Steven D. Girouard

Mechanism linking T-wave alternans to the genesis of cardiac fibrillation.

BACKGROUND Although T-wave alternans has been closely associated with vulnerability to ventricular arrhythmias, the cellular processes underlying T-wave alternans and their role, if any, in the mechanism of reentry remain unclear. METHODS AND RESULTS -T-wave alternans on the surface ECG was elicited in 8 Langendorff-perfused guinea pig hearts during fixed-rate pacing while action potentials were recorded simultaneously from 128 epicardial sites with voltage-sensitive dyes. Alternans of the repolarization phase of the action potential was observed above a critical threshold heart rate (HR) (209+/-46 bpm) that was significantly lower (by 57+/-36 bpm) than the HR threshold for alternation of action potential depolarization. The magnitude (range, 2.7 to 47.0 mV) and HR threshold (range, 171 to 272 bpm) of repolarization alternans varied substantially between cells across the epicardial surface. T-wave alternans on the surface ECG was explained primarily by beat-to-beat alternation in the time course of cellular repolarization. Above a critical HR, membrane repolarization alternated with the opposite phase between neighboring cells (ie, discordant alternans), creating large spatial gradients of repolarization. In the presence of discordant alternans, a small acceleration of pacing cycle length produced a characteristic sequence of events: (1) unidirectional block of an impulse propagating against steep gradients of repolarization, (2) reentrant propagation, and (3) the initiation of ventricular fibrillation. CONCLUSIONS Repolarization alternans at the level of the single cell accounts for T-wave alternans on the surface ECG. Discordant alternans produces spatial gradients of repolarization of sufficient magnitude to cause unidirectional block and reentrant ventricular fibrillation. These data establish a mechanism linking T-wave alternans of the ECG to the pathogenesis of sudden cardiac death.

Unique Properties of Cardiac Action Potentials Recorded with Voltage‐Sensitive Dyes

Unique Properties of Optical Action Potentials. Introduction: Optical mapping with voltage‐sensitive dyes has made it possible to record cardiac action potentials with high spatial resolution that is unattainable by conventional techniques. Optically recorded signals possess distinct properties that differ importantly from electrograms recorded with extracellular electrodes or action potentials recorded with microelectrode techniques. Despite the growing application of optical mapping to cardiac electrophysiology, relatively little quantitative information is available regarding the characteristics of optical action potentials recorded from cardiac tissue.

Modulation of Ventricular Repolarization by a Premature Stimulus Role of Epicardial Dispersion of Repolarization Kinetics Demonstrated by Optical Mapping of the Intact Guinea Pig Heart

Recent evidence suggests that ion channels governing the response of action potential duration (APD) to a premature stimulus (ie, APD restitution) are heterogeneously dispersed throughout the heart. However, because of limitations of conventional electrophysiological recording techniques, the effects of restitution in single cells on ventricular repolarization at the level of the intact heart are poorly understood. Using high-resolution optical mapping with voltage-sensitive dyes, we measured APD restitution kinetics at 128 simultaneous sites on the epicardial surface (1 cm2) of intact guinea pig hearts (n = 15). During steady state baseline pacing, APD gradients that produced a spatial dispersion of repolarization were observed. Mean APD was shortened monotonically from 186 +/- 19 ms during baseline pacing (S1-S1 cycle length, 393 +/- 19 ms) to 120 +/- 4 ms as single premature stimuli were introduced at progressively shorter coupling intervals (shortest S1-S2, 190 +/- 15 ms). In contrast, premature stimuli caused biphasic modulation of APD dispersion (defined as the variance of APD measured throughout the mapping field). Over a broad range of increasingly premature coupling intervals, APD dispersion decreased from 70 +/- 29 ms2 to a minimum of 10 +/- 7 ms2 at a critical S1-S2 interval (216 +/- 18 ms), and then, at shorter premature coupling intervals, APD dispersion increased sharply to 66 +/- 25 ms2. Modulation of APD dispersion by premature stimuli was attributed to coupling interval-dependent changes in the magnitude and direction of ventricular APD gradients, which, in turn, were explained by systematic heterogeneities of APD restitution across the epicardial surface. There was a characteristic pattern in the spatial distribution of cellular restitution such that faster restitution kinetics were closely associated with longer baseline APD. This relationship explained the reversal of APD between single cells, inversion of APD gradients across the heart, and ECG T-wave inversion during closely coupled premature stimulation. Therefore, because of the heterogeneous distribution of cellular restitution kinetics across the epicardial surface, a single premature stimulus profoundly altered the pattern and synchronization of ventricular repolarization in the intact ventricle. This response has important mechanistic implications in the initiation of arrhythmias that are dependent on dispersion of repolarization.

