Hemodynamic and hormone changes during induced ventricular tachycardia secondary to coronary artery disease

Vasovagal Responses to Human Monomorphic Ventricular Tachycardia: Hemodynamic Implications From Sinus Rate Analysis

BACKGROUND

Factors determining hemodynamic stability during human ventricular tachycardia (VT) are incompletely understood.

OBJECTIVES

The purposes of this study were to characterize sinus rate (SR) responses during monomorphic VT in association with hemodynamic stability and to prospectively assess the effects of vagolytic therapy on VT tolerance.

METHODS

This is a retrospective analysis of patients undergoing scar-related VT ablation. Vasovagal responses were evaluated by analyzing sinus cycle length before VT induction and during VT. SR responses were classified into 3 groups: increasing (≥5 beats/min, sympathetic), decreasing (≥5 beats/min, vagal), and unchanged, with the latter 2 categorized as inappropriate SR. In a prospective cohort (n = 30) that exhibited a failure to increase SR, atropine was administered to improve hemodynamic tolerance to VT.

RESULTS

In 150 patients, 261 VT episodes were analyzed (29% untolerated, 71% tolerated) with median VT duration 1.6 minutes. A total of 52% of VT episodes were associated with a sympathetic response, 31% had unchanged SR, and 17% of VTs exhibited a vagal response. A significantly higher prevalence of inappropriate SR responses was observed during untolerated VT (sustained VT requiring cardioversion within 150 seconds) compared with tolerated VT (84% vs 34%; P < 0.001). Untolerated VT was significantly different between groups: 9% (sympathetic), 82% (vagal), and 32% (unchanged) (P < 0.001). Atropine administration improved hemodynamic tolerance to VT in 70%.

CONCLUSIONS

Nearly one-half of VT episodes are associated with failure to augment SR, indicative of an under-recognized pathophysiological vasovagal response to VT. Inappropriate SR responses were more predictive of hemodynamic instability than VT rate and ejection fraction. Vagolytic therapy may be a novel method to augment blood pressure during VT.

"Vasovagal" response during ventricular fibrillation: incidence and implications

BACKGROUND

The purpose of this study was to assess the relationship between changes in sinus node cycle length (SNCL) during ventricular fibrillation (VF) and the peripheral changes in blood pressure (BP) and sympathetic nerve activity (SNA) in human subjects. We hypothesized that patients with no SNCL shortening during VF have a vasovagal-like response with a greater decrease in BP and SNA when compared to patients with SNCL shortening.

METHODS

SNCL, BP, and SNA recordings were attempted in 24 patients undergoing the implantation of a dual-chamber implantable defibrillator. Changes were measured during the first 5 seconds of VF and compared with the 5 seconds prior to VF induction.

RESULTS

SNCL shortened during VF in nine patients (mean%∆SNCL = -12 ± 8%) and remained unchanged or lengthened in seven patients (mean%∆SNCL = 7 ± 7%). Eight patients had ventriculoatrial (VA) conduction prohibiting assessment of SNCL changes. In patients with SNCL shortening, the %∆MBP (mean BP) was -47 ± 6% compared to -58 ± 8% in patients with no SNCL shortening (P < 0.01). In patients with VA conduction, the %∆MBP was -54 ± 3%. SNA recordings were successfully obtained in four patients. When compared to baseline, SNA increased by 34 ± 30% in two patients with SNCL shortening, decreased by 25% in one patient with SNCL lengthening, and by 90% in the fourth patient with VA conduction.

CONCLUSIONS

We have shown that patients with no SNCL shortening have a significantly greater decrease in MBP during VF when compared to patients with SNCL shortening. The underlying mechanism appears to be reflex mediated with a vasovagal-like response in patients with no SNCL shortening.

Modulation of the sinus rate during ventricular fibrillation

BACKGROUND

During supraventricular and ventricular tachycardia, the arterial baroreflex predominates with minimal contribution from the cardiopulmonary reflex. To our knowledge, the role of the arterial baroreflex gain (BRG) during and immediately following termination of ventricular fibrillation (VF) has not been characterized.

