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Diversity of ion channel expression in health and disease

S. Kaab* and M. Näbauer

LMU München, Klinikum Großhadern, Department of Medicine I, München, Germany

* Correspondence: Dr Stefan Kääb, LMU Munchen, Klinikum Großhadern, Department of Medicine I, 81366 München, Germany.

Abstract

Heterogeneity of action potential waveforms among different species and within specific regions of an individual's heart is a function of the diversity of ion channel expression. These species differences, mainly in repolarizing currents, have to be considered in interpreting experimental studies on arrhythmogenesis in animals. Even among larger mammals, such as dog and pig, mechanisms of repolarization differ significantly. Differential expression of ion channels in various regions of the heart, and more specifically the transmural distribution in ventricular myocardium, is currently under close investigation. The strongest transventricular gradient in human ventricular myocardium exists for the calcium independent transient outward current (ITo1), with its current being 4–5-fold larger in epicardial than in endocardial cells.

In hypertrophy and heart failure the hallmark feature of a prolonged action potential again reflects the altered diversity of ion channel expression. Prolonged and labile repolarization in hypertrophy and heart failure in both animal models and humans is predominantly caused by down-regulation of potassium channels. The reduction of outward potassium currents in hypertrophy and heart failure may contribute to the enhanced sensitivity of failing myocardium to proarrhythmia triggering factors such as hypokalaemia, ischaemia, antiarrhythmic drugs with class III effects and non-antiarrhythmic drugs with QT prolongation potential.

Key Words: Ion channels • repolarization • hypertrophy • heart failure • arrhythmia • sudden cardiac death

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