Optical Mapping in a New Guinea Pig Model of Ventricular Tachycardia Reveals Mechanisms for Multiple Wavelengths in a Single Reentrant Circuit

BACKGROUND Although the relationship between cardiac wavelength (lambda) and path length importantly determines the stability of reentrant arrhythmias, the physiological determinants of lambda are poorly understood. To investigate the cellular mechanisms that control lambda during reentry, we developed an experimental system for continuously monitoring lambda within a reentrant circuit with the use of voltage-sensitive dyes and a new guinea pig model of ventricular tachycardia (VT). METHODS AND RESULTS Action potentials were recorded simultaneously from 128 ventricular sites in Langendorff-perfused hearts (n = 15) in which propagation was confined to a two-dimensional rim of epicardium by an endocardial cryoablating procedure. The reentrant path was precisely controlled by creating an epicardial obstacle (2 x 10 mm) with an argon laser. To control for fiber orientation and rate-dependent membrane properties, lambda during reentry was compared with lambda during plane wave propagation transverse and longitudinal to cardiac fibers at a stimulus cycle length (CL) comparable to the VT CL. Reentrant VT (CL = 97.0 +/- 6.2 ms) was reproducibly induced by programmed stimulation in 93% of preparations. lambda varied considerably within the reentrant circuit (range, 10.6 to 22.5 mm), because of heterogeneities of conduction rather than action potential duration. lambda was significantly shorter during reentrant propagation (ie, with pivoting) parallel to fibers (10.6 +/- 4.2 mm) compared with plane wave propagation (ie, without pivoting) parallel to fibers (32.8 +/- 6.5 mm, P < .02), indicating that wave-front pivoting was primarily responsible for shortening of lambda during reentry. The mechanism of lambda shortening was conduction slowing from increased current load experienced by the pivoting wave front. CONCLUSIONS We provide direct experimental evidence that multiple wavelengths are present even within a relatively simple reentrant circuit. Abrupt changes in loading during wave-front pivoting, rather than membrane ionic properties or fiber structure, were a major determinant of lambda and, therefore, may play an important role in the stability of reentry.

Wild-Type and Mutant HCN Channels in a Tandem Biological-Electronic Cardiac Pacemaker

Background— Biological pacemakers (BPM) implanted in canine left bundle branch function competitively with electronic pacemakers (EPM). We hypothesized that BPM engineered with the use of mE324A mutant murine HCN2 (mHCN2) genes would improve function over mHCN2 and that BPM/EPM tandems confer advantage over either approach alone. Methods and Results— In cultured neonatal rat myocytes, activation midpoint was −46.9 mV in mE324A versus −66.1 mV in mHCN2 (P<0.05). mE324A manifested a positive shift of voltage dependence of gating kinetics of activation and deactivation compared with mHCN2 (P<0.05) in myocytes as well as Xenopus oocytes. In intact dogs in complete atrioventricular block, saline (control), mHCN2, or mE324A virus was injected into left bundle branch, and EPM were implanted (VVI 45 bpm). Twenty-four–hour ECGs were monitored for 14 days. With EPM discontinued, there was no difference in duration of overdrive suppression among groups. However, basal heart rates in controls were less than those in mHCN2, which did not differ from those in E324A (45 versus 57 versus 53 bpm; P<0.05). When spontaneous rate fell below 45 bpm, EPM intervened at that rate, triggering 83% of beats in control, contrasting (P<0.05) with 26% (mHCN2) and 36% (mE324A). On day 14, epinephrine (1 &mgr;g/kg per minute IV) induced a 50% heart rate increase in all mE324A, one third of mHCN2, and one fifth of control (P<0.05 mE324A versus control or mHCN2). Conclusions— mE324A induces faster, more positive pacemaker current activation than mHCN2 and stable, catecholamine-sensitive rhythms in situ that compete with EPM comparably but more catecholamine responsively than mHCN2. BPM/EPM tandems function reliably, reduce the number of EPM beats, and confer sympathetic responsiveness to the tandem.