OBJECTIVE

We hypothesized that (1) arterial BRG correlated with sinus node cycle length (SNCL) changes during VF, and that (2) the greater the arterial BRG, the greater the blood pressure (BP) recovery following successful defibrillation.

METHODS

Arterial BRG was assessed in 18 patients referred for the implantation of a defibrillator incorporating an atrial lead. The average SNCL was measured during the 5 seconds prior to VF induction and the last 5 seconds during VF before defibrillation. Percent SNCL change (%DeltaSNCL) was determined. Arterial BP recovery was calculated as the difference in mean BP following defibrillation compared to during VF.

RESULTS

Arterial BRG ranged between -3 and 18 ms/mmHg. During VF, SNCL shortened in 11 patients (group A, mean %DeltaSNCL =-15%), and surprisingly lengthened in seven patients (group B, mean %DeltaSNCL = 5%). There was no correlation between %DeltaSNCL and arterial BRG. In fact, arterial BRG in group A was lower when compared with group B (P = 0.075). Similarly, there was no correlation between arterial BRG and BP recovery.

CONCLUSIONS

We found no correlation between arterial BRG and %DeltaSNCL during VF, or BP recovery following defibrillation. Our findings of SNCL lengthening in 7 of 18 patients suggest that in some patients, arterial BRG plays a minor role during VF with a greater contribution from the cardiopulmonary BRG.

Characteristics of the acute rise of atrial natriuretic factor during ventricular pacing

BACKGROUND

Previous studies have shown that peripheral venous levels of atrial natriuretic factor (ANF) are elevated during ventricular pacing as a result of asynchrony of atrial and ventricular contraction. However, the pattern by which ANF rises following institution of ventricular pacing has not been fully established and its physiologic consequences are unclear.

METHODS

Eight ambulatory patients in stable condition with dual-chamber pacemakers were studied. The pacemaker was reprogrammed from the dual-chamber to the ventricular pacing mode for 3 h, during which serial measurements were made of BP, heart rate and rhythm, levels of ANF, and plasma renin activity (PRA).

RESULTS

ANF levels rose markedly but slowly following the onset of ventricular pacing, reaching levels as high as 694% of control. The rise occurred over the course of 120 min, at which time the average value for the group plateaued at 82.5 +/- 22.1 fmol/mL (mean +/- SEM) vs 25.3 +/- 4.5 fmol/mL at control (p < 0.01); there was, however, marked variability in individual responses. By contrast, levels of PRA remained remarkably stable. Average BP changes were small, although there was a trend in the later part of the study for systolic pressure to decrease.

CONCLUSIONS

ANF levels rise markedly but gradually after institution of ventricular pacing and, hence, acute pacing studies must account for this delay in their design. The physiologic importance of the rise in ANF should be evaluated further since the rise in peptide levels may be associated with a decrease in systolic BP.

Reflex control of sympathetic activity during simulated ventricular tachycardia in humans

BACKGROUND

Ventricular tachyarrhythmias present a unique set of stimuli to arterial and cardiopulmonary baroreceptors by increasing cardiac filling pressures and decreasing arterial pressure. The net effect on the control of sympathetic nerve activity (SNA) in humans is unknown. The purpose of this study was to determine the relative roles of cardiopulmonary and arterial baroreceptors in controlling SNA and arterial pressure during ventricular pacing in humans.

METHODS AND RESULTS

Two experiments were performed in which SNA and hemodynamic responses to ventricular pacing were compared with nitroprusside infusion (NTP) in 12 patients and studied with and without head-up tilt or phenylephrine to normalize the stimuli to either the arterial or cardiopulmonary baroreceptors in 9 patients. In experiment 1, the slope of the relation between SNA and mean arterial pressure was greater during NTP (-4.7+/-1.4 U/mm Hg) than during ventricular pacing (-3.4+/-1.1 U/mm Hg). Comparison of NTP doses and ventricular pacing rates that produced comparable hypotension showed that SNA increased more during NTP (P=0.03). In experiment 2, normalization of arterial pressure during pacing resulted in SNA decreasing below baseline (P<0.05), whereas normalization of cardiac filling pressure resulted in a greater increase in SNA than pacing alone (212+/-35% versus 189+/-37%, P=0. 04). Conclusions--These data demonstrate that in humans arterial baroreflex control predominates in mediating sympathoexcitation during ventricular tachyarrhythmias and that cardiopulmonary baroreceptors contribute significant inhibitory modulation.

