Abnormal excitability of myocardial cells may give rise to ectopic beats and initiate re-entry around an anatomical or functional obstacle. As K + currents control the repolarization process of the cardiac action potential (AP), the K+ channel function determines membrane potential and refractoriness of the myocardium. Both gain and loss of the K+ channel function can lead to arrhythmia. The former because abbreviation of the active potential duration (APD) shortens refractoriness and wave length, and thereby facilitates re-entry and the latter because excessive prolongation of APD may lead to torsades de pointes (TdP) arrhythmia and sudden cardiac death. The pro-arrhythmic consequences of malfunctioning K+ channels in ventricular and atrial tissue are discussed in the light of three pathophysiologically relevant aspects: genetic background, drug action, and disease-induced remodelling. In the ventricles, loss-of-function mutations in the genes encoding for K+ channels and many drugs (mainly hERG channel blockers) are related to hereditary and acquired long-QT syndrome, respectively, that put individuals at high risk for developing TdP arrhythmias and life-threatening ventricular fibrillation. Similarly, down-regulation of K+ channels in heart failure also increases the risk for sudden cardiac death. Mutations and polymorphisms in genes encoding for atrial K + channels can be associated with gain-of-function and shortened, or with loss-of-function and prolonged APs. The block of atrial K+ channels becomes a particular therapeutic challenge when trying to ameliorate atrial fibrillation (AF). This arrhythmia has a strong tendency to cause electrical remodelling, which affects many K+ channels. Atrial-selective drugs for the treatment of AF without affecting the ventricles could target structures such as IKur or constitutively active I K,ACh channels.
Role of potassium currents in cardiac arrhythmias / U.Ravens; E.Cerbai. - In: EUROPACE. - ISSN 1099-5129. - STAMPA. - 10:(2008), pp. 1133-1137.
Role of potassium currents in cardiac arrhythmias.
CERBAI, ELISABETTAWriting – Original Draft Preparation
2008
Abstract
Abnormal excitability of myocardial cells may give rise to ectopic beats and initiate re-entry around an anatomical or functional obstacle. As K + currents control the repolarization process of the cardiac action potential (AP), the K+ channel function determines membrane potential and refractoriness of the myocardium. Both gain and loss of the K+ channel function can lead to arrhythmia. The former because abbreviation of the active potential duration (APD) shortens refractoriness and wave length, and thereby facilitates re-entry and the latter because excessive prolongation of APD may lead to torsades de pointes (TdP) arrhythmia and sudden cardiac death. The pro-arrhythmic consequences of malfunctioning K+ channels in ventricular and atrial tissue are discussed in the light of three pathophysiologically relevant aspects: genetic background, drug action, and disease-induced remodelling. In the ventricles, loss-of-function mutations in the genes encoding for K+ channels and many drugs (mainly hERG channel blockers) are related to hereditary and acquired long-QT syndrome, respectively, that put individuals at high risk for developing TdP arrhythmias and life-threatening ventricular fibrillation. Similarly, down-regulation of K+ channels in heart failure also increases the risk for sudden cardiac death. Mutations and polymorphisms in genes encoding for atrial K + channels can be associated with gain-of-function and shortened, or with loss-of-function and prolonged APs. The block of atrial K+ channels becomes a particular therapeutic challenge when trying to ameliorate atrial fibrillation (AF). This arrhythmia has a strong tendency to cause electrical remodelling, which affects many K+ channels. Atrial-selective drugs for the treatment of AF without affecting the ventricles could target structures such as IKur or constitutively active I K,ACh channels.I documenti in FLORE sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.