A&P II (The Cardiovascular System) Need a timed quiz and a lab completed by midnight tonight! Pay negotiable!!Quiz is 20 minutes for 20 questions. *

A&P II (The Cardiovascular System)
Need a timed quiz and a lab completed by midnight tonight! Pay negotiable!!Quiz is 20 minutes for 20 questions.

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The cardiac conduction system
Cardiovascular System: The Heart
Chapter 17(II)

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Cells of cardiac conduction system
Pacemaker cells are concentrated in

Sinoatrial (SA) node in the wall of right atrium, below
opening of superior vena cava

SA cells generate action potentials at highest rate in the
heart 6080 per minute (our heart rate about 72-75/min)

serves as heart pacemaker that initiates heartbeats &
sets heart rate

Atrioventricular (AV) node in the wall of right atrium,
at junction b/w atrium & ventricle, above tricuspid valve

AV cells generate action potentials at a rate of 4060
per minute & serve as electrical gateway to ventricles

Conducting cells pacemaker cells that make pathways
throughout myocardium & can generate action potentials at
lowest rate of about 20/min

Pacemaker cell from the dog heart
*
By courtesy of Dr. Protas (Columbia University)

Pathways of cardiac conduction system
Conducting cells

Internodal pathways conducting cells that propagate
action potentials to atrial muscle cells

Atrioventricular bundle (bundle of His) conducting cells
between AV node & ventricular cells

branches of AV bundle right & left divisions of AV bundle;
enter interventricular septum & spread in ventricular walls

Purkinje fibers specific pacemaker cells make terminal
portions of AV bundle within walls of left & right ventricles

Purkinje fibers thicker than other conducting cells & can
transmit action potentials faster than other cells
*
There are no fibers in the conduction system

Pacemaker cells with low activity conduct action potentials

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Impulse propagation in conduction system
From SA node, action potentials travel through atria at 1 m/sec

AV node slows speed of propagation to 0.05 m/sec
conducting cells here are thin & have few gap junctions

slower speed delays impulse propagation to ventricles for
130 msec delays the beginning of ventricular
contraction (systole)

this delay allows atria to complete contraction (systole) &
eject required amount of blood into ventricles entirely
fill ventricles with blood during their diastole

AV bundle & Purkinje fibers speed up signal propagation
to ventricular cells to 4 m/sec

ventricular contraction (systole) begins at apex & moves up

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Pacemaker cells & sinus rhythm

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Action potentials in cardiac pacemaker cell (to remind)
repolarization

depolarization

level of the resting membrane potential

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*
Action potentials in contractile cardiac muscle cell
Contractile cardiac muscle cells have stable resting
membrane potential of 80 mV

At threshold 75 mV, voltage-gated Na+ channels open

Na+ rushes into cell, causing rapid depolarization; action
potential peaks at +20 mV; Na+ channels close quickly

However, depolarization continues for 200 msec longer,
making plateau, due to slow influx of Ca2+

Plateau extends ventricular contraction so ventricles have
enough time to eject required amount of blood

Repolarization Ca2+ channels close, K+ voltage-gated
channels open & K+ outflow returns membrane to resting level

Excitation-contraction coupling action potentials spread to
sarcoplasmic reticulum, open Ca2+ channels there, Ca2+ enter
cytoplasm, cytoplasmic Ca2+ increases & contraction starts

*

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*

Action potentials of a cardiac ventricular cell
-100
-80
-40
-60
+20
0
-20
2
3
4
0
1
Membrane Potential
(mV)
seconds
phase 0 fast voltage-gated Na+ channels open
phase 1 Na+ channels close
phase 2 slow voltage-gated Ca++ channels open
phase 3 slow voltage-gated K+ channels open
phase 4 return to the resting membrane potential

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Contractile cell action potential

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Plateau in action potential of contractile cells lengthens

absolute refractory period of cardiac muscle to 200-250 ms

during this time, cardiac muscle cells can not contract

Cardiac muscle has enough time to relax before next

contraction heart is protected against summation &
tetanus
Refractory period of cardiac muscle
10-15 msec
200-250 msec
What is highest
possible heart
rate?
240-300/min

mV
SKELETAL
MUSCLE
CARDIAC
MUSCLE
Action potential
mV
Contraction
Tension
Time (msec)
Time (msec)
Contraction
Tension
Action
potential
Absolute refractory
period
Relative refractory
period
Action potential, contraction
& refractory period in skeletal & cardiac muscle cells
*
duration of action potential ~300 ms; duration of contraction ~170 ms
duration of action potential ~15 ms; duration of contraction ~25 ms
Complete tetanus
Stimulus frequency is so high that
relaxation phase is eliminated &
tension plateaus at maximal levels.
Incomplete tetanus