Baroreflex gain predicts blood pressure recovery during simulated ventricular tachycardia in humans

BACKGROUND

Despite similar degrees of left ventricular dysfunction and similar tachycardia or pacing rate, blood pressure (BP) response and symptoms vary greatly among patients. Sympathetic nerve activity (SNA) increases during sustained ventricular tachycardia (VT), and the magnitude of this sympathoexcitatory response appears to contribute to the net hemodynamic outcome. We hypothesize that the magnitude of sympathoexcitation and thus arterial baroreflex gain is an important determinant of the hemodynamic outcome of VT.

METHODS AND RESULTS

We evaluated the relation between arterial baroreflex sympathetic gain and BP recovery during rapid ventricular pacing (VP) in patients referred for electrophysiological study. Efferent postganglionic muscle SNA, BP, and central venous pressure (CVP) were measured in 14 patients during nitroprusside infusion and during VP at 150 (n=12) or 120 (n=2) bpm. Arterial baroreflex gain was defined as the slope of the relationship of change in SNA to change in diastolic BP during nitroprusside infusion. Recovery of mean arterial pressure (MAP) during VP was measured as the increase in MAP from the nadir at the onset of pacing to the steady-state value during sustained VP. Arterial baroreflex gain correlated positively with recovery of MAP (r=0.57, P=0.034). No significant correlation between ejection fraction and baroreflex gain (r=0.48, P=0.08) or BP recovery (r=0.41, P=0.15) was found. When patients were separated into high versus low baroreflex gain, the recovery of MAP during simulated VT was significantly greater in patients with high gain.

CONCLUSIONS

These data strongly suggest that arterial baroreflex gain contributes significantly to hemodynamic stability during simulated VT. Knowledge of baroreflex gain in individual patients may help the clinician tailor therapy directed toward sustained VT.

Vasoactive peptide release in relation to hemodynamic and metabolic changes during rapid ventricular pacing

Plasma atrial natriuretic peptide (ANP) concentration increases during ventricular arrhythmias and rapid ventricular pacing but less is known about plasma brain natriuretic peptide (BNP) and endothelin (ET-1). In the present study concentrations of ANP, the amino terminal part of the proANP (NT-proANP), BNP, and ET-1 were measured in the coronary sinus and femoral artery before and at the end of rapid ventricular pacing in 15 patients with coronary arterial disease. The changes were compared with the changes in mean arterial blood pressure, pulmonary capillary wedge pressure (PCWP), transcardiac differences in pH, pCO2, lactate, and norepinephrine. There was an increase in PCWP and a transient decrease in blood pressure after initiation of pacing. Pacing caused a decrease in ST-segment, transcardiac difference of norepinephrine, lactate extraction, pCO2 difference, and an increase in pH difference. Concentration of ANP in the coronary sinus and femoral artery and its transcardiac difference increased during pacing (P < 0.001), whereas changes in NT-proANP were small and BNP and ET-1 levels remained unchanged. The change in transcardiac ANP difference correlated with the change in lactate (r = 0.53, P < 0.05) but not that of norepinephrine, PCWP, or blood pressure. The results show that the plasma concentration of ANP increases more than that of NT-proANP during rapid ventricular pacing. Ischemia-induced release of ANP and its diminished elimination may contribute to the increased plasma ANP level.

Effect of atrial natriuretic peptide on electrical defibrillation efficacy

INTRODUCTION

In vitro studies have suggested that human atrial natriuretic peptide (ANP) modulates the electrophysiologic properties of myocardial cells. This study assessed whether ANP could influence defibrillation efficacy.

