Heart Part 2
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Transcript Heart Part 2
HEART
Part 2
A&P
Instructor Terry Wiseth
HEART CONDUCTION
Throughout the heart are clumps of
specialized cardiac muscle tissue whose
fibers contain only a few myofibrils
Initiate and distribute cardiac impulses
throughout the myocardium
2
HEART CONDUCTION
intrinsic ability to
generate and
conduct nerve
impulses
conducts impulse for
proper contraction
sequence of heart
3
HEART CONDUCTION
intrinsic ability to generate and conduct
nerve impulses
conducts impulse for proper contraction
sequence of heart
4
HEART CONDUCTION
intrinsic ability to generate and conduct
nerve impulses
conducts impulse for proper contraction
sequence of heart
5
SINOATRIAL NODE
Cell area located on the posterior part of
the right atrial wall, adjacent to the
junction of the superior vena cava and the
right atrium
“Pacemaker”
signals atria to contract
6
SINOATRIAL NODE
depolarization of the SA node is the first
step of the cardiac cycle
does not produce enough energy to be
recorded by the EEG
cells in the SA node
transmit impulses six
times faster than do
ordinary cell-to-cell
interconnections
7
SINOATRIAL NODE
The SA node sets the heart rate at 95
beats per minute
60 beats per minute is intrinsic to the
atria alone
20 - 40 beats per minute
is intrinsic to the
ventricles alone
8
HEART CONDUCTION
SINOATRIAL NODE
Acetycholine released by parasympathetic
system of ANS slows SA node to 72 beats
per minute
Other hormones affect heart rate by
influencing SA node
10
ECTOPIC PACEMAKER
Site other than SA node
develops an abnormal
self-excitability
Produces extra beats
Irregularly pace the
heart for short periods
of time
Nicotine and caffeine
can trigger these events
11
ATRIOVENTRICULAR NODE
made up of another cluster of specialized
cardiac conduction system cells
forms a pathway for impulse conduction
that bridges between the atria and
ventricles
delays impulse for atria to
finish contraction
12
HEART CONDUCTION
ATRIOVENTRICULAR NODE
Depolarization of the AV node is relatively
slow due to the intrinsic characteristics of
its cells
This causes a delay in the transmission of
the depolarization wave to the ventricles
transmission of the wave through the AV
node is relatively weak
considered silent on the
electrocardiogram
14
ATRIOVENTRICULAR NODE
damaged AV node
ventricles contract intrinsically slower
may require an artificial pacemaker
15
BUNDLE OF HIS
a compact tract of cardiac conduction
system fibers
also called the AV bundle
route for signals to leave the AV node
16
BUNDLE OF HIS
tract down the interventricular septum
The right and left branches spread the
electrical impulse to the right and left
ventricles
17
PURKINJE FIBERS
conduction system fibers which form a
rapid conduction network within the
myocardium
located at the ends of the bundle branches
18
PURKINJE FIBERS
responsible for propagating the
depolarization wave to all cardiac muscle
cells
The QRS Complex of the
electrocardiogram represents the
ventricular depolarization of contraction
19
HEART CONDUCTION
CONDUCTION
SA node
AV node
bundle of His
Purkinje fibers
CONDUCTION
Contraction begins at the heart apex and
progresses upwards
milking action of ventricular contraction
and the spiral arrangement of the
ventricular muscle fibers twist and wring
out the blood
22
HEART CONDUCTION
CONTROL OF CONTRACTION
brain is able to affect heart rate via
1) parasympathetic nerve impulses
heart-slowing
2) sympathetic nerve impulses
increase heart rate
24
CONTROL OF CONTRACTION
Click to View
Baroreceptor
control of
heart rate
CARDIAC RHYTHM
normal resting
70-80 beats/min
Systole
Contraction
Diastole
Expansion
26
VENTRICULAR DIASTOLE
during ventricular diastole cusps hang
loosely into ventricular chamber
27
VENTRICULAR SYSTOLE
during (at start of ) ventricular systole the
resulting increased blood pressure
developing in the ventricle forces the
flaps up together shutting the AV valves
28
VENTRICULAR SYSTOLE
semilunar valves forced open
29
VENTRICULAR DIASTOLE
semilunar valves
closed from back
flow pressure of
aortic and
pulmonary trunks
30
HEART SOUNDS
Lubb - dupp sounds are due to vibrations
in the heart tissues
created as the blood flow is suddenly
increased or slowed with the
contraction and relaxation of the heart
chambers