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Your take-home (prerequisite) test is on Canvas, in the folder
Quizzes

You may take the test between 12:00 PM (noon) Sunday, January
26, and 11:59 PM Tuesday, January 28 ONLY

Make sure your computer and Internet work properly

There are 35 questions on material of Chapters 10, 11, 14 in the
test (see p. 4 in my syllabus)

After you open the test, you have one attempt ONLY to complete
and submit it

You can see one question at a time

You cannot go back to a previous question and change your
answer

You have 40 min to answer all questions and submit the test

Don’t forget to click the “Submit” button after the test is
completed

You can see your result and correct answers between 8:00 AM
and 11:59 PM Wednesday, January 29
Take-home Test

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Recording electrocardiogram

ECG summation of
all action potentials of
nodal & myocardial cells
recorded by electrodes
on arms, legs & chest

Electrical changes are
seen as ECG waves

ECG is recorded with
electrocardiograph

Most obvious
changes in heart seen
in ECG is disturbances
in electrical rhythm
arrhythmia
Electrocardiogram (ECG, EKG) graphic representation of
changes in electrical activity in the whole cardiac muscle

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ECG waves, intervals, segments
Waves P wave, QRS complex, T wave

periods between waves represent action potential

phases & spread of electrical activity through heart
Intervals include a
component of at least
one wave: R-R interval,
P-R interval, Q-T
interval

Segments do not
include any wave
components: ST
segment

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P wave depolarization of
atrial cells, except SA node

QRS complex cells in
ventricles depolarize

T wave ventricular
repolarization

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onset of pain; beginning of MI
1 hr later; onset of necrosis
inverted T; sign of reperfusion
24 hrs later; ST returned to iso-electric line; T stays inverted
EKG looks normal; deep Q indicates dead myocardium; will remain in EKG
recent myocardial wall infarction
scar formation in the infarction place

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P-R interval period from
beginning of P wave to
beginning of R wave; time
required for spread of
depolarization from SA node
through atria to ventricles;
includes AV node delay

Q-T interval time from
beginning of QRS complex
to end of T wave; action
potentials spread through
ventricular cells
ECG intervals
R-R interval time between two successive R waves shows
duration of generation & spread of action potential through
the heart; can be measured to determine heart rate

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Disturbances in heart rate

Bradycardia heart rate

under 60 beats/minute

Tachycardia heart rate

over 100 beats/minute

sinus tachycardia

regular fast rhythm
Cardiac arrhythmias
Disturbances in conduction

blockage along conduction
system heart block

Partial blockage at AV node

P-R interval is longer, due to

increased time for spread to ventricles through AV node

extra P waves some SA node action potentials are not

conducted through AV node

Ectopic (abnormal) location of pacemaker cells results in

arrhythmias

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Complete AV heart block with atrial tachycardia
*

rate of atria ~120/min rate of ventricles ~33/min
1 sec 25 mm
R
P+T
P
P
P
P
P
R
R
R
R
P+T
P+T
P+QRS
four P for one R

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Atrial fibrillation not life threatening because atrial

contraction is not necessary for ventricular filling

ECG recording lacks many P waves

Cardiac arrhythmias: fibrillation
Ventricular fibrillation immediately life-threatening !!
chaotic activity on ECG;
SA node may resume
pacing heart after shock
by electrical defibrillation

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Relationships between pressure, valve position & blood flow (left ventricle)

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Cardiac cycle sequence of events in heart during time
between start of one heartbeat and beginning of the next

Each cardiac cycle consists of relaxation period
diastole & contraction period systole, for each chamber

Atrial & ventricular diastoles & systoles occur at
different times as result of AV node delay

Left & right heart ventricles pump blood into
corresponding circuits simultaneously

Cycle is divided into four main phases defined by
actions of ventricles & positions of valves: filling,
contraction, ejection & relaxation
Cardiac cycle and its phases

