[Transvenous parasympathetic nerve stimulation in the chronic myocardial infarction phase]. / Transvenöse Stimulation parasympathischer Nerven in der chronischen Infarktphase.

The study describes the electrophysiological effects of transvenous cardiac nerve stimulation in an animal model of myocardial infarction. In ten sheep with recent myocardial infarction, transvenous stimulation of parasympathetic cardiac nerves was achieved from a catheter in the right pulmonary artery. The effects of transvenous cardiac nerve stimulation on sinus rhythm cycle length, ventricular refractory periods and inducibility of monomorphic ventricular tachycardia were evaluated. Sinus rhythm cycle length increased from 620 +/- 24 ms to 723 +/- 30 ms during nerve stimulation with 20 Hz and to 779 +/- 28 ms during stimulation with 40 Hz (p < 0.05). Effective ventricular refractory periods from stimulation sites in non-infarcted right and left ventricular myocardium showed a tendency towards prolongation during cardiac nerve stimulation with shortening after cessation of stimulation. These differences, however, were not significant. In contrast, refractory periods from stimulation sites within the infarcted area remained unchanged during cardiac nerve stimulation. The inducibility of monomorphic ventricular tachycardia by programmed electrical stimulation was reduced during transvenous cardiac nerve stimulation. Pathological examination showed cholinergic nerves in close proximity to the tip of the stimulation catheter in the right pulmonary artery. Transvenous cardiac nerve stimulation in sheep with remote myocardial infarction exhibits electrophysiological effects on the ventricles. Although a parasympathetic effect on the ventricles could not be proven, the observed effects may result from direct stimulation of efferent parasympathetic nerves.

Right atrial septal electrode for reducing the atrial defibrillation threshold.

BACKGROUND: The atrial defibrillation threshold (ADFT) energy of the standard lead configuration, right atrial appendage (RAA) to coronary sinus (CS), was reduced by >50% with the addition of a third electrode traversing the atrial septum in a previous study. This study determined whether the ADFT would be lowered by a more clinically practical third electrode placed in the right atrium along the atrial septum (RSP). METHODS AND RESULTS: Sustained atrial fibrillation was induced in 8 closed-chest sheep with burst pacing and maintained with pericardial infusion of acetyl-beta-methylcholine chloride. A custom-made, dual-defibrillation catheter was placed with electrodes in the lateral RA, CS, and RSP. A separate defibrillation catheter was also placed in the RAA. ADFT characteristics of RAA-->CS and 6 other single- or sequential-shock configurations were determined in random order by using biphasic, truncated-exponential waveforms in a multiple-reversal protocol. The delivered-energy, peak-voltage, and peak-current ADFTs for the sequential-shock configuration CS-->RSP/RA-->RSP (0.53+/-0.31 J, 86+/-22 V, and 1.6+/-0.6 A, respectively) were significantly lower than those of RAA-->CS (1.14+/-0.64 J, 157+/-34 V, and 2.5+/-1.1 A, respectively). The ADFT characteristics of RAA-->CS and RA-->CS were not significantly different, nor were those of CS-->RSP/RA-->RSP and CS-->RSP/RAA--> RSP. CONCLUSIONS: The ADFT of the standard RAA-->CS configuration may be markedly reduced with an additional electrode situated at the RSP.

Atrial defibrillation thresholds of electrode configurations available to an atrioventricular defibrillator.

