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Electrocardiography

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Title: Electrocardiography


1
Electrocardiography
  • A recording of the electrical activity of the
    heart over time
  • Gold standard for diagnosis of cardiac
    arrhythmias
  • Helps detect electrolyte disturbances (hyper-
    hypokalemia)
  • Allows for detection of conduction abnormalities
  • Screening tool for ischemic heart disease during
    stress tests
  • Helpful with non-cardiac diseases (e.g.
    pulmonary embolism or hypothermia

2
Electrocardiogram (ECG/EKG)
  • Is a recording of electrical activity of heart
    conducted thru ions in body to surface

Fig 13.22a
13-60
3
  • ECG Graph Paper
  • Runs at a paper speed of 25 mm/sec
  • Each small block of ECG paper is 1 mm2
  • At a paper speed of 25 mm/s, one small block
    equals 0.04 s
  • Five small blocks make up 1 large block which
    translates into 0.20 s (200 msec)
  • Hence, there are 5 large blocks per second
  • Voltage 1 mm 0.1 mV between each individual
    block vertically

4
Normal conduction pathway
SA node - atrial muscle - AV node - bundle
of His - Left and Right Bundle Branches -
Ventricular muscle
5
  • Recording of the ECG
  • Leads used
  • Limb leads are I, II, II. So called because
    at one time subjects had to literally place arms
    and legs in buckets of salt water.
  • Each of the leads are bipolar i.e., it
    requires two sensors on the skin to make a lead.
  • If one connects a line between two sensors,
    one has a vector.
  • There will be a positive end at one electrode
    and negative at the other.
  • The positioning for leads I, II, and III were
    first given by Einthoven. Form the basis of
    Einthovens triangle.

6
Types of ECG Recordings
  • Bipolar leads record voltage between electrodes
    placed on wrists legs (right leg is ground)
  • Lead I records between right arm left arm
  • Lead II right arm left leg
  • Lead III left arm left leg

Fig 13.23
13-61
7
Fig. 13.22b
8
ECG
  • 3 distinct waves are produced during cardiac
    cycle
  • P wave caused by atrial depolarization
  • QRS complex caused by ventricular depolarization
  • T wave results from ventricular repolarization

Fig 13.24
13-63
9
  • Elements of the ECG
  • P wave Depolarization of both atria
  • Relationship between P and QRS helps distinguish
    various cardiac arrhythmias
  • Shape and duration of P may indicate atrial
    enlargement
  • PR interval from onset of P wave to onset of
    QRS
  • Normal duration 0.12-2.0 sec (120-200 ms) (3-4
    horizontal boxes)
  • Represents atria to ventricular conduction time
    (through His bundle)
  • Prolonged PR interval may indicate a 1st degree
    heart block
  • QRS complex Ventricular depolarization
  • Larger than P wave because of greater muscle
    mass of ventricles
  • Normal duration 0.08-0.12 seconds
  • Its duration, amplitude, and morphology are
    useful in diagnosing cardiac arrhythmias,
    ventricular hypertrophy, MI, electrolyte
    derangement, etc.
  • Q wave greater than 1/3 the height of the R
    wave, greater than 0.04 sec are abnormal and may
    represent MI

10
  • ST segment
  • Connects the QRS complex and T wave
  • Duration of 0.08-0.12 sec (80-120 msec
  • T wave
  • Represents repolarization or recovery of
    ventricles
  • Interval from beginning of QRS to apex of T is
    referred to as the absolute refractory period
  • QT Interval
  • Measured from beginning of QRS to the end of the
    T wave
  • Normal QT is usually about 0.40 sec
  • QT interval varies based on heart rate

11
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12
Fig. 13.24b
13
Fig. 13.24c
14
Fig. 13.24d
15
  • Elements of the ECG
  • P wave
  • Depolarization of both atria
  • Relationship between P and QRS helps distinguish
    various cardiac arrhythmias
  • Shape and duration of P may indicate atrial
    enlargement