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Ventricular filling phase
Ventricular filling blood drains from atria into ventricles,

ventricular pressures lower than in atria, p. trunk, aorta

Pressure in pulmonary trunk & aorta increases semilunar

valves closes; no blood flow from the vessels into ventricles
AV valves open due to
higher atrial pressure
blood flows passively from
atria into ventricles 70-80%
of volume passive filling

Atrial systole contracting
atria eject remaining 20-30%

At end of atrial systole and
ventricular diastole
ventricles contain ~120 ml
of blood end-diastolic
volume (EDV)
0.1 sec

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Starts with short isovolumetric contraction in the beginning
of ventricular systole
Ventricular contraction phase
(systole)
Pressure in ventricles rises
rapidly high pressure closes
AV valves & causes S1 heart
sound

Ventricular pressure not high
enough to open semilunar valves

both semilunar valves are still
closed ventricular volume
does not change (isovolumetric =
same volume)

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Systole of ventricles continues
ventricular ejection phase starts
pressure in ventricles rises higher
than in pulmonary trunk & aorta

semilunar valves open rapid
outflow of blood from ventricles

Ejection continues pressure in
pulmonary trunk & aorta approaches
that in ventricles

ejection of blood into vessels
decreases considerably

About 70 ml of blood pumped from
each ventricle in ejection phase
stroke volume (SV)

50 ml remains in each ventricle after
ejection end-systolic volume (ESV)
Ventricular
ejection phase
0.3 sec

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When ventricular diastole
begins, brief isovolumetric
relaxation occurs blood
pressure in ventricles declines

Semilunar valves shut,
S2 heart sound is heard

Pressure in ventricles still
higher than in atria & AV
valves remain closed

No blood ejected from
ventricles or enters ventricles
ventricular blood volume
briefly remains constant
Ventricular relaxation phase
(diastole)
0.4 sec
One cardiac
cycle total
time 0.8 sec
When heart rate increases all phases
of cardiac cycle shorten, particularly
diastole !!!

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Normal blood flow through open AV & semilunar valves
does not produce sounds

Sounds generated only when valves closing & result from
vibrations of ventricular & blood vessel walls

Two heart sounds: S1 lub when AV valves close & S2
dub when semilunar valves close; S1 is typically longer
louder than S2

Heart murmur when blood flow through heart is turbulent;
heart murmurs are generally caused by defective valves

Children often have heart murmurs do not represent defects

Stethoscope clinical device used to listen to (auscultate)
rhythmic heart sounds, to measure blood pressure; to listen
to sounds produced by (i) breathing, (ii) gastrointestinal
tract, (iii) developing fetus in the uterus
Heart sounds

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Auscultation of heart sounds

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Blood volume in ventricles
End-systolic volume ESV 50 ml

Passively added to ventricle
before atrial systole 50 ml

Added by atrial systole 20 ml

End-diastolic volume EDV 120 ml

Stroke volume SV blood ejected
by one ventricular systole 70 ml

End-systolic volume ESV 50 ml
Both ventricles eject same amount of blood

When heart rate increases all phases of cardiac cycle

shorten, particularly diastole

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Characteristic ventricular volumes
End-diastolic volume EDV 120 ml

End-systolic volume ESV 50 ml

Stroke volume SV SV = EDV ESV

120 ml 50 ml = 70 ml per one heart beat

Ejection fraction percentage of EDV represented by SV

(SV x 100) / EDV (70 x 100) /120 ~ 58% normal 50-65%

Cardiac output CO volume pumped by each ventricle into
systemic or pulmonary circuit in one minute

CO = SV x HR 70 ml x 72/min = 5040 ml/min

Each ventricle pumps into its circuit ~5 liters per minute

Adult blood volume ~5 liters entire stock of blood passes
through heart every minute

Factors that influence cardiac output
Cardiac output (CO = SV x HR) affected by changes in
both heart rate & stroke volume

Stroke volume (SV = EDV ESV) affected by changing
EDV or ESV

Heart rate regulated by autonomic nervous system,
circulating hormones, venous return & stretch receptors
although heart is autorhythmic, it still requires regulation to
ensure that cardiac output meets body needs at all times
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A. Factors affecting heart rate
Agents that influence rate of SA node pacemaker cells
chronotropic agents

Increase rate positive chronotropic agents sympathetic
nervous system, certain hormones, elevated body T0

Decrease rate negative chronotropic agents para-
sympathetic nervous system & decreased body T0

