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The Electrical System

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The normal pattern of muscle contraction begins in the upper chambers (atria) ... ECG or EKG (Electrocardiogram) Measure heart rate. Look for arrhythmias ... – PowerPoint PPT presentation

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Title: The Electrical System


1
The Electrical System
2
The Electrical System
  • The pumping of the heart muscle generates a
    pulse, or heartbeat.
  • The normal pattern of muscle contraction begins
    in the upper chambers (atria), which pump blood
    into the lower chambers (ventricles).

3
The Electrical System
  • The ventricles pump blood to the body and lungs.
  • This coordinated action occurs because the heart
    is "wired" to send electrical signals that tell
    the chambers of the heart when to contract.

4
The Electrical System
  • Your heartbeat is able to speed up and slow down
    because it is wired with electrical tissue.
  • Your heart also has built-in "pacemakers" that
    are like electrical outlets.

5
The Electrical System
  • The electrical system of the heart triggers the
    heartbeat.
  • The pacemakers and the wiring that run through
    your heart also coordinate contractions in the
    upper chambers and lower chambers, which makes
    the heartbeat more powerful so it can do its job
    effectively.

6
How is the Heart Wired?
  • We normally have our own pacemakers that tell the
    heart when to beat.
  • The master pacemaker is located in the atrium
    (upper chamber).
  • It acts like a spark plug that fires in a
    regular, rhythmic pattern to regulate the heart's
    rhythm.

7
How is the Heart Wired?
  • This "spark plug" is called the sinoatrial (SA),
    or sinus node.
  • It sends signals to the rest of the heart so the
    muscles will contract.
  • First, the atrium contracts.
  • The electrical signal from the sinus node spreads
    through the atria.

8
How is the Heart Wired?
  • Next, the electrical signal travels to the area
    that connects the atria with the ventricles.
  • This electrical connection is critical.
  • Without it, the signal would never reach the
    ventricles, the major pumping chambers of the
    heart.

9
How is the Heart Wired?
  • The first structure it reaches is another natural
    pacemaker called the atrioventricular (AV node).
  • A structure called the bundle of His emerges from
    the AV node and divides into thin, wire-like
    structures called bundle branches that extend
    into the right and left ventricles.

10
How is the Heart Wired?
  • The electrical signal travels down the bundle
    branches to thin filaments known as Purkinje
    fibers.
  • These fibers distribute the electrical impulse to
    the muscles of the ventricles, causing them to
    contract and pump blood into the arteries.

11
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12
When Your Heart Doesn't Work as It Should
  • The S-A node doesn't produce the right number of
    signals.
  • Another part of the heart takes over as the
    natural pacemaker.
  • The electrical pathways are interrupted.

13
When Your Heart Doesn't Work as It Should
  • Slow Arrhythmias When the heart beats too
    slowly it's called bradycardia (brady slow,
    cardia heart).
  • Slow arrhythmias can be a problem because they
    cause the oxygen- and nutrient-rich blood to
    travel more slowly to your organs and other
    tissues.
  • Your body may not receive enough oxygen and
    nutrients to function properly.

14
When Your Heart Doesn't Work as It Should
  • Fast Arrhythmias When the heart beats too fast
    it's called tachycardia (tachy fast, cardia
    heart).
  • During tachycardia the heart isn't able to pump
    blood to the body as well as it should.
  • Fast rhythms in the upper chambers may not be
    life-threatening in themselves.
  • But they may contribute to other problems that
    are serious.
  • Fast arrhythmias in the lower chambers, the
    ventricles, can be dangerous and even fatal.

15
What Causes These Problems?
  • Heart disease causes changes in the heart tissue.
  • Aging of the heart muscle can also change the
    heart tissue.
  • Physical problems, such as diabetes, smoking, and
    excessive alcohol or drug use, can affect the
    heart tissue.
  • There could be an inherited heart problem.
  • There is evidence of heart failure or a heart
    attack.

16
Tests for the Conduction System
  • ECG or EKG (Electrocardiogram)
  • Measure heart rate
  • Look for arrhythmias
  • Identify enlargement of the heart's chambers
  • Help diagnose whether you've had a heart attack

17
  • The ECG or EKG, directly measures microvoltages
    in the heart muscle (myocardium) occurring over
    specific periods of time in a heartbeat,
    otherwise known as a cardiac impulse.
  • With each heartbeat, electrical currents called
    action potentials, measured in millivolts (mV),
    travel through a conducting system in the heart.

18
  • The potentials originate in a sinoatrial (SA)
    node which lies in the entrance chamber of the
    heart, called the right atrium.
  • These currents also diffuse through tissues
    surrounding the heart whereby they reach the
    skin.
  • There they are picked up by external electrodes
    which are placed at specific positions on the
    skin.