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. METHODS AND RESULTS: In 12 closed chest sheep, we situated a two-coil (RV, SVC) defibrillation catheter, a left-pectoral subcutaneous Can, and a CS lead. Atrial fibrillation was burst induced and maintained with continuous infusion of intrapericardial acetyl-beta-methylcholine chloride. Using fixed-tilt biphasic shocks, we determined the atrial defibrillation thresholds of seven test configurations in random order according to a multiple-reversal protocol. The peak voltage and delivered energy atrial defibrillation thresholds of CS-->SVC+Can (168+/-67 V, 2.68+/-2.40 J) were significantly lower than those of RV-->SVC+Can (215+/-88 V, 4.46+/-3.40 J). The atrial defibrillation thresholds of the other test configurations were RV+CS-->SVC+Can: 146+/-59 V, 1.92+/-1.45 J; RV-->CS+SVC+Can: 191+/-89 V, 3.53+/-3.19 J; CS-->SVC: 188+/-98 V, 3.77+/-4.14 J; SVC-->CS+ Can: 265+/-145 V, 7.37+/-9.12 J; and SVC-->Can: 516+/-209 V, 24.5+/-15.0 J. CONCLUSIONS: The atrial defibrillation threshold of CS-->SVC+Can is significantly lower than that of RV-->SVC+Can. In addition, the low atrial defibrillation threshold of RV+CS-->SVC+Can merits further investigation. Based on corroboration of low atrial defibrillation thresholds of CS-based configurations in humans, physicians might consider using CS leads with atrioventricular defibrillators.

Critically timed auxiliary shock to weak field area lowers defibrillation threshold.

INTRODUCTION: This study tested the hypothesis that the defibrillation threshold (DFT) can be lowered by delivering a weak auxiliary shock in conjunction with a stronger primary shock to the cardiac region where the primary shock electric field is weakest. METHODS AND RESULTS: Eight swine were studied in each of two study parts. In both parts, DFTs were determined for dual shocks delivered through two electrode pairs. The biphasic primary shock was delivered through electrodes in the right ventricle and superior vena cava. The auxiliary shock was delivered through a separate electrode in the superior vena cava and a left ventricular electrode placed where the primary shock field was presumed to be weakest. In part I, a monophasic auxiliary shock of 50, 100, or 150 V was delivered either simultaneously with or 1, 20, or 40 msec before primary shock. When auxiliary shock was delivered simultaneously with or 1 msec before primary shock, DFT energy was reduced by approximately 50% compared with primary shock alone. In part II, a 150-V monophasic or biphasic auxiliary shock of either polarity was delivered 1 msec before or after primary shock. Regardless of waveform or polarity, all auxiliary shock delivered before primary shock lowered DFT energy by approximately 30% compared with primary shock alone. Depending on waveform and polarity, auxiliary shock delivered after primary shock either did not significantly change the DFT or elevated the DFT compared with primary shock alone. CONCLUSION: Application of a small auxiliary shock, just before or simultaneously with a primary shock, to the cardiac region where the primary shock field is weakest significantly lowers DFT.

Reduction of atrial defibrillation threshold with an interatrial septal electrode.

BACKGROUND: The standard lead configuration for internal atrial defibrillation consists of a shock between electrodes in the right atrial appendage (RAA) and coronary sinus (CS). We tested the hypothesis that the atrial defibrillation threshold (ADFT) of this RAA-->CS configuration would be lowered with use of an additional electrode at the atrial septum (SP). METHODS AND RESULTS: Sustained atrial fibrillation was induced in 8 closed-chest sheep with burst pacing and continuous pericardial infusion of acetyl-ss-methylcholine. Defibrillation electrodes were situated in the RAA, CS, pulmonary artery (PA), low right atrium (LRA), and across the SP. ADFTs of RAA-->CS and 4 other lead configurations were determined in random order by use of a multiple-reversal protocol. Biphasic waveforms of 3/1-ms duration were used for all single and sequential shocks. The ADFT delivered energies for the single-shock configurations were 1.27+/-0.67 J for RAA-->CS and 0. 86+/-0.59 J for RAA+CS-->SP; the ADFTs for the sequential-shock configurations were 0.39+/-0.18 J for RAA-->SP/CS-->SP, 1.16+/-0.72 J for CS-->SP/RAA-->SP, and 0.68+/-0.46 J for RAA-->CS/LRA-->PA. Except for CS-->SP/RAA-->SP versus RAA-->CS and RAA-->CS/LRA-->PA versus RAA+CS-->SP, the ADFT delivered energies of all of the configurations were significantly different from each other (P:<0. 05). CONCLUSIONS: The ADFT of the standard RAA-->CS configuration is markedly reduced with an additional electrode at the atrial SP.