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Autonomic heart
regulation
Sympathetic system
increases cardiac output
with positive (A) chronotropic
and (B) inotropic effects
A. heart rate increases due to
accelerated SA pacemaker
cells (up to 180200 per min)
B. stroke volume increases
due to increased cardiac
muscle cell contractility
Parasympathetic system
decreases cardiac output
with negative (A) chronotropic
and (B) inotropic effects
A. heart rate decreases due to
suppressed SA cells
B. stroke volume decreases
due to decreased cardiac cell
contractility

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Sympathetic effects on the heart (1)
Cardioacceleratory center in
medulla oblongata activates
sympathetic spinal neurons &
sympathetic cardiac nerves
that terminate on SA node cells
& on some cardiac muscle cells
in ventricles

Nerves release norepinephrine
(NE) that binds to & activates
-1 adrenoreceptors in SA
pacemaker cells & cardiac
muscle cells

Activated receptors open Na+ &
Ca2+ channels & cause depo-
larization of pacemaker &
contractile cells
Cardioacceleratory
center
Cardioinhibitory
center

Sympathetic effects on the heart (2)
Under sympathetic stimulation

A. the rate of action potentials in SA cell increases
positive chronotropic effect

B. the strength of cardiac muscle contractions increases
positive inotropic effect

Hormones epinephrine, norepinephrine, thyroid hormone &
certain drugs also have positive chronotropic effect
*
No stimulation
Heart rate 75 bpm
threshold
Resting potential
Sympathetic stimulation
Heart rate 120 bpm
Resting potential

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Parasympathetic effects on the heart
Cardioinhibitory center in medulla oblongata activates
vagus nerve & postganglionic parasympathetic fibers that
terminate on SA node pacemaker cells & on some cardiac
muscle cells in ventricles

The terminals release acetylcholine (ACh) that binds to &
activates muscarinic receptors in pacemaker cells &
cardiac muscle cells

Activated receptors open K+ channels & cause hyper-
polarization of pacemaker & contractile cells

A. the rate of pacemaker cell action potentials decreases
negative chronotropic effect

B. the strength of cardiac muscle contractions decreases
negative inotropic effect

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Parasympathetic effect on heart rate
No stimulation
Heart rate 75 bpm
Resting potential
Resting potential
Parasympathetic stimulation
Heart rate 40 bpm

Autonomic tone Sinus rhythm
Sympathetic & parasympathetic fibers have tonic activity
at rest autonomic tone

Parasympathetic influence, called vagal tone, is stronger

If vagus nerve is separated from the heart rate of SA pace-
makers increases from ~75 to ~95 beats per minute (bpm)

Vagal tone causes slight hyperpolarization of SA cells &
holds them at a lower rate of 7080 bpm sinus rhythm

Strong vagal stimulation decreases heart rate to 20 bpm

Maximum vagal stimulation can stop heart for a few
seconds; then, heart escapes & starts beating at initial
rate of 20-40 bpm
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25
20
15
10
5
0
-4
0
+4
+8
Cardiac Output (L/min)
Right atrial pressure (mm Hg)
Parasympathetic
stimulation
Zero
sympathetic stimulation
Intermediate
sympathetic stimulation
Maximum
sympathetic stimulation
Effect of sympathetic & parasympathetic stimulation on cardiac output (via heart rate)

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Receptors, cardiac centers, heart rate
Interoreceptors signal about changes in interior activity to
cardiac centers in medulla oblingata heart rate (HR)
changes to meet metabolic demands

Higher centers cerebral cortex, hypothalamus, limbic
structures influenced by sensory & emotional stimuli, adjust
heart rate by effects on medulla oblongata

Baroreceptors, located in aorta & internal carotid artery,
signal medulla oblongata centers about blood pressure (BP)

if BP decreases impulse rate from receptors drops &
cardiac center activates sympathetic system

if BP increases impulse rate from receptors rises &
cardiac center activates parasympathetic system

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Location of
arterial baro-
and chemo-
receptors
Chemoreceptors sensitive to blood

pH, CO2, O2 located in aortic arch
& external carotid artery signal
medulla oblongata

if blood CO2 increases impulse

rate from receptors rises & cardiac
center activates sympathetic
system

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Autonomic reflex arc
in regulation of blood
pressure
Increasing BP was detected by
arterial baroreceptors (1)