19
  • They are in turn sent through leads to an
    electrocardiograph.
  • A pen records the transduced electrical events
    onto special paper.
  • The paper is ruled into mV against time and it
    provides the reader with a so-called rhythm
    strip.

20
  • This is a non-invasive method to used evaluate
    the electrical counterparts of the myocardial
    activity in any series of heart beats.
  • Careful observation of the records for any
    deviations in the expected times, shapes, and
    voltages of the impulses in the cycles gives the
    observer information that is of significant
    diagnostic value, especially for human medicine.

21
  • The normal rhythm is called a sinus rhythm if the
    potentials begin in the sinoatrial (SA) node.

22
  • A cardiac cycle has a phase of activity called
    systole followed by a resting phase called
    diastole.
  • In systole, the muscle cell membranes, each
    called a sarcolemma, allow charged sodium
    particles to enter the cells while charged
    potassium particles exit.

23
  • These processes of membrane transfer in systole
    are defined as polarization.
  • Electrical signals are generated and this is the
    phase of excitability.
  • The currents travel immediately to all cardiac
    cells through the mediation of end-to-end
    high-conduction connectors termed intercalated
    disks.

24
  • The potentials last for 200 to 300 milliseconds.
  • In the subsequent diastolic phase, repolarization
    occurs.
  • This is a period of oxidative restoration of
    energy sources needed to drive the processes.
  • Sodium is actively pumped out of the fiber while
    potassium diffuses in.
  • Calcium, which is needed to energize the force of
    the heart, is transported back to canals called
    endoplasmic reticula in the cell cytoplasm.

25
  • The action potentials travel from the superior
    part of the heart called the base to the inferior
    part called the apex.
  • In the human four-chambered heart, a pacemaker,
    the SA node, is the first cardiac area to be
    excited because sodium and potassium interchange
    and energize both right and left atria.

26
  • The impulses then pass downward to an
    atrioventricular (AV) node in the lower right
    atrium where their velocity is slowed, whereupon
    they are transmitted to a conducting system
    called the bundle of His.
  • The bundle contains Purkinje fibers that transmit
    the impulses to the outer aspects of the right
    and left ventricular myocardium.

27
  • In turn, they travel into the entire ventricular
    muscles by a slow process of diffusion.
  • Repolarization of the myocardial cells takes
    place in a reverse direction to that of
    depolarization, but does not utilize the bundle
    of His.

28
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29
Cardiac Cycle
  • The events that occur from the beginning of one
    heartbeat to the beginning of the next.
  • Consists of ventricular diastole (relxation) and
    ventricular systole (contraction)

30
Diastole
  • During diastole, blood flows from the atria
    through the open tricuspid and mitral valves into
    the relaxed ventricles.
  • The aortic and pulmonic valves are closed.
  • 75 of blood flow is passive

31
Systole
  • During ventricular systole the mitral and
    tricuspid valves are closed.
  • The relaxed atria fill with blood. A ventricular
    pressure rises, the aortic and pulmonic valves
    open.
  • The ventricle contract, and blood is ejected into
    the pulmonic and systemic circulation.

32
Cardiac Output
  • Is the amount of blood the left ventricle pumps
    into the aorta per minute.
  • Is measured by multiplying heart rate times
    stroke volume.
  • Stroke volume refers to the amount of blood
    ejected with each ventricular contraction and is
    usually about 70 mls.

33
Cardiac Output
  • Normal CO is 4 to 8 L/min.
  • The heart pumps only as much blood as the body
    requires, based on metabolic requirements.

34
Cardiac Output
  • Three factors determines stroke volume
  • Preload
  • Afterload
  • Myocardial contractility.

35
Preload
  • Is the degree of stretch or tension on the muscle
    fibers when they begin to contract..
  • Its usually considered to be the end-diastolic
    pressure when the ventricl has filled

36
Afterload
  • Is the load (or amount of pressure) the left
    ventricle must work against to eject blood during
    systole.
  • It corresponds to systolic pressure.
  • The greater this resistance is, the greater the
    hearts workload.

37
Myocardial contractility
  • Is the ventricles ability to contract, which is
    determined by the degree of muscle fiber stretch
    at the end of diastoe.
  • The more the muscle fibers stretch during
    ventricular filling, up to an optimal length, the
    more forecful the contration.

38
Autonomic innervations of the heart
  • Two branches of the autonomic nervous system
    supply the heart.
  • Sympathetic nervous system
  • Parasympathetic nervous system

39
Sympathetic
  • Innervate all the areas of the heart
  • Nerve stiulation causes the release of
    norepinephrine, which increases the heart rate by
    increasing SA node discharge, accelerates AV noe
    conduction time, and increases the force of
    myocardial contraction and cardiac output.

40
Parasympathetic
  • Vagal stimulation causes the release of
    acetylcholine, which produces the opposite
    effects.
  • The rate of SA node dischare is decrease, thus
    slowing hear rate and conduction through the AV
    node and reducing cardiac output.