Marked reduction of ventricular defibrillation threshold by application of an auxiliary shock to a catheter electrode in the left posterior coronary vein of dogs.

INTRODUCTION: For endocardial shocks near the defibrillation threshold (DFT), postshock activity originates from the lateral left ventricular apex, where the shock field is weak. This study tested the hypothesis that an auxiliary shock (AS) delivered between an electrode at this site and a superior vena cava (SVC) electrode before the primary endocardial shock (PS) would reduce the DFT. METHODS AND RESULTS: In six pentobarbital-anesthetized dogs (26 to 36 kg), catheter electrodes were placed in the right ventricular (RV) apex and the SVC. To simulate transvenous introduction, a small electrode was inserted into the posterior cardiac vein using an epicardial approach. For dual shock treatments, AS (2-msec monophasic) was applied to the coronary vein electrode at different time intervals before a biphasic PS (4 msec/3 msec) to the RV-SVC electrodes. The mean DFT energy for dual shocks treatments were significantly reduced (P < 0.05) in comparison to the control treatment (no AS, 26.5+/-8.8 J). Mean DFT energy after 10 seconds of electrically induced ventricular fibrillation for dual shocks, in which AS and PS were separated by 1, 5, 10, and 20 msec, were 10.2+/-4.1 J, 10.9+/-5.5 J, 11.3+/-6.3 J, and 15.4+/-7.2 J, respectively. These values were all significantly lower than the PS alone (26.5+/-8.8 J). CONCLUSION: Addition of an AS from the posterior cardiac vein before an endocardial PS reduces DFT energy by more than 50%. Such DFT reduction could improve therapeutic safety margin or permit reduction in volume of implantable cardioverter defibrillators.

Prevention of high incidence of neurally mediated ventricular arrhythmias by afferent nerve stimulation in dogs.

BACKGROUND: This study tested the hypothesis that the high incidence of ventricular arrhythmias caused by hypothalamic stimulation during acute myocardial ischemia could be attenuated by afferent nerve stimulation and investigated the cardiac mechanisms for those effects. METHODS AND RESULTS: In 18 anesthetized dogs, stimulating electrodes were implanted in the hypothalamus and in the isolated left peroneal nerve. The chest was opened and approximately 100 plunge needles were inserted into the ventricles for 3-D activation mapping. Each animal underwent 4 episodes of 2.5 minutes of acute myocardial ischemia. The first and fourth episodes served as controls. During the second and third episodes, animals received either hypothalamic stimulation, peroneal nerve stimulation, or both. Hypothalamic stimulation significantly increased the incidence of ventricular arrhythmias. This high incidence was reduced 34% by simultaneous stimulation of the hypothalamus and peroneal nerve. 3-D mapping showed a focal origin for all ventricular arrhythmias. Hypothalamic stimulation increased the number of arrhythmic beats and decreased the coupling interval between each arrhythmic beat and the preceding beat. These effects were reduced by peroneal nerve stimulation. CONCLUSIONS: Alteration in autonomic tone by hypothalamic stimulation causes a high incidence of ventricular arrhythmias during acute myocardial ischemia that can be decreased by afferent nerve stimulation.

Fibrillation is more complex in the left ventricle than in the right ventricle.

INTRODUCTION: The mechanisms that maintain ventricular fibrillation (VF) are not completely understood. It has been proposed that increased ventricular wall thickness destabilizes VF wavefronts and therefore is an important determinant of VF activation patterns. We hypothesized that if this is the case, then VF patterns on the thin-walled right ventricle (RV) should be simpler than those on the thick-walled left ventricle (LV). METHODS AND RESULTS: In seven open chest pigs, we mapped VF simultaneously from two epicardial recording arrays, one on the RV and one on the LV. Each array contained 504 unipolar electrodes (in a 21 x 24 grid) spaced by 2 mm. We used specialized pattern analysis methods to compute quantitative descriptors of RV and LV activation patterns. Our data show that VF is more organized in the RV than the LV, containing fewer, larger wavefronts that follow fewer distinct pathways and are less likely to fragment or collide with other wavefronts. The incidence, size, and cycle length of reentrant circuits were similar in the two ventricles, but RV reentry persisted for more cycles. These results are not predicted by the differences in electrophysiologic properties between LV and RV that have been reported in mammalian hearts. CONCLUSION: The geometry of the ventricular wall, particularly wall thickness, is an important determinant of VF activation patterns.

