Which phase of the non-pacemaker action potential is the resting potential with high K+ currents and low Ca++ and Na+ currents?

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Prepare for the Cardiac Electrophysiology Test. Enhance your knowledge with flashcards and multiple-choice questions, each supplemented with explanations and hints. Gear up for success on your exam!

Multiple Choice

Which phase of the non-pacemaker action potential is the resting potential with high K+ currents and low Ca++ and Na+ currents?

Explanation:
The key idea is the resting phase of a non-pacemaker cardiac myocyte. At rest, the cell’s membrane is highly permeable to potassium through inward rectifier channels, which drives the resting membrane potential to a negative value (around −90 mV). Because voltage-gated sodium and calcium channels are closed in this state, their inward currents are minimal, so there’s little depolarizing current. This is why the cell stays at a stable, negative resting potential with high potassium conductance and low calcium and sodium currents. In contrast, depolarization (rapid upstroke) is driven by a swift influx of Na+, the plateau phase arises from a sustained calcium influx, and repolarization follows mainly from potassium efflux. The described condition—resting at a stable negative potential with dominant K+ permeability and minimal Ca2+ and Na+ currents—matches the resting phase.

The key idea is the resting phase of a non-pacemaker cardiac myocyte. At rest, the cell’s membrane is highly permeable to potassium through inward rectifier channels, which drives the resting membrane potential to a negative value (around −90 mV). Because voltage-gated sodium and calcium channels are closed in this state, their inward currents are minimal, so there’s little depolarizing current. This is why the cell stays at a stable, negative resting potential with high potassium conductance and low calcium and sodium currents.

In contrast, depolarization (rapid upstroke) is driven by a swift influx of Na+, the plateau phase arises from a sustained calcium influx, and repolarization follows mainly from potassium efflux. The described condition—resting at a stable negative potential with dominant K+ permeability and minimal Ca2+ and Na+ currents—matches the resting phase.

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