16
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17
  • QRS complex
  • Represents ventricular depolarization
  • Larger than P wave because of greater muscle
    mass of ventricles
  • Normal duration 0.08-0.12 seconds
  • Its duration, amplitude, and morphology are
    useful in diagnosing cardiac arrhythmias,
    ventricular hypertrophy, MI, electrolyte
    derangement, etc.
  • Q wave greater than 1/3 the height of the R
    wave, greater than 0.04 sec are abnormal and may
    represent MI

18
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19
  • PR interval
  • From onset of P wave to onset of QRS
  • Normal duration 0.12-2.0 sec (120-200 ms) (3-4
    horizontal boxes)
  • Represents atria to ventricular conduction time
    (through His bundle)
  • Prolonged PR interval may indicate a 1st degree
    heart block

20
Fig. 13.24g
21
  • T wave
  • Represents repolarization or recovery of
    ventricles
  • Interval from beginning of QRS to apex of T is
    referred to as the absolute refractory period

22
  • ST segment
  • Connects the QRS complex and T wave
  • Duration of 0.08-0.12 sec (80-120 msec
  • QT Interval
  • Measured from beginning of QRS to the end of the
    T wave
  • Normal QT is usually about 0.40 sec
  • QT interval varies based on heart rate

23
Ischemic Heart Disease
  • Is most commonly due to atherosclerosis in
    coronary arteries
  • Ischemia occurs when blood supply to tissue is
    deficient
  • Causes increased lactic acid from anaerobic
    metabolism
  • Often accompanied by angina pectoris (chest pain)

Click here to play Myocardial Infarction RealMedia
Movie
13-78
24
Ischemic Heart Disease
  • Detectable by changes in S-T segment of ECG
  • Myocardial infarction (MI) is a heart attack
  • Diagnosed by high levels of creatine phosphate
    (CPK) lactate dehydrogenase (LDH)

Fig 13.34
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25
Arrhythmias Detected on ECG
  • Arrhythmias are abnormal heart rhythms
  • Heart rate 100/min is
    tachycardia

Fig 13.35
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26
Arrhythmias Detected on ECG continued
  • In flutter contraction rates can be 200-300/min
  • In fibrillation contraction of myocardial cells
    is uncoordinated pumping ineffective
  • Ventricular fibrillation is life-threatening
  • Electrical defibrillation resynchronizes heart by
    depolarizing all cells at same time

Fig 13.35
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27
Arrhythmias Detected on ECG continued
  • AV node block occur when node is damaged
  • Firstdegree AV node block is when conduction
    through AV node 0.2 sec
  • Causes long P-R interval
  • Second-degree AV node block is when only 1 out of
    2-4 atrial APs can pass to ventricles
  • Causes P waves with no QRS
  • In third-degree or complete AV node block no
    atrial activity passes to ventricles
  • Ventricles driven slowly by bundle of His or
    Purkinjes

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28
Arrhythmias Detected on ECG continued
  • AV node block occurs when node is damaged
  • Firstdegree AV node block is when conduction
    thru AV node 0.2 sec
  • Causes long P-R interval

Fig 13.36
13-83
29
Arrhythmias Detected on ECG continued
  • Second-degree AV node block is when only 1 out of
    2-4 atrial APs can pass to ventricles
  • Causes P waves with no QRS

Fig 13.36
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30
Arrhythmias Detected on ECG continued
  • In third-degree or complete AV node block, no
    atrial activity passes to ventricles
  • Ventricles are driven slowly by bundle of His or
    Purkinjes

Fig 13.36
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31
  • Representation in culture
  • In TV medical dramas, an isoelectric ECG (no
    cardiac electrical activity, aka, flatline, is
    used as a symbol of death or extreme medical
    peril.
  • Technically, this is known as asystole, a form
    of cardiac arrest, with a partcularly bad
    prognosis.
  • Defibrillation, which can be used to correct
    arrythmias such as ventricular fibrillation and
    pulseless ventricular tachycardia, cannot correct
    asystole.
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