Effects of peroneal nerve stimulation on hypothalamic stimulation-induced ventricular arrhythmias in rabbits.

We tested the hypothesis that peripheral afferent nerve stimulation decreases the incidence of ventricular arrhythmias induced by central nervous system stimulation. The hypothalamus in each of 24 anesthetized rabbits (12 with anterior myocardial ischemia) was electrically stimulated for 10 s with 10-min intervals between each of six consecutive stimulation episodes. The left peroneal nerves were electrically stimulated for 15 min beginning 5 min after the second hypothalamic stimulation episode in six ischemic and six nonischemic rabbits. Cardiac rhythm was monitored with the electrocardiogram lead I and atrial and ventricular electrograms. Hypothalamic stimulation alone induced ventricular arrhythmias [mean no. of arrhythmic beats occurring during 3rd and 4th hypothalamic stimulation episodes: nonischemic animals, 20 +/- 8; ischemic animals, 62 +/- 41 (P < 0.05 by unpaired t-test)]. Peroneal nerve stimulation reduced the number of arrhythmic beats induced by hypothalamic stimulation in nonischemic animals (6 +/- 5; P < 0.05 vs. without peroneal stimulation) and prevented an increase in arrhythmic beats during ischemia (21 +/- 16). Thus peripheral nerve stimulation decreased the number of ventricular arrhythmic beats induced by repeated hypothalamic stimulation in both ischemic and normal rabbit hearts and may be important in the prevention of arrhythmias in patients.

Existence of both fast and slow channel activity during the early stages of ventricular fibrillation.

Although sodium channels have been reported to be inactive after 5-10 minutes of ventricular fibrillation (VF), their state during early VF is unknown. In 12 open-chest dogs, a floating glass microelectrode was used to record intracellular action potentials from the right ventricle during pacing and during electrically induced VF. Before any drug was administered, an initial episode of VF was continuously recorded for at least 20 seconds followed by defibrillation. Recordings were made during VF episodes after superfusion for 15 minutes around the microelectrode site by low (2.8 x 10(-5) M) and high (10(-4) M) concentrations of tetrodotoxin (TTX) in five dogs, or by low (4 microM) and high (100 microM) concentrations of verapamil in another four dogs. In three dogs, VF was induced without drugs three times to determine if the effects observed in the previous dogs were caused by the drugs or by successive episodes of VF. Ten consecutive action potentials were analyzed at the onset and after 5, 10, 15, and 20 seconds of VF. Action potential amplitude and duration during paced rhythm or VF were not changed by the local perfusion of either TTX or verapamil. In the TTX group, the maximum upstroke rate of depolarization of an action potential (Vmax) during paced rhythm was 104 +/- 14 V/sec for control cycles before any drug was given, 86 +/- 15 V/sec for the low TTX concentration, and 55 +/- 14 V/sec for the high TTX concentration (p less than 0.05 versus other two). Vmax decreased from 55 +/- 32 V/sec at the beginning of VF to 37 +/- 27 V/sec after 20 seconds of VF for predrug VF, from 39 +/- 20 V/sec to 18 +/- 11 V/sec for low-dose TTX VF, and from 18 +/- 13 V/sec to 12 +/- 7 V/sec for high-dose TTX VF (p less than 0.05 among the three groups). In the dogs receiving verapamil, VF was still inducible with Vmax not significantly different from predrug VF at the onset and after 5 or 20 seconds of VF but with Vmax smaller (p less than 0.05) for verapamil than for predrug VF after 10 or 15 seconds of VF. In three dogs, Vmax was not significantly different during three successive episodes of VF when no drug was given between the episodes.(ABSTRACT TRUNCATED AT 400 WORDS)