Prolongation Of Monophasic Action Potential Duration Research Articles

Selective inhibition of physiological late Na+ current stabilizes ventricular repolarization.

The physiological role of cardiac late Na+ current ( INa) has not been well described. In this study, we tested the hypothesis that selective inhibition of physiological late INa abbreviates the normal action potential (AP) duration (APD) and counteracts the prolongation of APD and arrhythmic activities caused by inhibition of the delayed rectifier K+ current ( IKr). The effects of GS-458967 (GS967) on the physiological late INa and APs in rabbit isolated ventricular myocytes and on the monophasic APs and arrhythmias in rabbit isolated perfused hearts were determined. In ventricular myocytes, GS967 and, for comparison, tetrodotoxin concentration dependently decreased the physiological late INa with IC50 values of 0.5 and 1.9 µM, respectively, and significantly shortened the APD measured at 90% repolarization (APD90). A strong correlation between inhibition of the physiological late INa and shortening of APD by GS967 or tetrodotoxin ( R2 of 0.96 and 0.97, respectively) was observed. Pretreatment of isolated myocytes or hearts with GS967 (1 µM) significantly shortened APD90 and monophasic APD90 and prevented the prolongation and associated arrhythmias caused by the IKr inhibitor E4031 (1 µM). In conclusion, selective inhibition of physiological late INa shortens the APD, stabilizes ventricular repolarization, and decreases the proarrhythmic potential of pharmacological agents that slow ventricular repolarization. Thus, selective inhibition of late INa may constitute a generalizable approach to stabilize ventricular repolarization and suppress arrhythmogenicity associated with conditions whereby AP or QT intervals are prolonged. NEW & NOTEWORTHY The contribution of physiological late Na+ current in action potential duration (APD) of rabbit cardiac myocytes was estimated. The inhibition of this current prevented the prolongation of APD in rabbit cardiac myocytes, the prolongation of monophasic APD, and generation of arrhythmias in rabbit isolated hearts caused by delayed rectifier K+ current inhibition.

Attenuated Ventricular β-Adrenergic Response and Reduced Repolarization Reserve in a Rabbit Model of Chronic Heart Failure

Animal models of pacing-induced heart failure (HF) are often associated with high acute mortality secondary to high pacing frequencies. The present study therefore exploits lower-frequency left ventricular pacing (300 beats per minute) in rabbits for 11 weeks to produce chronic HF with low acute mortality but profound structural, functional, and electrical remodeling and compare with nonpaced controls. Pacing increased heart weight/body weight ratio and decreased left ventricular fractional shortening in tachypaced only. Electrocardiogram recordings during sinus rhythm revealed QTc prolongation in paced animals. Ventricular arrhythmias or sudden death was not observed. Isoproterenol increased heart rate similarly in both groups but showed a blunted QT-shortening effect in tachypaced rabbits compared with controls. Langendorff experiments revealed significant monophasic action potential duration prolongation in tachypaced hearts and reduced contractility at cycle lengths from 400 to 250 ms. Hyperkalemia caused monophasic action potential duration shortening in controls, whereas crossover was seen in tachypaced with monophasic action potential duration prolongation at short cycle length. Hypokalemia prolonged monophasic action potential duration and increased short-term variability of repolarization in tachypaced hearts. A blunted monophasic action potential duration response was observed ex vivo in tachypaced hearts after isoproterenol. The HF rabbits showed structural, functional, and electrical remodeling but very low mortality. Isokalemic and hyperkalemic responses indicate downregulation of functional IKs. Increased short-term variability during hypokalemia unmasks a reduced repolarization reserve.