Afferent nerve carries receptor
signal to medulla oblongata (2)

Efferent signals from medulla
oblongata travel in vagus
nerve to heart (3)

Heart rate decreases, reducing
blood pressure (4)
*

Venous return, atrial (Bainbridge) reflex & heart rate
Venous return amount of blood returning by veins to the
right atrium every minute

If right atrium receives larger blood volume its walls & SA
pacemaker cells inside them stretch SA cells stimulated
rate of SA cell action potentials & then heart rate increase

direct effect on heart rate

Bainbridge reflex adjusts heart rate in response to venous
return if right atrium receives larger blood volume
stretch receptors in its wall are stimulated they activate
neurons in medulla oblongata the neurons activate cells
of sympathetic system heart rate & cardiac output increase

indirect effect on heart rate
*

*
B. Factors affecting stroke volume:
Preload
Three factors influence stroke volume preload, heart

contractility & afterload

Preload degree of stretching of ventricular muscle cells

during diastole; directly proportional to EDV

in turn, EDV depends on filling time & venous return

Preload ability of muscle cells to produce tension

Frank-Starling law about relationship between preload &

stroke volume the more ventricular muscle cells
stretch, the more forcefully they contract
(principle more IN more OUT)

stretching causes more optimal overlap of actin & myosin filaments

& enables stronger contraction & higher stroke volume (p. 365)
Hormonal regulation may occur through changing blood volume

atrial natriuretic peptide ANP increases loss of fluid in urine, thus
decreasing blood volume and, in turn, stroke volume

*
Factors affecting stroke volume:
Contractility & afterload
Contractility heart intrinsic ability to generate tension

contractility increases stroke volume increases & ESV

decreases; contractility decreases opposite effects

Agents that affect contractility inotropic agents

positive inotropic agents sympathetic activation; hormones

NE, epinephrine, thyroid hormone, dopamine

negative inotropic agents -blockers, Ca channel blockers

Afterload force that ventricles must overcome to eject blood

into aorta & pulmonary trunk

Mostly determined by blood pressure in arteries

Afterload increases ventricular pressure must be greater to

open semilunar valves; stroke volume drops & ESV increases

Afterload decreases stroke volume rises & ESV decreases

*
Ventricular hypertrophy
Long increase in preload & afterload results in enlargement

of ventricles ventricular hypertrophy

Cardiac muscle cells generate higher tension to continue

pumping against higher afterload

muscle fibers make more myofibrils & organelles & get bigger

Right ventricular hypertrophy results from respiratory

disease or high blood pressure in pulmonary circuit

Left ventricular hypertrophy results from high blood

pressure in systemic circuit

Ventricular hypertrophy can increase heart pumping up to

certain point; however, heart lumen & filling space decreases

Risk for heart failure increases

*
Heart failure reduced heart ability to pump effectively

Causes (i) reduced contractility (myocardial ischemia,
infarction), (ii) any valvular heart disease, (iii) disease of
heart muscle (cardiomyopathy) & electrolyte imbalances

Heart pathology results in decreased stroke volume, which
reduces cardiac output

Left ventricular failure blood backs up within pulmonary
circuit pulmonary congestion

this increases pressure in pulmonary vessels, driving fluid
out of capillaries into lungs pulmonary edema

Right & left ventricular failure may produce peripheral
edema, in which blood backs up in systemic capillaries
systemic congestion

Treatment increasing cardiac output
Heart failure

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Cardiovascular System: The Heart
Chapter 17(I)
The heart is located in
the middle of thoracic
cavity mediastinum,
within the pericardial
cavity
Apex
Base
Cardiovascular system Heart Blood Blood vessels
Heart has four
chambers: left &
right atria and left
& right ventricles
weight 250350 g
beats ~100,000 times/day
pumps ~8,000 L of blood/day

*
Position of heart in thoracic cavity
position of the apex in the 4th intercostal space

*
Atria receive blood from veins

(vessels that bring blood TO heart)

right atrium from superior &

inferior venae cavae

left atrium from pulmonary veins

Blood drains from atria to ventricles

Ventricles pump blood into

arteries (vessels that carry blood
FROM the heart)

right ventricle to the pulmonary

trunk, then to pulmonary arteries

left ventricle to the aorta

Sup. vena cava
Inf. vena cava
Aorta
Pulm. trunk
Heart chambers & blood vessels

Pulmonary circuit
*
Pulmonary arteries deliver
deoxygenated (O2-poor & CO2-rich)
blood from right ventricle to lungs

