
the depolarization of ventricles and
hides the repolarization of atria.
The T waves ends the ECG pattern
and corresponds to ventricular
repolarization.
4.
39
Fig13.14
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(a)
1.0
R
Millivolts
.5
T
P
0
Q
–.5
S
0
(b)
200
400
Milliseconds
600
40
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G.
Regulation of the Cardiac Cycle
1. The amount of blood pumped at any
one time must adjust to the current
needs of the body (more is needed
during strenuous exercise).
2. The S-A node is innervated by branches of
the sympathetic and parasympathetic
divisions, so the CNS controls heart rate.
a. Sympathetic impulses increase the speed of
heart rate.
b. Heart rate is decreased by parasympathetic
impulses.
41
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3.
The cardiac control center of the
medulla oblongata maintains a
balance between the sympathetic
and parasympathetic divisions of the nervous
system in response to messages from
baroreceptors which detect changes in blood
pressure.
4.
Impulses from the cerebrum or hypothalamus may
also influence heart rate, as do body temperature
and the concentrations of certain ions.
42
Fig13.16
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Receptor
Sensory or
afferent neuron
Central
Nervous
System
Motor or
efferent neuron
Effector
(muscle or gland)
(a)
Carotid
baroreceptors
Carotid
sinus
Cerebrum
(frontal
section)
Sensory
fibers
Common
carotid
artery
Hypothalamus
Aorta
Medulla oblongata
(transverse section)
Cardiac
center
Aortic
baroreceptors
Fibers of parasympathetic
vagus nerve
SA node
AV node
Spinal cord
(transverse sections)
Fibers of
sympathetic nerve
Sympathetic trunk
(b)
43
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Blood Vessels
A.
B.
The blood vessels (arteries, arterioles,
capillaries, venules, and veins) form a
closed tube that carries blood away from
the heart, to the cells, and back again.
Arteries and Arterioles
1.
Arteries are strong, elastic vessels
adapted for carrying high-pressure
blood.
2.
Arteries become smaller as they
divide and give rise to arterioles.
44
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3.
The wall of an artery consists of
an endothelium, tunica media
(smooth muscle), and tunica
externa (connective tissue).
4.
Arteries are capable of
vasoconstriction as directed by the
sympathetic impulses; when impulses
are inhibited, vasodilation results.
45
Fig13.17
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Artery
Vein
Lumen
Valve
Endothelium of
tunica interna
Connective tissue
(elastic and collagenous fibers)
Tunica media
Tunica externa
(a)
(b)
46
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C.
Capillaries
1.
Capillaries are the smallest vessels,
consisting only of a layer of
endothelium through which
substances are exchanged with
tissue cells.
2.
Capillary permeability varies from
one tissue to the next, generally
with more permeability in the liver,
intestines, and certain glands, and
less in muscle and considerably
less in the brain (blood-brain
barrier).
47
Fig13.19
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Tissue fluid
Endothelial cell
Slit
Tissue fluid
Capillary
48
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3.
The pattern of capillary density also
varies from one body part to the
next.
a.
Areas with a great deal of
metabolic activity (leg
muscles, for example) have
higher densities of capillaries.
49
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4.
Precapillary sphincters can regulate
the amount of blood entering a
capillary bed and are controlled by
oxygen concentration in the area.
a.
If blood is needed elsewhere
in the body, the capillary beds in
less important areas are shut
down.
50
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5.
Exchanges in Capillaries
a.
Blood entering capillaries
contains high concentrations
of oxygen and nutrients that
diffuse out of the capillary wall
and into the tissues.
b.
Plasma proteins remain in the
blood due to their large size.
51
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c.
d.
e.
Hydrostatic pressure drives the
passage of fluids and very small
molecules out of the capillary at
this point.
At the venule end, osmosis, due
to the osmotic pressure of the
blood, causes much of the tissue
fluid to return to the bloodstream.
Lymphatic vessels collect excess
tissue fluid and return it to
circulation.
52
Fig13.21
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Lymphatic
capillary
Blood
flow
from
arteriole
Outward force,
including
hydrostatic
pressure
35 mm Hg
Net outward
pressure
11 mm Hg
Inward force
of osmotic
pressure
24 mm Hg
Net force at arteriolar end
Outward force, including hydrostatic pressure = 35 mm Hg
Inward force of osmotic pressure
= 24 mm Hg
Net outward pressure
= 11 mm Hg
Capillary
Tissue
cells
Outward force,
Net inward
including
pressure
hydrostatic
8 mm Hg
pressure
Inward force of
16 mm Hg
osmotic pressure
24 mm Hg
Blood
flow to
venule
Net force at venular end
Outward force, including hydrostatic pressure = 16 mm Hg
Inward force of osmotic pressure
= 24 mm Hg
Net inward pressure
= 8 mm Hg
53
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D.