created with the opening and closing of
the valves
31
HEART SOUNDS
closing of valves causes vibrations in
heart wall
“lubb-dupp” sound of heartbeat
“lubb” S1
lower, louder
closing of AV valves
start of ventricular systole
“dupp” S2
softer, sharper
closing of semilunar valves
end of ventricular systole
32
ELECTROCARDIGRAM
Comprehensive image of the hearts
electrical activity
supplies a composite recording of all
action potentials produced by nodal and
muscle cells
three principle deflections
P wave
QRS complex
T wave
33
EKG COMPONENTS
EKG COMPONENTS
P WAVE
Signal from the SA node spreads through
the atria
atrial systole
36
QRS COMPLEX
Firing of SA node
ventricular systole
37
S-T SEGMENT
Following ventricular contraction and the
QRS complex is a brief period of low
electrical activity
On the electrocardiogram this appears
as the S-T segment
38
T WAVE
Ventricular repolarization is represented
by the T-wave on the electrocardiogram
The T-wave deflection is also in the same
direction of the largest deflection of the
QRS complex
39
EKG SUMMARY
depolarization
repolarization
READING EKG
Important to note the size of the deflection
waves at certain time intervals
41
ENLARGEMENT OF P-WAVE
Indicates
enlargement of the atria
atrial stenosis
mitral valve narrows
blood backs into the left atrium and
there is an expansion of the atrial wall
42
LENGTHENED P-R INTERVAL
Occurs because the heart tissue, covered
by the P-Q interval, namely the atria and AV node is scarred or inflamed
Impulse, as a result, travels at a slower rate
and the interval is lengthened
Atherosclerotic disease
Rheumatic fever
43
ENLARGED Q-WAVES AND R-WAVES
Enlarged R wave generally indicates
enlarged ventricles
Enlarged Q-wave may indicate a
myocardial infarction
44
S-T SEGMENT
Elevated S-T segment
acute myocardial infarction
Depressed S-T segment
heart muscle receives insufficient
oxygen
45
T-WAVE
Flat when the heart muscle is receiving
insufficient oxygen
May be elevated during hyperkalemia
High levels of potassium in bloodstream
46
CARDIAC CYCLE
1) Ventricular filling
2) Atrial systole
3) Isovolumetric ventricular contraction
4) Rapid ventricular ejection
5) Isovolumetric ventricular relaxation
47
1) VENTRICULAR FILLING
AV valves open due to low ventricular
pressure
blood passively enters the ventricles
P wave starts
48
2) ATRIAL SYSTOLE
SA node fires
contraction of the atrium stops the
pulmonary venous and systemic inflow
atrial contraction completes the filling of
the ventricles
pressure in the ventricles
increases closing the
AV valves
phase is indicated by the
P wave
49
3) ISOVOLUMETRIC CONTRACTION
ventricular contraction causes the
pressure to rise in the ventricles
AV valves close
blood is not ejected from the ventricles
atria relax
heart sound S1
phase is indicated
by the QRS complex
50
4) VENTRICULAR EJECTION
the pressure in the ventricles exceed the
pulmonary and systemic pressures
causing the semilunar valves to open
ventricle continues to contract rapidly
ejecting blood to the aorta
and pulmonary trunk
51
4) VENTRICULAR EJECTION
Ventricle contains 130 ml blood
EDV (End Diastolic Volume)
ventricles eject 54% (ejection fraction) of
the EDV during contraction
blood remaining behind is called ESV
(End Systolic Volume)
during rigorous exercise 90% may be
ejected
ejection fraction is an important measure
of cardiac health
52
5) ISOVOLUMETRIC RELAXATION
Ventricles expand causing pressure to
drop
semilunar valves close as the ventricular
pressure falls below the systemic and
pulmonary diastolic level
53
5) ISOVOLUMETRIC RELAXATION
ventricular pressures continue to fall until
it is slightly below atrial pressure
AV valves open
blood begins to fill the ventricles
phase is indicated
by the T wave
heart sound S2
54
CARDIAC CYCLE
VOLUME CHANGES
Ventricles pump as much blood as they
receive
both ventricles eject the same volume of
blood
ESV (leftover) 60 ml
atrial diastole +30 ml
atrial systole +40 ml
total EDV
130 ml
stroke volume -70 ml
ESV
60 ml
56
VOLUME CHANGES
If RV pumped more than LV could handle
on return
causes hypertension and edema in the
lungs
fluid swells the lungs
impairing gas
exchange
57
VOLUME CHANGES
If LV pumped more blood than RV can
handle on return
results in hypertension and edema in
the body
can lead to aneurysms,
stroke, kidney failure,
heart failure
58
CONGESTIVE HEART FAILURE