Gas exchange occurs between
lung alveoli & pulmonary capillaries

O2 diffuses from air in alveoli into
capillary blood (oxygenation) & CO2
diffuses from blood in capillaries to
air in alveoli (to be exhaled)

Pulmonary veins deliver
oxygenated (O2-rich) blood to left
atrium
Heart pumps blood through two circuits (loops of vessels)

In pulmonary circuit blood moves TO and FROM the lungs

Systemic circuit
*
There, O2 diffuses from blood
into tissues & CO2 diffuses from
tissues into blood

After such exchange, blood is
deoxygenated; veins deliver it
to right atrium, to be pumped
into pulmonary circuit

pulmonary circuit carries blood
only to lungs & has low blood
pressure
Systemic circuit carries blood to
entire body & has high blood
pressure
Left side of heart systemic pump: receives oxygenated
blood from pulmonary veins & pumps it to aorta & its branches
that serve rest of body systemic circuit

Arteries deliver oxygenated blood from left ventricle to
systemic capillaries

Pericardium
*
Pericardium membranous
structure surrounding heart

Fibrous pericardium outer layer
tough collagen bundles anchor heart to diaphragm & great vessels
low distensibility doesnt change shape/size & prevent heart chambers from overfilling
Serous pericardium thin inner serous membrane that
is composed of two layers & produces serous fluid

Parietal pericardium fused to fibrous pericardium; encases heart like sac; at great vessels,
it folds under itself & forms

*
cardiac tamponade
fluid or blood
accumulates inside
pericardial cavity;
squeezes heart;
filling of ventricles &
amount of pumped
blood decreases

*
The heart wall
Myocardium thickest layer of wall; cardiac muscle cells
attached to inner fibrous skeleton

Endocardium internal layer; simple squamous epithelium
endothelium; continuous with lining of great vessels & valves

*
Great vessels carry blood to & from the heart
Major systemic veins drain most of systemic circuit

superior vena cava & inferior vena cava drain deoxy-

genated blood from veins above & below diaphragm

the veins open into posterior aspect of

right atrium
Pulmonary
trunk largest
artery in circuit;
receives deoxy-
genated blood
from right
ventricle

splits into right &
left pulmonary
arteries; bring
blood to right &
left lungs

*
Pulmonary arteries branch extensively inside lungs, become
pulmonary capillaries where gases are exchanged

Oxygenated blood in pulmonary capillaries returns to left
atrium via pulmonary veins, two from each lung
Aorta supplies
entire systemic
circuit with
oxygenated blood

arises from left
ventricle as
ascending
aorta; curves as
aortic arch,
continues down
as thoracic &
abdominal
descending
aorta

*

*
Inside heart chambers (1)
Four chambers in the heart two ventricles & two atria

Ventricles are larger than atria & have much thicker walls;
it makes ventricles much stronger pumps
Right atrium larger
& thinner-walled than
left atrium

Each atrium has
muscular pouch
auricle; right auricle is
much larger than left
auricle

Pectinate muscles
muscular ridges on
anterior side of right
atrium; left atrium
walls are smooth

Inside heart chambers (2)
*
Right ventricle wider; has thinner walls than left ventricle
because of pressure differences in pulmonary & systemic
circuits; right ventricle pumps against slight resistance
Left ventricle pumps against much
greater resistance & has to work harder;
so, it has greater muscle mass ~3 times
thicker than right ventricle
Interventricular septum
thick, muscular wall; separates
ventricles; contracts with the rest
of ventricular muscle

Inside heart chambers (3)
*
Trabeculae carneae inside both ventricles; have ridged
surface made by irregular protrusions of cardiac muscle tissue

Papillary muscles finger-like muscles in each ventricle

Chordae tendineae tendon-like cords that attach papillary
muscles to valves between atria & ventricles
Blood flows through
heart in only one
direction
deoxygenated blood
to pulmonary circuit
& oxygenated blood
to systemic circuit

Two types of valves
prevent blood from
flowing backward

*
The heart valves (1)
Atrioventricular valves tricuspid & bicuspid valves that
prevent movement of blood backward into atria at the time of
ventricle contractions
Tricuspid valve three cusps
between right atrium & right
ventricle

