Autonomic modulation and antiarrhythmic therapy in a model of long QT syndrome type 3.

AIMS: Clinical observations in patients with long QT syndrome carrying sodium channel mutations (LQT3) suggest that bradycardia caused by parasympathetic stimulation may provoke torsades de pointes (TdP). Beta-adrenoceptor blockers appear less effective in LQT3 than in other forms of the disease. METHODS AND RESULTS: We studied effects of autonomic modulation on arrhythmias in vivo and in vitro and quantified sympathetic innervation by autoradiography in heterozygous mice with a knock-in deletion (DeltaKPQ) in the Scn5a gene coding for the cardiac sodium channel and increased late sodium current (LQT3 mice). Cholinergic stimulation by carbachol provoked bigemini and TdP in freely roaming LQT3 mice. No arrhythmias were provoked by physical stress, mental stress, isoproterenol, or atropine. In isolated, beating hearts, carbachol did not prolong action potentials per se, but caused bradycardia and rate-dependent action potential prolongation. The muscarinic inhibitor AFDX116 prevented effects of carbachol on heart rate and arrhythmias. beta-Adrenoceptor stimulation suppressed arrhythmias, shortened rate-corrected action potential duration, increased rate, and minimized difference in late sodium current between genotypes. Beta-adrenoceptor density was reduced in LQT3 hearts. Acute beta-adrenoceptor blockade by esmolol, propranolol or chronic propranolol in vivo did not suppress arrhythmias. Chronic flecainide pre-treatment prevented arrhythmias (all P < 0.05). CONCLUSION: Cholinergic stimulation provokes arrhythmias in this model of LQT3 by triggering bradycardia. beta-Adrenoceptor density is reduced, and beta-adrenoceptor blockade does not prevent arrhythmias. Sodium channel blockade and beta-adrenoceptor stimulation suppress arrhythmias by shortening repolarization and minimizing difference in late sodium current.

Regional, age-dependent, and genotype-dependent differences in ventricular action potential duration and activation time in 410 Langendorff-perfused mouse hearts.

Although numerous studies have reported the effects of genetic alterations on murine electrophysiology, the range of normal values for ventricular activation, repolarization, and arrhythmias in mouse hearts is not known. We analyzed right ventricular (RV), left ventricular (LV), and septal activation times, monophasic action potential durations (APD), and right ventricular effective refractory periods during spontaneous rhythm, induced AV nodal block, right ventricular pacing (100-300 ms paced cycle length), and programmed stimulation in 410 beating, Langendorff-perfused, wild-type mouse hearts of CD1, DBAC3H, FVBN, C57/Bl6, and hybrid backgrounds (age 203 +/- 132 days). Action potential duration was longer at longer cycle lengths. LV-APD prolonged more than RV-APD, resulting in an increased heterogeneity of APD at longer pacing cycle lengths. Higher heart weight/body weight ratio and DBAC3H and FVB/N backgrounds were associated with long APD, C57Bl/6 background was associated with short APD. Activation times were longer in older hearts. There were no clear-cut sex-dependent APD differences. Sustained spontaneous arrhythmias occurred in 1% of hearts, non-sustained arrhythmias in 18%. Induction of AV block and C57Bl/6 genetic background were associated with spontaneous arrhythmias. Programmed stimulation induced arrhythmias in 51% of hearts. Inducible arrhythmias were associated with advanced age and shorter refractory periods. Ventricular APD in beating mouse hearts show rate- and site-dependent changes comparable to man and large animals. Bradycardia provokes spontaneous arrhythmias in mouse heart, while age-dependent conduction slowing and short refractory periods predispose to induced arrhythmias. Genetic background influences repolarization and arrhythmogenesis. These findings provide systematic data for the design and interpretation of arrhythmia studies in murine disease models.