Cardioprotective Effects of Sarcolemmal and Mitochondrial K-ATP Channel Openers in an Experimental Model of Autoimmune Myocarditis

It has been reported that K-ATP channel openers have a cardioprotective effect in acute ischemia as a pharmacological preconditioning effect. In the present study, the chronic effects of clinical K-ATP channel openers, ie, nicorandil (Nic) and mexiletine (Mex), on cardiac function were evaluated in a rat model of experimental autoimmune myocarditis (EAM). Nicorandil (3 or 10 mg/kg/day) or Mex (10 or 25 mg/kg/day) was administered to the EAM rats, and the effects were compared with those in untreated EAM rats (control EAM) and sham rats without EAM on day 21 (acute phase) or day 60 (chronic phase). In the acute phase, the control EAM rats exhibited a reduced left ventricular ejection fraction (LVEF) and prolonged monophasic action potential duration (MAPD). Neither drug had an affect on the LVEF or degree of myocarditis, but Mex 25 mg suppressed the MAPD prolongation. In the chronic phase, EAM+Nic and EAM+Mex 25 mg exhibited a higher LVEF than the control EAM. Although the control EAM exhibited sustained MAPD prolongation, the other groups showed recovery of the MAPD in the chronic phase. The mitochondorial redox state was lower in the control EAM than in the sham, and EAM+Nic exhibited a similar level of the redox state as the sham in the chronic phase. Nicorandil exhibited a cardioprotective effect through the protection of mitochondrial function. Mexiletine exhibited a cardioprotective effect possibly through a reduction in the calcium overload by shortening the MAPD in the acute phase.

Prolongation of Cardiac Ventricular Repolarization Under Paliperidone: How and How Much?

Paliperidone (9-hydroxyrisperidone) is a second-generation antipsychotic. As observed with risperidone, QT interval prolongation was reported with paliperidone. The aim was to evaluate the effects of paliperidone on cardiac ventricular repolarization. (1) Patch-clamp experiments: Human ether-a-go-go-related gene (HERG)- or KCNQ1 + KCNE1-transfected cells were exposed to 0.1-100 μmol/L paliperidone (N = 39 cells, total) to assess the drug effect on HERG and KCNQ1 + KCNE1 currents. (2) Langendorff perfusion experiments: Hearts isolated from male Hartley guinea pigs (N = 9) were exposed to 0.1 μmol/L paliperidone to assess drug-induced prolongation of monophasic action potential duration measured at 90% repolarization. (3) In vivo cardiac telemetry experiments: Guinea pigs (N = 8) implanted with transmitters were injected a single intraperitoneal dose of 1 mg/kg of paliperidone, and 24-hour electrocardiogram recordings were made. (1) The estimated concentration at which 50% of the maximal inhibitory effect is observed (IC(50)) for paliperidone on HERG current was 0.5276 μmol/L. In contrast, 1 μmol/L paliperidone had hardly any effect on KCNQ1 + KCNE1 current (4.0 ± 1.6% inhibition, N = 5 cells). (2) While pacing the hearts at cycle lengths of 150, 200, or 250 milliseconds, 0.1 μmol/L paliperidone prolonged monophasic action potential duration measured at 90% repolarization by, respectively, 6.1 ± 3.1, 9.8 ± 2.7, and 12.8 ± 2.7 milliseconds. (3) Paliperidone (1 mg/kg) intraperitoneal caused a maximal 15.7 ± 5.3-millisecond prolongation of QTc. Paliperidone prolongs the QT interval by blocking HERG current at clinically relevant concentrations and is potentially unsafe.

Low-dose carvedilol reduces transmural heterogeneity of ventricular repolarization in congestive heart failure

To study the effects of carvedilol on the transmural heterogeneity of ventricular repolarization in rabbits with congestive heart failure (CHF). Rabbits were randomly divided into 3 groups: control, CHF and carvedilol treated CHF group. Monophasic action potential duration (MAPD) in the 3 myocardial layers was simultaneously recorded. All the rabbits in the CHF group had signs of severe CHF. Compared with the control group, the mean blood pressure and cardiac output were significantly decreased, while peripheral resistance was significantly increased in the CHF group. This proved that the CHF model was successful created with adriamycin in this study. Compared to the control group, the ventricular fibrillation threshold (VFT) was remarkably decreased and all MAPD of the 3 myocardial layers were extended in rabbits with CHF. However, the extension of MAPD in the midmyocardium was more obvious. The transmural dispersion of repolarization (TDR) was significantly increased in CHF. Low-dose carvedilol (0.25 mg/kg, twice daily) had no effects on ventricular remodeling. Treatment with low-dose carvedilol significantly increased VFT. Although the MAPD of the 3 myocardial layers were further prolonged in the carvedilol treated CHF group, the prolongation of MAPD in the midmyocardium was shorter than those in the epicardium and endocardium. Treatment with low-dose carvedilol significantly decreased TDR in CHF. In the present study, the transmural heterogeneity of ventricular repolarization increased in the rabbits with CHF. Low-dose carvedilol decreased the transmural heterogeneity of ventricular repolarization in CHF, which may be related to its direct electrophysiological property rather than its effect on ventricular remodeling.