41
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42
Depolarization and Repolarization
  • As impulses are transmitted, cardiac cells
    undergo cycles of depolarization and
    repolarization.
  • Cardiac cells at rest are considered polarized,
    meaning that no electrical activity takes place.

43
  • Cell membranes separate different concentrations
    of ion, such as sodium and potassium and create a
    more negative charge inside the cell.
  • This is called resting potential
  • After a stimulus occurs, ions cross the cell
    membrane and cause an action potential or cell
    depolarization.
  • When a cells fully depolarized it attempts to
    return to its resting state in a process called
    repolarization.
  • Electrical charges in the cell reverse and return
    to normal.

44
Electrical Activity
  • Of the heart is represented on an ECG.
  • ECG represent only electrical activity not the
    mechanical activity or actual pumping of the
    heart.

45
How to Read an EKG Strip
  • EKG paper is a grid where time is measured along
    the horizontal axis.
  • Each small square is 1 mm in length and
    represents 0.04 seconds.
  • Each larger square is 5 mm in length and
    represents 0.2 seconds.

46
How to Read an EKG Strip
  • Voltage is measured along the vertical axis.
  • 10 mm is equal to 1mV in voltage.
  • The diagram on the next slide illustrates the
    configuration of EKG graph paper and where to
    measure the components of the EKG wave form

47
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48
Heart rate can be easily calculated from the EKG
strip
  • When the rhythm is regular, the heart rate is 300
    divided by the number of large squares between
    the QRS complexes.
  • For example, if there are 4 large squares between
    regular QRS complexes, the heart rate is 75
    (300/475).

49
Heart rate can be easily calculated from the EKG
strip
  • The second method can be used with an irregular
    rhythm to estimate the rate. Count the number of
    R waves in a 6 second strip and multiply by 10.
  • For example, if there are 7 R waves in a 6 second
    strip, the heart rate is 70 (7x1070).

50
P wave
  •   Indicates atrial depolarization, or
    contraction of the atrium.
  • Location precedes the QRS complex
  • Amplitude (height) is no more than 3 mm
  • Duration 0.06 to 0.12 seconds
  • Usually rounded and smooth

51
PR Interval
  • Tracks the atrial impulse from the atria through
    the AV node, bundle of His and right and left
    bundle branches.
  • Location from the beginning of the P wave to the
    beginning of the QRS complex.
  • Duration 0.12 seconds to 0.20 seconds
  • Short intervals indicate that the impulse
    originated somewhere other than the SA node.

52
QRS complex
  • Indicates ventricular depolarization, or
    contraction of the ventricles.
  • Location follows the PR interval
  • Amplitude 5 to 30 mm high, but differs with each
    lead used.
  • Duration 0.06 to 0.10 seconds or half of the PR
    interval measured from the beginning of the Q
    wave to the end of the S wave
  • R waves are deflected positively and the Q and S
    waves are negative

53
ST Segment
  • Represents the end of ventricular conduction or
    depolarization and the beginning of ventricular
    recover or repolariztion.
  • Location extends from the S wave to the
    beginning of the T wave.
  • Deflection usually on the baseline may vary from
    -0.5 to 1.0 mm.
  • A change in the ST segment may indicate
    myocardial injury or ischemia.

54
T wave
  • Indicates ventricular repolarization
  • Location follows the ST segment
  • Amplitude 0.5 mm in standard leads and 10 mm in
    precordial leads
  • Rounded and smooth

55
ST segment
  • Represents the end of ventricular conduction or
    depolarization and the beginning of ventricular
    recovery or repolariztion.
  • Normally not depressed more than 0.5 mm

56
QT interval
  • Indicates repolarization time
  • Location extends from the beginning of the QRS
    complex to the end of the T wave
  • General rule duration is less than half the
    preceding R-R interval.
  • Duration varies according to age, gender and
    heart rate. From 0.36 to 0.44 seconds

57
Paper and Pencil method of measuring Rhythm
  • Place the ECG strip on a flat surface.
  • Position the straight edge of a piece of paper
    along the strips baseline.
  • Move the paper up slightly so that the straight
    edge is near the peak of the R wave.
  • Mark the paper at the R waves of 2 consecutive
    QRS complexes. This distance is the R-R interval.

58
  • Move the paper across the strip lining up the two
    marks with succeeding R-R intervals. If the
    distance for each R-R interval is the same, the
    ventricular rhythm is REGULAR.
  • If the distances varies the RHYTHIM ins
    irregular.
  • The same can be done using the distance between
    the P waves to determine atrial rhythm

59
  • Building 1 suite313
  • Dr. Sneider
  • Dec 2nd at 215

60
  • http//usasam.amedd.army.mil/_fm_course/Study/Unde
    rstandingECG.pdf
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