Bicuspid valve two cusps
between left atrium & left ventricle;
also called mitral valve

Chordae tendineae attached to
end of each cusp & to papillary
muscles, which contract before(!)
ventricles begin contraction; create
tension on chordae tendineae
keeping valves closed

*
From mitre to mitral valve
Benedict XVI wearing an
embroidered mitre
Mitre simplex traditional style

*
Backflow of blood from pulmonary artery & aorta to
ventricles is prevented by semilunar pulmonary & aortic
valves

Pulmonary semilunar valve between right ventricle &
pulmonary trunk

Aortic semilunar valve between left ventricle & aorta

Valvular heart diseases impaired function of one or
more valves; usually bicuspid (mitral) & aortic valves

insufficient valve fails to close fully & allows blood to
leak backward regurgitation
The heart valves (2)
stenotic valve
cusps are impregnated
with calcium; hard &
inflexible; blood flows
through stenotic valve
with difficulty

*
Blood flow through the heart: pulmonary circuit

*
Blood flow through the heart: systemic circuit

Aortic arch
Brachiocephalic
trunk
Superior
vena cava
Right
pulmonary
arteries
Ascending aorta
Fossa ovalis
Left common carotid artery
Left subclavian artery
Ligamentum arteriosum
Pulmonary trunk
Pulmonary valve
Left pulmonary
arteries
Left pulmonary
veins
Left
atrium
Interatrial septum
Aortic valve
Cusp of left AV
(mitral) valve
Left ventricle
Interventricular
septum
Opening of
coronary sinus
Right atrium
Pectinate muscles
Conus arteriosus
Cusp of right AV
(tricuspid) valve
Chordae tendineae
Trabeculae
carneae
Moderator band
Descending aorta
Papillary muscles
Right ventricle
Inferior vena cava
Diagrammatic frontal section of the heart,
showing major landmarks & path of blood flow
(arrows) through atria, ventricles & associated vessels.
*
almost all about heart anatomy

a

*

*
recognize blood vessels and heart structures

*
name pointed heart structures &
great blood vessels

*
The origin of coronary circulation
High blood pressure & elastic
rebound of ascending aorta
force blood through coronary
arteries between contractions
of left ventricle

In coronary circulation cardiac
veins collect deoxygenated blood

Most cardiac veins bring blood
to coronary sinus that opens
into right atrium
Coronary circulation blood vessels that supply the heart

Right & left coronary arteries (very first branches of aorta!!)
emerge from aortic sinuses sacs in the base of ascending
aorta; they prevent cusps from sticking to walls of aorta

*
Coronary arteries (1)
Right coronary artery

supplies blood to right atrium; portions of both
ventricles; cells of sinoatrial & atrioventricular nodes

gives rise to marginal artery & posterior inter-
ventricular artery

*
Left coronary artery

supplies blood to left ventricle; left atrium; inter-

ventricular septum

gives rise to circumflex & anterior interventricular

arteries

when blood flow to myocardium is insufficient, coronary

arteries grow arterial anastomoses (brunches that connect
them), forming collateral circulation
Coronary arteries (2)

*
Most cardiac
veins empty into
large venous
structure on
posterior heart wall
coronary sinus,
which drains into
right atrium

Right atrium
final destination
for blood coming
from coronary
circulation
Cardiac veins

*
Partial blockage of coronary circulation by fatty deposit
(atherosclerotic plaque) or thrombus reduces blood supply to
cardiac muscle & results in myocardial ischemia or
coronary artery disease (CAD)

Major symptom chest pain = angina pectoris

When part of coronary circulation is completely blocked,
cardiac muscle cells die from the lack of oxygen & form
nonfunctional area of myocardial infarction MI

Diagnosis heart attack
Coronary artery disease & myocardial infarction
Normal artery
Narrowed artery

*
Symptoms chest pain that radiates to left arm or left side of neck, shortness of breath, sweating, anxiety, nausea & vomiting

Risk factors for CAD & MI smoking, high blood pressure, poorly controlled diabetes, high levels of lipids in blood, obesity, age over 40 for males & over 50 for females, genetics

Survival depends on extent & location of damage; cardiac
muscle cells do not divide & dead cells are replaced with noncontractile scar tissue

Lethality 25% of MI patients die before obtain medical help;
65% of dea