Copyright © 2008 Thomson Delmar Learning CHAPTER 12 Electrophysiology of the Heart.

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Presentation transcript:

Copyright © 2008 Thomson Delmar Learning CHAPTER 12 Electrophysiology of the Heart

Copyright © 2008 Thomson Delmar Learning Action Potentials Polarized or resting state Resting membrane potential (RMP)

Copyright © 2008 Thomson Delmar Learning Polarized State Fig The polarized state. For each Na + ion that diffuses into the cell, about 75 K + ions diffuse out of the cell. The result is a deficiency of positive cations inside the cell; this is a cell with a negative charge.

Copyright © 2008 Thomson Delmar Learning THE FIVE PHASES OF THE ACTION POTENTIAL

Copyright © 2008 Thomson Delmar Learning Depolarization: Trigger for Myocardial Contraction Phase 0: Rapid depolarization –Early phase

Copyright © 2008 Thomson Delmar Learning Action Potentials Fig The action potential and the Na +, K +, and Ca ++ changes during phases 0, 1, 2, 3, and 4.

Copyright © 2008 Thomson Delmar Learning Repolarization: Process of heart cells returning to their resting state –Phase 1: Initial repolarization –Phase 2: Plateau state –Phase 3: Final rapid repolarization –Phase 4: Resting or polarized state

Copyright © 2008 Thomson Delmar Learning Properties of the Cardiac Muscle Composed of Two Cardiac Cells Contractile muscle fibers Autorhythmic cells

Copyright © 2008 Thomson Delmar Learning Four Specific Properties Automaticity Excitability Conductivity Contractility

Copyright © 2008 Thomson Delmar Learning Four Specific Properties Automaticity –Unique ability of the cells in the SA node (pacemaker cells) to generate an action potential without being stimulated.

Copyright © 2008 Thomson Delmar Learning Action Potential of Pacemaker and Nonpacemaker Myocardial Cells Fig Schematic representation comparing action potential of pacemaker and nonpacemaker (working) myocardial cells.

Copyright © 2008 Thomson Delmar Learning Four Specific Properties Excitability (irritability) –Ability of a cell to reach its threshold potential and respond to a stimulus or irritation

Copyright © 2008 Thomson Delmar Learning Four Specific Properties Conductivity –Ability of the heart cells to transmit electrical current from cell to cell throughout the entire conductive system.

Copyright © 2008 Thomson Delmar Learning Four Specific Properties Contractility –Ability of cardiac muscle fibers to shorten and contract in response to an electrical stimulus

Copyright © 2008 Thomson Delmar Learning Refractory Periods Absolute refractory period Relative refractory period Nonrefractory period

Copyright © 2008 Thomson Delmar Learning Absolute Refractory Period Time in which the cells cannot respond to a stimulus Phases 0, 1, 2, and about half of 3 represent the absolute refractory period

Copyright © 2008 Thomson Delmar Learning Relative Refractory Period Time in which repolarization is almost complete Strong stimulus may cause depolarization of some of the cells Second half of phase 3 represents the relative refractory period

Copyright © 2008 Thomson Delmar Learning Nonrefractory Period Occurs when all the cells are in their resting or polarized state Phase 4 represents the nonrefractory period

Copyright © 2008 Thomson Delmar Learning Conductive System of the Heart Fig Conductive system of the heart.

Copyright © 2008 Thomson Delmar Learning Cardiac Response to Autonomic Nervous System Changes Table 12-1