Structural and electrical ventricular remodeling in rat acute myocarditis and subsequent heart failure.

We reported that experimental autoimmune myocarditis (EAM) rats showed dramatic changes in ventricular action potential and enhanced arrhythmogenicity in the acute phase, but mechanisms for this are still unclear. To investigate the mechanisms of cardiac remodeling in acute myocarditis and subsequent heart failure, physiological and molecular changes were evaluated along the time course of EAM. Six-week-old Lewis rats were immunized with porcine cardiac myosin. On days 14, 21, 35 and 60 after immunization, histology, hemodynamics and electrophysiological parameters (i.e., effective refractory period (ERP), monophasic action potential duration (MAPD) and PVC inducibility) were evaluated and compared with control rats. After these studies, the expression levels of Kv(+) and L-Ca(2+) channels, ion transporters and BNP expressions in the left ventricle were examined by quantitative real time RT-PCR and Western blot analysis. EAM rats showed acute myocarditis with massive infiltration of the mononuclear cells on days 14 and 21. Subsequently, a chronic dilated cardiomyopathy (DCM)-like structural change was observed on day 60. Hemodynamic parameters were worse in EAM than controls. ERP and MAPD were longer in EAM than controls, with a peak on day 21, which was parallel to PVC inducibility. mRNA levels of Kv4.2, Kv1.5, KChIP2, frequenin and SERCA2a, and the protein levels of Kv4.2 and Kv1.5, were reduced, especially in the acute phase. The initial reduction of Ito-related molecules, such as the expression levels of Kv4.2, 1.5, frequenin and KChIP2, and the prolongation of MAPD are considered to be a key mechanism of ventricular remodeling and cause the characteristic clinical findings in EAM in the acute inflammatory phase and chronic DCM phase.

Frequency-dependent electrophysiological effects of flecainide, nifekalant and d,l-sotalol on the human atrium.

To compare the effects of class Ic and III antiarrhythmic agents on the termination and prevention of atrial fibrillation, the present study investigated the use-dependent electrophysiological effects of flecainide, nifekalant and d,l-sotalol on the human atrium. Flecainide significantly prolonged effective refractory period (ERP), intra-atrial conduction time (IACT) and monophasic action potential duration (MAPD), and its effects on ERP and IACT were use-dependent. Nifekalalant significantly prolonged ERP and MAPD, and these effects were reverse use-dependent; however, there was no significant change in IACT. d,l-Sotalol significantly prolonged MAPD and the effect was reverse use-dependent. It significantly prolonged ERP, but the effect was not reverse use-dependent. d,l-Sotalol increased IACT in a use-dependent manner. Thus, for atrial fibrillation, class Ic antiarrhythmic agents might be more effective in termination and class III antiarrhythmic agents might be more effective in prevention.

Rate and time dependent effects of D-sotalol on the monophasic action potential after sudden increase of the heart rate.