Venules and Veins
1.
Venules leading from capillaries
merge to form veins that return
blood to the heart.
2.
Veins have the same three layers
as arteries have and have a flap-like
valve inside to prevent backflow of
blood.
54
Fig13.23
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Toward
heart
(a)
(b)
55
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a.
Veins are thinner and less
muscular than arteries; they do
not carry high-pressure blood.
b.
Veins also function as blood
reservoirs.
56
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Blood Pressure
A.
Blood pressure is the force of blood
against the inner walls of blood vessels
anywhere in the cardiovascular system,
although the term "blood pressure"
usually refers to arterial pressure.
57
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B.
2.
Arterial Blood Pressure
1.
Arterial blood pressure rises and
falls following a pattern established
by the cardiac cycle.
a.
During ventricular contraction,
arterial pressure is at its
highest (systolic pressure).
b.
When ventricles are relaxing,
arterial pressure is at its
lowest (diastolic pressure).
The surge of blood that occurs with
ventricular contraction can be felt at
certain points in the body as a
pulse.
58
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C.
Factors that Influence Arterial Blood Pressure
1.
Arterial pressure depends on heart
action, blood volume, resistance to
flow, and blood viscosity.
2.
Heart Action
a.
Heart action is dependent upon
stroke volume and heart rate
(together called cardiac output);
if cardiac output increases, so
does blood pressure.
59
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3.
Blood Volume
a.
Blood pressure is normally
directly proportional to the
volume of blood within the
cardiovascular system.
b.
Blood volume varies with age,
body size, and gender.
60
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4.
Peripheral Resistance
a.
Friction between blood and
the walls of blood vessels is a
force called peripheral
resistance.
b.
As peripheral resistance
increases, such as during
sympathetic constriction of
blood vessels, blood pressure
increases.
61
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5.
Blood Viscosity
a.
The greater the viscosity (ease
of flow) of blood, the greater its
resistance to flowing, and the
greater the blood pressure.
62
Fig13.25
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Blood volume
increases
Heart rate
increases
Stroke volume
increases
Blood pressure increases
Blood viscosity
increases
Peripheral resistance
increases
63
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D.
Control of Blood Pressure
1.
Blood pressure is determined by
cardiac output and peripheral
resistance.
2.
3.
4.
The body maintains normal blood
pressure by adjusting cardiac output
and peripheral resistance.
Frank-Starling law of the heart is the
relationship between fiber length
and force of contraction.
Baroreceptors sense change in BP
64
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3.
Cardiac output depends on stroke
volume and heart rate, and a
number of factors can affect these
actions.
a.
The volume of blood that
enters the right atrium is
normally equal to the volume
leaving the left ventricle.
65
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b.
c.
If arterial pressure increases,
the cardiac center of the
medulla oblongata sends
parasympathetic impulses to
slow heart rate.
If arterial pressure drops, the
medulla oblongata sends
sympathetic impulses to
increase heart rate to adjust
blood pressure.
66
Fig13.26
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Cardiac output increases
Blood pressure rises
Baroreceptors in aortic arch and
carotid sinuses are stimulated
Sensory impulses to cardiac center
Parasympathetic impulses to heart
SA node inhibited
Heart rate decreases
Blood pressure returns
toward normal
67
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d.
Other factors, such as
emotional upset, exercise, and
a rise in temperature can
result in increased cardiac
output and increased blood
pressure.
68
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4.
The vasomotor center of the
medulla oblongata can adjust the
sympathetic impulses to smooth
muscles in arteriole walls, adjusting
blood pressure.
a.
Certain chemicals, such as
carbon dioxide, oxygen, and
hydrogen ions, can also affect
peripheral resistance.
69
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E.
Venous Blood Flow
1.
Blood flow through the venous
system is only partially the result of
heart action and instead also
depends on skeletal muscle
contraction, breathing movements,
and vasoconstriction of veins
(venoconstriction).
70
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a.
Contractions of skeletal
muscle squeeze blood back
up veins one valve at a time.
b.
Differences in thoracic and
abdominal pressures draw
blood back up the veins.
71
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Paths of Circulation
A.
