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EKG
Plain and Simple
Third Edition
CHAPTER
2
Electrophysiology
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
All rights reserved.
Media Directory
Slide 31
Inherent Rates Animation
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
All rights reserved.
Depolarization
• Change in the cardiac cell’s electrical
charge from negative to positive
• Accomplished by sodium and potassium
ions changing place
• Causes a wave of electrical charge to
course from cell to cell, resulting in a
discharge of electricity
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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Repolarization
• Return of the cardiac cell to its electrically
negative charge
• Accomplished by way of the sodiumpotassium pump, an active transport
system
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
All rights reserved.
Figure 2-1 Depolarization and Repolarization
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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Electrical vs. Mechanical
• Depolarization and repolarization —
myocardium’s electrical stimuli
• Contraction and relaxation — mechanical
response to that stimuli
• Depolarization should result in heart
muscle contraction
• Repolarization should result in relaxation
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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Electrical vs. Mechanical
• Electrical stimulus precedes mechanical
response
• There will be NO HEART BEAT without
first having had depolarization
• But electrical stimulus does not guarantee
mechanical response
• There could be a mechanical problem
making the myocardium incapable of
pumping
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
All rights reserved.
Action Potential
•
•
•
•
•
Phase 4: Cardiac cell at rest
Phase 0: Depolarization
Phases 1 & 2: Early repolarization
Phase 2: Plateau phase
Phase 3: Rapid repolarization
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
All rights reserved.
Figure 2-2 Action Potential
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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Refractory Periods
• Absolute: No stimulus can cause
depolarization
• Relative: Strong stimulus can cause
depolarization
• Supernormal period: Even a weak
stimulus can cause depolarization
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
All rights reserved.
Figure 2-3 Refractory Periods
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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EKG Waves and Complexes
• P wave: Atrial depolarization
• Ta wave: Atrial repolarization. Not usually
seen, as it occurs simultaneous with QRS
• QRS complex: Ventricular depolarization
• T wave: Ventricular repolarization
• U wave: Late ventricular repolarization.
Not usually seen
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
All rights reserved.
Figure 2-4 EKG Waves and Complexes
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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EKG Waves and Complexes
• Each P-QRS-T sequence is one heart
beat
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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Segments
• PR segment: Flat line between P wave
and QRS complex
• ST segment: Flat line between QRS
complex and T wave
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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Baseline
• The flat line between the T wave of one
beat and the P wave of the next beat
• Also called isoelectric line
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
All rights reserved.
Waves and Complexes
Identification Practice 1
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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Waves and Complexes
Identification Practice 2
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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Waves and Complexes
Identification Practice 3
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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Waves and Complexes
Identification Practice 4
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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Waves and Complexes
Identification Practice 5
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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QRS Nomenclature
• Q wave: Downward wave preceding an
upward wave
• R wave: Any upward wave
• S wave: Downward wave following an R
wave
• QS wave: Downward wave with no upward
wave at all
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
All rights reserved.
Figure 2-5 Examples of QRS Complexes
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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QRS Nomenclature Practice
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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Cardiac Conduction System
• Pathway of specialized cells that create
and conduct electrical impulses
EKG Plain and Simple, Third Edition
Karen M. Ellis
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Figure 2-6 Cardiac Conduction System
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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Conduction Pathway
• Sinus node interatrial tracts atrium
internodal tracts AV node bundle of
His bundle branches Purkinje fibers
ventricle
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
All rights reserved.
Characteristics of Cardiac Cells
• Automaticity: Ability to create an impulse
without outside stimulation
• Conductivity: Ability to conduct an impulse
to neighboring cells
• Excitability: Ability to depolarize
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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Characteristics of Cardiac Cells
• Contractility: Ability to contract
• Automaticity, conductivity, and excitability
are electrical characteristics. Contractility is
mechanical
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
All rights reserved.
Pacemaker Cells
• Pacemaker: Area of the conduction
system that initiates the electrical impulses
– Sinus node: Heart’s normal pacemaker.
Inherent rate 60–100 beats per minute
– AV junction: Backup pacemaker. Inherent rate
40–60 beats per minute
– Ventricle: A lower backup pacemaker.
Inherent rate 20–40 beats per minute
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
All rights reserved.
Inherent Rates Animation
Click on the screenshot to view an animation showing inherent rates.
Click again to pause the animation.
EKG Plain and Simple, Third Edition
Karen M. Ellis
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Figure 2-7 Normal Conduction
EKG Plain and Simple, Third Edition
Karen M. Ellis
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Figure 2-8 Sinus Fails, AV Junction Escapes
EKG Plain and Simple, Third Edition
Karen M. Ellis
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Figure 2-9 All Higher Pacemakers Fail, Ventricle Escapes
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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Figure 2-10 Block in Conduction, AV Junction Escapes
EKG Plain and Simple, Third Edition
Karen M. Ellis
Copyright ©2012 by Pearson Education, Inc.
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