Experimental and clinical data suggests that almost all Class III antiarrhythmic agents diminish their ability to prolong cardiac repolarization at fast heart rates. However, only limited data exists about the time course of efficacy decay of Class III agents after sudden increase of the heart rate. In the present study, we assessed both rate and time dependent changes of the efficacy of d-sotalol in higher stimulation frequencies following an abrupt increase in heart rate. This might imitate the situation seen in the development of paroxysmal tachycardias. Monophasic action potentials were recorded from the right ventricular apex during sinus rhythm and constant stimulation with the paced cycle length (PCL) of 550 ms, 400 ms, and 330 ms in the baseline and 20 minutes after intravenous administration of d-sotalol (2.5 mg/kg) in seven patients with documented life-threatening ventricular tachyarrhythmias. D-sotalol significantly prolonged monophasic action potential duration at different steady-state heart rates (sinus rhythm: 21.1% +/- 3.6%; PCL 550 ms: 16.6% +/- 4.3%, 400 ms: 11.2% +/- 2.7%, 330 ms: 5.8% +/- 2.1%). The prolongation is significantly shorter in higher steady-state pacing, confirming a pronounced reverse-use dependent decrease of the efficacy of d-sotalol at faster stimulation frequencies. After the abrupt increase in heart rate, the beat-to-beat adaptation of the postdrug action potential prolongation exhibits only slight reverse-use dependent shortening. The decrease of the efficacy of d-sotalol is insignificant for the first 20 consecutive beats at the stimulation frequency of the PCL of 400 msec (from 16.6% at PCL of 550 ms to 14.6% at the 20th beat of the PCL of 400 ms), and for the first ten consecutive beats at the stimulation frequency of the PCL of 330 ms (from 16.8% at PCL of 550 ms to 12.3% at the 10th beat of the PCL of 330 ms). This slow decay of action potential prolongation after an abrupt increase in heart rate might contribute to the antiarrhythmic action of d-sotalol in cardiac tachyarrhythmias.

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

Recently, ionic current simulation in the Luo-Rudy model has elucidated putative mechanisms of afterdepolarizations under various experimental conditions. The present study was aimed at gaining insight into the differential mechanism of different types of afterdepolarizations in the guinea-pig heart in vivo. The effects of pharmacological and heart rate perturbations on early (EADs) and delayed (DADs) afterdepolarizations, induced by either digoxin, CsCl, or BayK 8644 were studied, using mid-myocardial left ventricular monophasic action potential (MAP) recordings. Digoxin insignificantly shortened sinus cycle length (SCL) and CsCl and BayK 8644 differentially prolonged SCL and MAP duration. Digoxin induced phase 3-EADs and DADs and CsCl or BayK 8644 induced phase 2- and phase 3-EADs. Pinacidil shortened MAP duration, suppressed almost all the phase 2-EADs and some of the phase 3-EADs, but not the DADs. In a few cases, DADs were manifested following the abolishment of phase 2-EADs by pinacidil, but this phenomenon did not occur in the presence of hexamethonium. Verapamil prolonged SCL, did not significantly affect phase 2-EADs, but suppressed almost all of the DADs, including those which appeared after pinacidil, and all but one of the phase 3-EADs. The effects of pinacidil and verapamil were independent of the mode of afterdepolarization induction. A pacing-induced heart rate increase, which shortened MAP duration, and vagal stimulation, which prolonged MAP duration, attenuated and enhanced phase 2-EADs, respectively. The amplitude of phase 3-EADs was inversely related to the heart rate. These data, taken together, are consistent with those obtained previously by others in a computer model and recent observations on CsCl-induced EADs in the guinea-pig Purkinje fibers in vitro which have indicated that the mechanism of phase 2-EADs is different from that of DADs and that late phase 3-EADs generated under conditions of Ca2+ overload and DADs share similar properties.

Repeated intracoronary injections of contrast media. Additive hemodynamic and electrophysiologic effects in a dog model.