The body’s blood vessels can be divided
into a pulmonary circuit, including vessels
carrying blood to the lungs and back, and
a systemic circuit made up of vessels
carrying blood from the heart to the rest of
the body and back.
72
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B.
Pulmonary Circuit
1.
The pulmonary circuit is made up of
vessels that convey blood from the
right ventricle to the pulmonary
arteries to the lungs, alveolar
capillaries, and pulmonary veins
leading from the lungs to the left
atrium.
73
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C.
Systemic Circuit
1.
The systemic circuit includes the
aorta and its branches leading to all
body tissues as well as the system
of veins returning blood to the right
atrium.
74
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Arterial System
A.
B.
The aorta is the body’s largest artery.
Principal Branches of the Aorta
1.
The branches of the ascending
aorta are the right and left coronary
arteries that lead to heart muscle.
2.
Principal branches of the aortic arch
include the brachiocephalic, left
common carotid, and left subclavian
arteries.
75
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3.
The descending aorta (thoracic
aorta) gives rise to many small
arteries to the thoracic wall and
thoracic viscera.
4.
The abdominal aorta gives off the
following branches: celiac, superior
mesenteric, suprarenal, renal,
gonadal, inferior mesenteric, and
common iliac arteries.
76
Fig13.27
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Right common carotid a.
Right subclavian a.
Left common carotid a.
Left subclavian a.
Brachiocephalic a.
Aortic arch
Ascending aorta
Left coronary a.
Right coronary a.
Abdominal aorta
Left gastric a.
Celiac a.
Splenic a.
Hepatic a.
Right gastric a.
Suprarenal a.
Right renal a.
Superior mesenteric a.
Lumbar a.
Gonadal a.
Inferior mesenteric a.
Middle sacral a.
Right common iliac a.
Left common iliac a.
77
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C.
Arteries to the Head, Neck, and Brain
1.
Arteries to the head, neck, and brain
include branches of the subclavian
and common carotid arteries.
2.
The vertebral arteries supply the
vertebrae and their associated
ligaments and muscles.
78
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3. In the cranial cavity, the vertebral
arteries unite to form a basilar artery
which ends as two posterior cerebral
arteries.
4. The posterior cerebral arteries help form
the cerebral arterial circle which provides
alternate pathways through which blood
can reach the brain.
79
Fig13.29
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Anterior
cerebral a.
Anterior
cerebral a.
Posterior
communicating a.
Posterior
cerebral a.
Internal
carotid a.
Pituitary
gland
Basilar a .
Basilar a .
Vertebral a.
Spinal cord
80
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5.
6.
7.
The thyrocervical arteries are short
vessels that give off branches to
various parts of the neck, shoulder,
and back.
The right and left common carotid
arteries diverge into the external
carotid and internal carotid arteries.
Near the base of the internal carotid
arteries are the carotid sinuses that
contain baroreceptors to monitor
blood pressure.
81
Fig13.28
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Superficial
temporal a.
Posterior
.auricular a.
Anterior choroid a.
.Basilar a
.Occipital a
Maxillary a.
Internal
.carotid a.
External
carotid a.
Facial a.
Carotid sinus
Lingual a.
Vertebral a.
Superior thyroid a.
Thyrocervical
axis
Common carotid a.
Subclavian a..
Brachiocephalic a.
82
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D.
Arteries to the Shoulder and Upper Limb
1.
The subclavian artery
continues into the arm where
it becomes the axillary artery.
2.
In the shoulder region, the
axial artery becomes the
brachial artery that, in turn,
gives rise to the ulnar and
radial arteries.
83
Fig13.30
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Right common carotid a.
Right subclavian a.
Axillary a.
Anterior circumflex a.
Posterior circumflex a.
Deep brachial a.
Brachial a.
Radial recurrent a.
Radial a.
Ulnar recurrent a.
Ulnar a.
Principal
artery of
thumb
Deep volar arch a.
Superficial volar arch a.
Digital a.
84
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E.
Arteries to the Thoracic and Abdominal Walls
1.
Branches of the thoracic aorta and
subclavian artery supply the thoracic
wall with blood. (internal thoracic artery,
anterior intercostal arteries and posterior
intercostal arteries)
2.
Branches of the abdominal aorta, as
well as other arteries, supply the
abdominal wall with blood. (internal
thoracic, external iliac, phrenic and
lumbar arteries).
85
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F.
Arteries to the Pelvis and Lower Limb
1.
At the pelvic brim, the abdominal
aorta divides to form the common
iliac arteries that supply the pelvic
organs, gluteal area, and lower
limbs.