METHODS AND RESULTS

In 35 anesthetized dogs, the transcardiac defibrillation threshold (DFT) as well as hemodynamic and electrophysiologic variables were determined before and during treatment with ANP (n = 11), hydralazine (n = 11), or saline (n = 13). ANP (1.5 microg/kg + 0.2 microg/kg per min) increased the plasma concentration of cyclic GMP (a second messenger for ANP) and significantly decreased aortic blood pressure (mean 100+/-11 mmHg to 83+/-15 mmHg). ANP also prolonged ventricular repolarization (effective refractory period 157+/-7 msec to 165+/-11 msec) and markedly reduced DFT (5.4+/-1.2 J to 3.8+/-0.7 J [P < 0.01]) without changing pulmonary artery pressure or sinus cycle length. Neither saline nor hydralazine (1.5 mg/kg) had a significant effect on DFT (saline 4.7+/-2.1 J to 4.6+/-2.4 J; hydralazine 4.3+/-2.0 J to 4.2+/-1.9 J), although hydralazine caused pronounced hypotension (mean aortic pressure 103+/-9 mmHg to 74+/-13 mmHg).

CONCLUSION

These results suggest that ANP increases defibrillation efficacy, and that this effect is not necessarily shared by other vasodilating agents.

Reflex control of sympathetic activity during ventricular tachycardia in dogs: primary role of arterial baroreflexes

BACKGROUND

The determinants of hemodynamic outcome during ventricular tachycardia (VT) are not well understood. In the present study, we addressed the relative contributions of arterial and cardiopulmonary baroreflexes to the sympathetic and arterial pressure responses to VT or ventricular pacing (VP) in dogs with inducible VT.

METHODS AND RESULTS

Responses of renal sympathetic nerve activity (RSNA), pulmonary capillary wedge pressure (PCWP), and mean arterial pressure (MAP) to induced VT or VP (220 to 280 beats per minute) were determined in 12 dogs with a healed anteroapical infarction and inducible VT and in 8 control dogs. The responses were determined with all reflexes intact, after selective denervation of either arterial or cardiopulmonary baroreflexes, and after combined denervation. Differences between intact and denervated conditions were used to assess the relative effects of each baroreflex. In the infarct group, responses during VT were comparable to those during VP. RSNA and PCWP increased significantly (P<.01), whereas MAP decreased significantly (P<.001) during VT or VP with baroreflexes intact in both groups. The increase in RSNA and the recovery of MAP during sustained VP were greater in the infarct group (P<.05); in addition, the increase in PCWP was greater in the infarct group (P<.05). Arterial baroreflex denervation abolished the increased RSNA and recovery of MAP during VP in both groups. After cardiopulmonary baroreflex denervation, the increase in RSNA was augmented in both groups (control group more than infarct group), but recovery of MAP was increased further only in the control group.

CONCLUSIONS

These results suggest that arterial baroreflex mediated sympathoexcitation plays an important role in determining the hemodynamic outcome during VT, whereas cardiopulmonary baroreflexes play only a modest modulatory role.

Hemodynamic recovery, atrial natriuretic peptide, and catecholamines during simulated ventricular tachycardia: effects of ventriculoatrial conduction

Ventriculoatrial (VA) sequence and neurohumoral responses may be important modulators of hemodynamic recovery during VT. We studied the effects of VA conduction on blood pressure recovery, and levels of atrial natriuretic peptide (ANP), epinephrine, and norepinephrine during simulated VT. After diagnostic coronary angiography, VT was simulated by rapid right ventricular pacing (150 beats/min, 3 mins) in a consecutive series of patients. Whenever the patients demonstrated VA dissociation during ventricular pacing, they were included in the study. After 10 minutes of recovery, a group of nine patients then underwent an additional VA pacing (150 beats/min, 3 mins, VA delay of 150 msec). Intra-arterial blood pressure was continuously monitored, and plasma ANP and catecholamine levels were measured before, during, and after both pacing protocols. The mean arterial pressures declined rapidly by 26% and 30% after initiation of ventricular and VA pacing, respectively. The blood pressure then gradually recovered, the hemodynamic recovery being better during VA pacing. Plasma ANP and catecholamine levels increased toward the end of both pacing periods. The observed increase in ANP concentration was more prominent during VA pacing than ventricular pacing (P < 0.001), whereas catecholamine levels increased similarly. The results show that during simulated VT hemodynamic recovery is partially dependent on VA sequence. The increases in circulating ANP and catecholamines occur too slowly to account for the rapid changes in blood pressures observed after initiation of simulated VT. Therefore, other mechanisms, such as reflex stimulation of the sympathoadrenergic nervous system, must be involved, too. ANP release increases when atrial contraction frequency increases, but the exact determinants for this release remain unknown.

