Effects of pinacidil, verapamil, and heart rate on afterdepolarizations in the guinea-pig heart in vivo

The Electrogenic Na+/K+ Pump Is a Key Determinant of Repolarization Abnormality Susceptibility in Human Ventricular Cardiomyocytes: A Population-Based Simulation Study

Background: Cellular repolarization abnormalities occur unpredictably due to disease and drug effects, and can occur even in cardiomyocytes that exhibit normal action potentials (AP) under control conditions. Variability in ion channel densities may explain differences in this susceptibility to repolarization abnormalities. Here, we quantify the importance of key ionic mechanisms determining repolarization abnormalities following ionic block in human cardiomyocytes yielding normal APs under control conditions.

Methods and Results: Sixty two AP recordings from non-diseased human heart preparations were used to construct a population of human ventricular models with normal APs and a wide range of ion channel densities. Multichannel ionic block was applied to investigate susceptibility to repolarization abnormalities. I_Kr block was necessary for the development of repolarization abnormalities. Models that developed repolarization abnormalities over the widest range of blocks possessed low Na⁺/K⁺ pump conductance below 50% of baseline, and I_CaL conductance above 70% of baseline. Furthermore, I_NaK made the second largest contribution to repolarizing current in control simulations and the largest contribution under 75% I_Kr block. Reversing intracellular Na⁺ overload caused by reduced I_NaK was not sufficient to prevent abnormalities in models with low Na⁺/K⁺ pump conductance, while returning Na⁺/K⁺ pump conductance to normal substantially reduced abnormality occurrence, indicating I_NaK is an important repolarization current.

Conclusions: I_NaK is an important determinant of repolarization abnormality susceptibility in human ventricular cardiomyocytes, through its contribution to repolarization current rather than homeostasis. While we found I_Kr block to be necessary for repolarization abnormalities to occur, I_NaK decrease, as in disease, may amplify the pro-arrhythmic risk of drug-induced I_Kr block in humans.

Cell model of catecholaminergic polymorphic ventricular tachycardia reveals early and delayed afterdepolarizations

Background

Induced pluripotent stem cells (iPSC) provide means to study the pathophysiology of genetic disorders. Catecholaminergic polymorphic ventricular tachycardia (CPVT) is a malignant inherited ion channel disorder predominantly caused by mutations in the cardiac ryanodine receptor (RyR2). In this study the cellular characteristics of CPVT are investigated and whether the electrophysiological features of this mutation can be mimicked using iPSC -derived cardiomyocytes (CM).

Methodology/Principal Findings

Spontaneously beating CMs were differentiated from iPSCs derived from a CPVT patient carrying a P2328S mutation in RyR2 and from two healthy controls. Calcium (Ca²⁺) cycling and electrophysiological properties were studied by Ca²⁺ imaging and patch-clamp techniques. Monophasic action potential (MAP) recordings and 24h-ECGs of CPVT-P2328S patients were analyzed for the presence of afterdepolarizations. We found defects in Ca²⁺ cycling and electrophysiology in CPVT CMs, reflecting the cardiac phenotype observed in the patients. Catecholaminergic stress led to abnormal Ca²⁺ signaling and induced arrhythmias in CPVT CMs. CPVT CMs also displayed reduced sarcoplasmic reticulum (SR) Ca²⁺ content, indicating leakage of Ca²⁺ from the SR. Patch-clamp recordings of CPVT CMs revealed both delayed afterdepolarizations (DADs) during spontaneous beating and in response to adrenaline and also early afterdepolarizations (EADs) during spontaneous beating, recapitulating the changes seen in MAP and 24h-ECG recordings of patients carrying the same mutation.

Conclusions/Significance

This cell model shows aberrant Ca²⁺ cycling characteristic of CPVT and in addition to DADs it displays EADs. This cell model for CPVT provides a platform to study basic pathology, to screen drugs, and to optimize drug therapy.

Afterdepolarizations promote the transition from ventricular tachycardia to fibrillation in a three-dimensional model of cardiac tissue

Recent experimental results regarding the action potential duration restitution curve have explained the transition from ventricular tachycardia (VT) to fibrillation (VF) in terms of spiral wave (SW) meandering and breakup. However, it remains unclear whether VF always has a steep restitution curve. The present study was designed to test the hypothesis that afterdepolarizations occur at excitable gaps during VF and affect the SW dynamics, even if the restitution curve is gentle. Homogeneous and isotropic 3-dimensional tissue was simulated with a LRd model. Because of the gentle restitution curve, it was not expected that SW instabilities would occur in this condition. In the tissue, a stationary SW reentry was initially observed; however, afterdepolarizations erupted from the excitable gap near the SW tip, and the SW then meandered widely. Following that, afterdepolarizations erupted far from the SW tip, resulting in SW breakup. In this manner, the wave dynamics degenerated into a chaotic state within a few seconds. Furthermore, not only triggered activity but also subthreshold afterdepolarizations were found to cause SW instabilities. These results suggest that afterdepolarizations may play an important role in the transition to VF and that the mechanism is independent of restitution properties.