Failure of either ventricle to eject blood
effectively
can be caused by:
1) myocardial infarcted weakened heart
muscle
2) chronic hypertension
3) valvular insufficiency
4) congenital defects
59
CONGESTIVE HEART FAILURE
Left ventricle failure
pulmonary edema
shortness of breath
sense of suffocation
Right ventricle failure
systemic edema
enlargement of liver
swelling of fingers, ankles, feet
60
CONGESTIVE HEART FAILURE
Left ventricle failure
pulmonary edema
shortness of breath
sense of suffocation
Right ventricle failure
systemic edema
enlargement of liver
swelling of fingers, ankles, feet
61
CARDIAC OUTPUT
volume pumped by each ventricle per
minute
CO = Heart Rate (HR) X Stroke Volume (SV)
HR = 75 bpm
SV = 70 ml/beat
CO = 75 X 70 = 5,250 ml/min = 5.25 L/min
total volume of blood is 4-6 L
thus entire volume of body’s blood is
pumped through each minute
vigorous exercise increases CO up to 21
L/min
62
CARDIAC OUTPUT
Cardiac output and peripheral resistance
determine blood pressure
Healthy young adult
120 mm Hg/ 80 mm Hg
63
HEART RATE
Normal
72 bpm
Tachycardia
rate above 100 bpm
stress, anxiety, drugs, disease, elevated
body temperature
Bradycardia
HR below 60 bpm
sleep, well trained
athlete, low body temperature
64
STROKE VOLUME
Governed by three factors
1) pre-load
2) contractility
3) after-load
65
PRE-LOAD
Determined by volume of blood in
ventricles
stretched myocardial muscle is able to
contract more forcefully
thus expel more blood
and increasing CO
66
CONTRACTILITY
Refers to the strength of contraction for a
given pre-load
measures myocyte receptivity to
stimulation
solutions of glucagon and calcium
chloride are standard emergency
treatment for heart attacks
digitalis acts as a cardiac stimulant to
treat congestive heart failure
barbiturates are negative
agents which reduce myocyte
response to stimulation
67
AFTER-LOAD
Blood pressure in arteries outside the
semilunar valve
opposes the opening of semilunar valves
increased after-load reduces the stroke
volume
68
AFTER-LOAD
arterial circulation impediments increase afterload
scar tissue (lung diseases)
emphysema, chronic bronchitis
cor pulmonale
RV failure due to obstructed pulmonary
circulation
Emphysema
69
HEART ABORMALITIES
Cardiomyopathy
The myocardium
functions poorly and
the heart is large and
dilated
MYOCARDIAL INFARCTION
71
MYOCARDIAL INFARCTION
MI ,“heart attack”
Within the lumen of the
coronary can be seen a dark
red recent coronary
thrombosis
The dull red color to the
myocardium to the lower
right of the thrombus is
consistent with underlying
myocardial infarction
72
MYOCARDIAL INFARCTION
left ventricular wall
sectioned lengthwise to
reveal a recent
myocardial infarction
The center of the
infarct contains
necrotic muscle that
appears yellow-tan
Remaining viable
myocardium is reddishbrown
73
MYOCARDIAL INFARCTION
Myocardial infarction necrotic tissue
74
MYOCARDIAL INFARCTION
histological acute myocardial infarction
contraction band necrosis
myocardial fibers are beginning to lose
cross striations
nuclei are not
clearly visible
many irregular
darker pink wavy
contraction bands
extending across
the fibers
75
ATRIAL FLUTTER
Cells in the atria set off extra
contractions
the atria beats 400-500 beats per minute
early firing can cause premature
ventricular contractions (PVCs)
often due to irritation of the heart by
stimulants, emotional stress, or lack of
sleep
can lead to ventricular fibrillation
76
VENTRICULAR FIBRILLATION
An arrhythmia caused by electrical
signals arriving at different regions of the
myocardium at widely different times
squirming, uncoordinated contractions
“bag of worms”
no pumping of blood
ischemia rapidly follows
77
CARDIAC ARREST
A cessation of cardiac output
ventricles may be motionless or in
fibrillation
78
DEFIBRILLATION
Heart is given a strong electric shock with
a pair of electrodes
79
DEFIBRILLATION
Depolarizes the entire myocardium and
stops the fibrillation
hope that the SA node will resume in
sinus rhythm
Atrial fibrillation
Normal sinus rhythm
Defibrillation
shocks
80
PACEMAKER
A pacing system stimulates the heart
muscle with precisely timed discharges of
electricity
cause the heart to beat in a manner very
similar to a naturally occurring heart
rhythm
81
PACEMAKER
The pacemaker sends tiny
electrical impulses to start a heartbeat
The electrode is designed to relay