86
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2.
The common iliac arteries divide
into internal and external iliac
arteries.
a.
Internal iliac arteries supply
blood to pelvic muscles and
visceral structures.
b.
External iliac arteries lead into
the legs, where they become
femoral, popliteal, anterior
tibial, and posterior tibial
arteries.
87
Fig13.31
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Superficial temporal a.
External carotid a.
Internal carotid a.
Vertebral a.
Common carotid a.
Subclavian a.
Brachiocephalic a.
Aorta
Axillary a.
Coronary a.
Intercostal a.
Suprarenal a.
Deep brachial a.
Brachial a.
Celiac a.
Renal a.
Superior mesenteric a.
Radial a.
Lumbar a.
Inferior mesenteric a.
Common iliac a.
Internal iliac a.
Gonadal a.
External iliac a.
Ulnar a.
Deep femoral a.
Femoral a.
Popliteal a.
Anterior tibial a.
Posterior tibial a.
Fibular a.
Dorsalis pedis a.
88
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Venous System
A.
B.
Veins return blood to the heart after the
exchange of substances has occurred in
the tissues.
Characteristics of Venous Pathways
1.
Larger veins parallel the courses of
arteries and are named accordingly;
smaller veins take irregular
pathways and are unnamed.
89
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2.
Veins from the head and upper
torso drain into the superior vena
cava.
3.
Veins from the lower body drain into
the inferior vena cava.
4.
The vena cavae merge to join the
right atrium.
90
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C.
Veins from the Head, Neck, and Brain
1.
The jugular veins (internal & external)
drain the head and unite with the
subclavian veins to form the
brachiocephalic veins.
91
Fig13.32
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Venous
Sinuses
Superior
ophthalmic v.
Vertebral v.
Right external
jugular v.
Right
.
subclavian
v.
Anterior
facial v.
Right internal
jugular v.
Right axillary v.
Right brachiocephalic v.
92
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D.
Veins from the Upper Limb and Shoulder
1.
The upper limb is drained by
superficial and deep veins.
2.
The basilic and cephalic veins
are major superficial veins.
3.
The major deep veins include
the radial, ulnar, brachial, and
axillary veins.
E.
Veins from the Abdominal and Thoracic
Walls
1.Tributaries of the brachiocephalic and
azygos veins drain the abdominal and
thoracic walls.
93
Fig13.33
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Right internal jugular v.
Right external jugular v.
Right subclavian v.
Right brachiocephalic v.
Axillary v.
Brachial vv.
Cephalic v.
Basilic v.
Median cubital v.
Radial vv.
Superior vena cava
Left brachiocephalic v.
Ulnar vv.
Dorsal arch v.
94
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F.
Veins from the Abdominal Viscera
1.
Blood draining from the intestines
enters the hepatic portal system and
flows to the liver first rather than into
general circulation.
2.
The liver can process the nutrients
absorbed during digestion as well
as remove bacteria.
95
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3.
Hepatic veins drain the liver, gastric
veins drain the stomach, superior
mesenteric veins lead from the
small intestine and colon, the
splenic vein leaves the spleen and
pancreas, and the inferior
mesenteric vein carries blood
from the lower intestinal area.
96
Fig13.34
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Liver
Stomach
Hepatic
portal v.
Left gastric v.
Right gastric v.
Gallbladder
Spleen
Pancreas
Splenic v.
Superior
mesenteric v.
Inferior
mesenteric v.
Small intestine
Ascending colon
Descending colon
Rectum
97
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G.
Veins from the Lower Limb and Pelvis
1.
Deep and superficial veins drain the
leg and pelvis.
2.
The deep veins include the anterior
and posterior tibial veins which unite
into the popliteal vein and femoral
vein (becomes the extrenal iliac
vein); superficial veins include the
small and great saphenous veins.
3.
These veins all merge to empty into
the common iliac veins.
98
Fig13.35
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Superficial
temporal v.
External jugular v.
Anterior facial v.
Internal jugular v.
Subclavian v.
Right brachiocephalic v.
Axillary v.
Superior vena cava
Azygos v.
Cephalic v.
Brachial vv.
Hepatic v.
Basilic v.
Inferior vena cava
Median cubital v.
Renal v.
Radial vv.
Ascending lumbar v.
Ulnar vv.
Gonadal v.
Common iliac v.
Internal iliac v.
External iliac v.
Femoral v.
Great saphenous v.
Popliteal v.
Posterior tibial vv.
Small saphenous v.
Anterior tibial vv.
99