Proarrhythmic effects of adenosine: one decade of clinical data

In 1989, adenosine was introduced into the American clinical setting as an antiarrhythmic drug for the acute management of reentrant supraventricular tachycardia involving the atrioventricular node. During this decade of use, evidence for proarrhythmic effects of the drug have been documented. In addition to the mostly benign transient episodes of atrial fibrillation, several cases of life-threatening ventricular arrhythmias induced by adenosine have been reported. This article summarizes the proarrhythmic effects of adenosine as they were reported in the literature as well as data from the manufacturer files. The causes of these adverse effects of adenosine are analyzed, and factors to be considered before using the drug are discussed.

Effects of antiarrhythmic drugs on the monophasic action potential of the canine isolated, blood-perfused ventricular septum preparation

The present study was designed to combine the monophasic action potential (MAP) recording technique with a well-established canine isolated, blood-perfused ventricular septum preparation for examining, simultaneously, electrical and mechanical drug-induced changes. A MAP catheter was positioned onto the base of a papillary muscle for recording the local MAP, using a manual micromanipulator together with a commercially available catheter sheath to keep the optimal contact pressure against the ventricular wall. The catheter sheath was filled with saline to eliminate the background electrical noise. Tetrodotoxin, disopyramide, lidocaine, and verapamil were used to clarify the potential utility of the preparation. Tetrodotoxin and lidocaine shortened the MAP duration, while disopyramide prolonged it. Verapamil slightly shortened the MAP duration but not significantly. Each drug showed negative inotropic and coronary vasodilator effects. Sodium channel blockers slowed intraventricular conduction and decreased the maximum upstroke velocity of MAP, while verapamil showed no effects. These results suggest that utilization of the blood-perfused ventricular septum preparation together with MAP recording will become a valuable model for evaluating drugs with multiple sites of action on cardiac muscles.

Cellular basis of ventricular arrhythmias and abnormal automaticity in heart failure

The high incidence of sudden death in heart failure may reflect an increased propensity to abnormal repolarization and long Q-T interval-related arrhythmias. If so, cells from failing hearts would logically be expected to exhibit a heightened susceptibility to early afterdepolarizations (EAD). We found that midmyocardial ventricular cells isolated from dogs with pacing-induced heart failure exhibited an increased action potential duration and many more EAD than cells from nonpaced controls; this was the case both under basal conditions (P < 0.01) and after lowering external K(+) concentration ([K(+)](o)) to 2 mM and exposing cells to cesium (3 mM; P < 0.05). An unexpected finding was the occurrence of spontaneous depolarizations (SD, >5 mV) from the resting potential that were not coupled to prior action potentials. These SD were observed in 20% of failing cells (n = 5 of 25) under basal ionic conditions but in none of the normal cells (n = 0 of 27, P < 0.05). The net inward current that underlies SD is not triggered by Ca(2+) oscillations and thus differs fundamentally from the currents that underlie delayed afterdepolarizations. We conclude that cardiomyopathic canine ventricular cells are intrinsically predisposed to EAD and SD. Because EAD have been linked to the pathogenesis of torsade de pointes, our results support the hypothesis that sudden death in heart failure often arises from abnormalities of repolarization. The frequent occurrence of SD points to a novel cellular mechanism for abnormal automaticity in heart failure.

The dynamic behavior of the diastolic slope of monophasic action potential can be related to the occurrence and maintenance of delayed afterdepolarization dependent arrhythmias

We have described the value of the diastolic slope of the MAP recording at the end of a pacing train as a qualifying marker for the induction of delayed afterdepolarization (DAD) dependent arrhythmias. In the present study (1) the behavior of the slope at different time points during a pacing train was quantified and related to the arrhythmogenic outcome (group A) and (2) termination of DAD dependent VT was related to changes in the slope steepness (group B). In dogs with chronic complete AV block, a MAP was recorded during (1) ventricular pacing, before and after ouabain administration (group A) and (2) 6 spontaneous and 6 lidocaine induced VT terminations (group B). During control (group A), the slope at the end of pacing train was 5 +/- 3 m V/s (mean +/- SD), independent of the pacing duration. During ouabain, this increased to 20 +/- 15 mV/s (P < 0.05), varying with the duration of pacing. The slope was steeper after pacing for 4 seconds, compared to 20 seconds (26 +/- 12 mV/s vs 16 +/- 13 mV/s, P < 0.05) which corresponded with more frequent VT induction. In spontaneously terminating VTs (group B), CL increased from 353 +/- 54 ms at the start to 434 +/- 78 ms (P < 0.05) before VT termination. This corresponded with a decreasing steepness of the slope from 19 +/- 10 mV/s to 6 +/- 5 mV/s (P < 0.05). In lidocaine induced VT termination, the CL and the steepness of the slope showed an identical behavior. There is a dynamic variation in the steepness of the diastolic slope during pacing, which depends on the duration of pacing and predicts arrhythmogenic outcome. Furthermore, a decrease in steepness of the slope during DAD dependent VT can be used to predict VT termination.