information (sense) about your heart's
own electrical activity to
the pacemaker and to
deliver electrical
impulses (paces) only
when the heart needs
them
82
PACEMAKER
DYNAMIC CARDIOMYOPLASTY
involves harvesting the the Latissimus
Dorsi
the muscle is wrapped around the surface
of the heart
the nerve to the muscle is stimulated
(with a specialized pacemaker device)
allowing the muscle to contract
improves the ejection of blood from the
heart
lessens the symptoms of heart failure
84
DYNAMIC CARDIOMYOPLASTY
DYNAMIC CARDIOMYOPLASTY
HYPERTENSION
The left ventricle is markedly thickened in
this patient with severe hypertension that
was untreated for many years
hypertension creates a greater pressure
load on the heart to induce the
hypertrophy
87
AORTIC TEAR
a sudden deceleration injury in a
vehicular accident can produce a tear in
the aorta
tear is just distal to the great vessels
the tear leads to sudden loss of blood and
shock
It is widely
believed that
Princess
Diana died
from an
aortic tear
brought on by
a sudden
deceleration
88
AORTIC TEAR
AORTIC TEAR
BACTERIAL INFECTION
Endocarditis
blue bacterial colonies on the lower left
extending into the pink connective
tissue of the valve
valves are relatively avascular
high dose antibiotic therapy is needed
to eradicate
the infection
91
BACTERIAL INFECTION
patient with infective endocarditis and
blood culture positive for Staphylococcus
aureus
small linear subungual splinter
hemorrhage
92
HEART TUMOR
heart of a two year old child who died
suddenly
at autopsy, a large firm, white tumor mass
was found filling much of the left ventricle
tumors of the
heart are rare
93
HEART TUMOR
PULMONARY
THROMBOEMBOLUS
Blood clots formed
elsewhere in the body
can dislodge and move
through the larger blood
vessels and heart and
become lodged in the
smaller pulmonary circuit
blood vessels causing a
blockage or bursting of
the blood vessel
HEART LUNG MACHINE
HEART LUNG MACHINE
FEET
BLUE
BLOOD TO
PUMP
RED
BLOOD TO
BODY
HEAD
ATRIAL SEPTAL DEFECT
A defect involving both the atrial and the
ventricular septums allows blood to pass
freely between the two ventricles and the
atriums
98
ATRIAL SEPTAL DEFECT
The valve apparatus at the junction
between atriums and ventricles is
"shared"
effectively only one valve instead of the
normal two
Blood flow and
pressure in the
lung circulation
is substantially
increased
99
ATRIAL SEPTAL DEFECT
often results in early onset of symptoms
with:
breathlessness
poor feeding
slow weight gain
defect is very
common in babies
with Down syndrome
100
VENTRICULAR SEPTAL DEFECT
FOSSA OVALIS
depression in interatrial septum
opening which exists in fetal heart
foramen ovale
RA
RV
102
HEART CHANGES AT BIRTH
At birth, the first breath inflates
the lungs
lowers the resistance to
blood flow
thus increases the volume of
blood flowing through them
thereby increasing the
amount of blood returning
from the pulmonary trunk to
the heart
all of which results in
increased pressure in the left
atrium
103
FETAL CIRCULATION
FETAL CIRCULATION
HEART CHANGES AT BIRTH
increased pressure in the left atrium
forces the flap covering the foramen
ovale against the interatrial septum
blocking off
communication
between the right
and left atrium
106
HEART CHANGES AT BIRTH
closure of the ductus arteriosus
takes place almost
immediately after birth
due to muscular contraction
mediated by, bradykinin
released from the lungs
after the newborn's first
breath
107
HEART CHANGES AT BIRTH
In some instances, the ductus arteriosus
does not obliterate within the first few
days leaving a left to right shunt
108
HEART CHANGES AT BIRTH
There are two shortcuts; normally, both of
them close up at birth or shortly
thereafter
ductus arteriosus
a small blood vessel
connecting the
pulmonary artery
and aorta
foramen ovale
a small hole
between the left
and right atria
109
DUCTUS ARTERIOSUS
BEFORE AND AFTER
HEART CHANGES AT BIRTH
Openings and blood vessels close at birth
and if they do not two conditions may
result:
Patent Ductus Arteriosus (PDA)
Patent Foramen Ovale (PFO)
111
PATENT DUCTUS ARTERIOSUS
HEART CHANGES AT BIRTH
Either of these conditions can cause
fatigue
difficult or rapid breathing
failure to grow normally
chronic respiratory
infections
Large openings can lead
to heart failure and death
113
DUCTUS ARTERIOSUS REPAIR
END
HEART
Part 2