Book contents
14 - Anti-arrhythmics
Published online by Cambridge University Press: 01 June 2010
Summary
Physiology
Cardiac action potential
The heart is composed of pacemaker, conducting and contractile tissue. Each has a different action potential morphology allowing the heart to function as a coordinated unit.
The SA node is in the right atrium, and of all cardiac tissue it has the fastest rate of spontaneous depolarization so that it sets the heart rate. The slow spontaneous depolarization (pre-potential or pacemaker potential) of the membrane potential is due to increased Ca2+ conductance (directed inward). At −40 mV, slow voltage-gated Ca2+ channels (L channels) open resulting in membrane depolarization. Na+ conductance changes very little. Repolarization is due to increased K+ conductance while Ca2+ channels close (Figure 14.1a).
Contractile cardiac tissue has a more stable resting potential at −80 mV. Its action potential has been divided into five phases (Figure 14.1b):
Phase 0 – describes the rapid depolarization (duration <1 ms) of the membrane, resulting from increased Na+ (and possibly some Ca2+) conductance through voltage-gated Na+ channels.
Phase 1 – represents closure of the Na+ channels while Cl− is expelled.
Plateau phase 2 – due to Ca2+ influx via voltage-sensitive type-L Ca2+ channels and lasts up to 150 ms. This period is also known as the absolute refractory period in which the myocyte cannot be further depolarized. This prevents myocardial tetany.
Phase 3 – commences when the Ca2+ channels are inactivated and there is an increase in K+ conductance that returns the membrane potential to its resting value. This period is also known as the relative refractory period in which the myocyte requires a greater than normal stimulus to provoke a contraction.
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- Pharmacology for Anaesthesia and Intensive Care , pp. 228 - 245Publisher: Cambridge University PressPrint publication year: 2008