Modulated Dispersion Explains Changes in Arrhythmia Vulnerability During Premature Stimulation of the Heart

BACKGROUND Previously, we have shown that a premature stimulus can significantly modulate spatial gradients of ventricular repolarization (ie, modulated dispersion), which result from heterogeneous electrophysiological properties between cells. The role modulated dispersion may play in determining electrical instability in the heart is unknown. METHODS AND RESULTS To determine if premature stimulus-induced changes in repolarization are a mechanism that governs susceptibility to cardiac arrhythmias, optical action potentials were recorded simultaneously from 128 ventricular sites (1 cm2) in 8 Langendorff-perfused guinea pig hearts. After baseline pacing (S1), a single premature stimulus (S2) was introduced over a range of S1S2 coupling intervals. Arrhythmia vulnerability after each premature stimulus was determined by measurement of a modified ventricular fibrillation threshold (VFT) during the T wave of each S2 beat (ie, S2-VFT). As the S1S2 interval was shortened to an intermediate value, spatial gradients of repolarization and vulnerability to fibrillation decreased by 51+/-9% (mean+/-SEM) and 73+/-45%, respectively, compared with baseline levels. As the S1S2 interval was further shortened, repolarization gradients increased above baseline levels by 54+/-30%, which was paralleled by a corresponding increase (37+/-8%) in vulnerability. CONCLUSIONS These data demonstrate that modulation of repolarization gradients by a single premature stimulus significantly influences vulnerability to ventricular fibrillation. This may represent a novel mechanism for the formation of arrhythmogenic substrates during premature stimulation of the heart.

Role of wavelength adaptation in the initiation, maintenance, and pharmacologic suppression of reentry.

Wavelength Adaptation and Reentry. Introduction: The stability of reentry is thought to depend on a critical balance between the spatial extent of refractory tissue in a reentrant wave (i.e., wavelength λ) and the reentrant path length. Because considerable evidence suggests that λ changes continuously in space and time during abrupt rate changes associated with the onset of tachycardia, we hypothesized that beat‐by‐beat adaptation of λ to the dimensions of the reentrant path plays a central role in the mechanism of initiation of reentry.

Atrial Defibrillation Thresholds of Electrode Configurations Available to an Atrioventricular Defibrillator

Atrial Defibrillation Thresholds. Introduction: Little investigation has been conducted to assess the atrial defibrillation thresholds of electrode configurations using electrodes designed for internal ventricular defibrillation (right ventricle [RV], superior vena cava [SVC], and pulse generator housing [Can]) combined with coronary sinus (CS) electrodes. We hypothesized that a CS → SVC+Can electrode configuration would have a lower atrial defibrillation threshold than a standard configuration for defibrillation, RV → SVC+Can. We also tested the atrial defibrillation thresholds of five other configurations.

Angiotensin-converting enzyme inhibition produces electrophysiologic but not antiarrhythmic effects in the intact heart.

Although angiotensin-converting enzyme (ACE) inhibitors are known to influence favorably the structural remodeling of the heart after myocardial infarction, the mechanisms by which ACE inhibitors improve survival are not well understood. The hypothesis that ACE inhibitors may possess antiarrhythmic activity has been studied in various isolated tissue preparations. However, the electrophysiologic effects of ACE inhibitors in the intact heart are not well understood. The effect of the ACE inhibitor enalaprilat on intact heart electrophysiology was studied by using multisite optical action-potential recordings with voltage-sensitive dyes. Action potentials were recorded simultaneously from 128 left ventricular epicardial sites in 15 Langendorff perfused hearts subjected to an endocardial cryoablation procedure, which was used to restrict propagation to a thin viable rim of epicardium. Action-potential duration (APD) was significantly prolonged in 67% of preparations perfused with 5 mg/L enalaprilat. Higher concentration of enalaprilat (50 mg/L) prolonged APD in all preparations tested. This APD-prolonging effect persisted over a broad range of stimulus rates, indicating the absence of reverse use-dependent properties. Enalaprilat did not modify conduction velocity, nor did it affect spatial dispersion of repolarization times. In addition, enalaprilat had no effect on ventricular fibrillation threshold and failed to suppress the initiation of ventricular tachycardia using an anatomically defined reentrant circuit. These findings indicate that in the intact heart, enalaprilat does indeed have electrophysiologic effects that cause APD prolongation, particularly at high drug concentrations. However, this effect was not of sufficient magnitude in the guinea pig to suppress the initiation of ventricular fibrillation or reentrant ventricular tachycardia.

Unique characteristics of optically recorded action potentials

Voltage-sensitive dyes have been used to optically monitor cardiac transmembrane potential for almost twenty years. This method now permits mapping of cardiac activation and recovery with spatial resolution that is unattainable by conventional mapping techniques. Despite the growing use and potential advantages of optical mapping with voltage-sensitive dyes, little information is available regarding optical action potential signal characteristics. Thus, no accepted standards for recording optical action potentials exists (e.g., sampling rates, analog filtering requirements). This paper will review some of the unique characteristics of optically recorded cardiac action potentials.