Coronary arteriography in patients implies several selective injections into the coronary arteries. The authors investigate whether repeated injections cause additive cardiac hemodynamic and electrophysiologic effects in dogs. Five repeated injections of 5 mL iohexol (Omnipaque 350 mgI/mL, Nycomed Imaging AS, Oslo, Norway), ioxaglate (Hexabrix 320 mgI/mL, Laboratory Guerbet, Cedex, France), and sodium meglumine-diatrizoate (Renografin-76 370 mgI/mL, Squibb Diagnostics, Princeton, NJ) were given into the left coronary artery in 7 anesthetized dogs and were compared with the effects after a 5 mL single injection of the same medium. Left ventricular (LV) pressures, LV dP/dtmax (inotropy) and epicardial monophasic action potential were recorded, from which monophasic action potential duration (MAPD) was measured. Repeated injections of ioxaglate and sodium meglumine-diatrizoate did not potentiate initial decrease in LV pressures and inotropy, but the secondary increase in LV inotropy increased more after repeated injections than after a single injection. Repeated injections of iohexol increased LV inotropy more than a single injection. All contrast media prolonged MAPD more after repeated injections than after single injections. MAPD was prolonged 30 sec after the last injection. Repeated injections of contrast media cause greater cardiac hemodynamic and electrophysiologic effects than a single injection during selective coronary arteriography.

Sotalol hydrochloride (Betapace): a new antiarrhythmic drug

Sotalol hydrochloride (Betapace), recently released by the Food and Drug Administration for general use, is used to treat a variety of ventricular and supraventricular tachyarrhythmias. The drug's dominant action is the result of combined nonselective beta-adrenergic antagonism (Class II effect) and monophasic action potential duration prolongation in all cardiac tissues (Class III effect). It causes less left ventricular depression than propranolol and has a low incidence of toxicity. It is a useful addition to the antiarrhythmic drug armamentarium. This article reviews the drug's pharmacokinetic, pharmacodynamic and electrophysiologic properties, clinical uses and potential side effects. Reports on the drug's use as an antianginal and antihypertensive agent are also discussed.

Computerized evaluation of drug-induced changes in guinea-pig epicardial monophasic action potentials.

The monophasic action potential (MAP) has been widely used for the study of drug effects on cardiac repolarization in vivo. There is, however, no study of drug-induced effects on MAP depolarization, i.e. effects on MAP Vmax and/or MAP rise-time. For this study, we developed a method in the anesthetized open chest guinea-pig. MAP signals were recorded and subjected to on-line computerized analysis, in which parameters describing both depolarization and repolarization were calculated. With the MAP electrode kept at the same epicardial position the MAP rise-time did not vary with time. If the influences of heart rate were eliminated, the intra- and interindividual variation in the MAP duration was very low. Sotalol significantly and dose-dependently prolonged MAP duration, but did not affect rise-time, whereas tocainide significantly and dose-dependently shortened MAP duration and increased rise-time. The effect of tocainide on rise-time is most likely secondary to a reduction in conduction velocity due to a decrease in Vmax in the single cell action potential. These results suggest that monophasic action potential recordings coupled with an on-line computerized analysis may be used for rapid and simple evaluation of drug effects, both on cardiac depolarization and repolarization.

Recording of monophasic action potentials in the horizontally perfused guinea pig heart: An in vitro method to study drug-induced changes in cardiac electrophysiology

An in vitro technique has been developed for the recording of monophasic action potentials to enable the measurement of changes in the duration of repolarization and in rise time produced by known concentrations of drugs and ions. Guinea pig hearts were perfused horizontally at constant pressure (60 cm H 2O) and temperature (37°C) with Krebs-Henseleit buffer. Epicardial monophasic action potentials were recorded from the right ventricular base using a bipolar Ag AgCI electrode to which a suction pressure of 400 mm Hg was applied. The monophasic action potential signals had smooth depolarization and repolarization phases with amplitudes of 25–65 mV; repeated measurements of monophasic action potential duration at the 50, 75, and 90% repolarization levels (MAPD 50, 75, and 90) and rise time, determined by computer analysis, were reproducible for at least 150 min of perfusion. There was an excellent linear correlation between heart rate and monophasic action potential duration. The ability of the method to detect drug-induced changes was confirmed using clofilium (10 −9 to 10 −5 M), which significantly prolonged monophasic action potential duration 50, 75, and 90 in a concentration-dependent manner, and tocainide (3 × 10 −4 M), which significantly decreased monophasic action potential duration 50, 75, and 90 and increased rise time.