Renal sympathetic responses to conflicting baroreceptor inputs: rapid ventricular pacing in dogs

1. Ventricular tachycardia generates complex changes in baroreceptor input to the central nervous system: arterial baroreceptors are unloaded while cardiopulmonary receptors are stimulated. In humans with heart diseases, muscle sympathetic nerve activity increases during ventricular tachycardia. This suggests that arterial baroreceptor-mediated sympathoexcitation overrides cardiopulmonary receptor-mediated sympathoinhibition. However, the relative roles of each reflex are difficult to determine in humans. 2. We measured efferent renal sympathetic neural responses to simulated ventricular tachycardia, to determine what pathophysiological mechanisms are invoked when inputs from different baroreceptive areas change in opposite directions. In alpha-chloralose anaesthetized, mechanically ventilated dogs, we recorded the electrocardiogram, mean left atrial and arterial pressures and multifibre efferent renal sympathetic nerve activity (RSNA) during 1 min of right ventricular pacing at 214 beats min-1. Pacing was repeated after either sinoaortic or vagal cardiopulmonary denervation and again after both sinoaortic and cardiopulmonary denervation. 3. With all afferent baroreceptor pathways intact, right ventricular pacing elicited transient sympathoinhibition (delta RSNA, -19 +/- 10%, mean +/- S.E.M.). After sinoaortic denervation (cardiopulmonary receptors intact), right ventricular pacing elicited abrupt and sustained sympathoinhibition (delta RSNA, -53 +/- 8%, P < 0.05 vs. intact). After vagal cardiopulmonary denervation (sinoaortic receptors intact), right ventricular pacing elicited abrupt and sustained sympathoexcitation (delta RSNA, + 56 +/- 19%, P < 0.05 vs. intact). After both sinoaortic and vagal cardiopulmonary denervation, right ventricular pacing elicited a gradual increase in sympathetic outflow (delta RSNA, + 16 +/- 6%, P < 0.05 vs. intact). 4. We conclude that interactions between vagal cardiopulmonary and arterial baroreflexes determine renal sympathetic outflow during simulated ventricular tachycardia. In healthy anaesthetized dogs, the balance of the two opposing reflexes is weighted towards vagal cardiopulmonary-mediated sympathoinhibition.

Atrial natriuretic factor release during rapid ventricular pacing: interplay between autonomic and hemodynamic stimulants

Plasma levels of atrial natriuretic factor (ANF) and norepinephrine are markedly elevated during episodes of ventricular tachycardia. Although atrial distention appears to be the major stimulus for ANF release, reflex changes in autonomic tone might also contribute. Plasma ANF and norepinephrine levels, sinus node cycle length, systolic blood pressure, and mean right atrial pressure were therefore assessed during rapid right ventricular pacing at 150 beats/min for 10 minutes. In five patients (group 1) observations were made without autonomic blockade, and another five patients (group 2) had ventricular pacing after cardiac autonomic blockade. In group 1 systolic blood pressure fell during ventricular pacing from 122 +/- 4 to 105 +/- 5 mm Hg (p < 0.02), norepinephrine levels increased from 195 +/- 26 to 411 +/- 71 pg/ml (p < 0.02), and sinus node cycle length decreased from 936 +/- 99 to 688 +/- 58 msec (p < 0.02). Right atrial pressure was elevated from 2.6 +/- 0.6 to 7.4 +/- 0.6 mm Hg (p < 0.02), and ANF levels increased from 161 +/- 23 to 240 +/- 26 pg/ml (p < 0.05). Whereas systolic blood pressure, norepinephrine, sinus cycle length, and right atrial pressure returned promptly to baseline levels when ventricular pacing was stopped, ANF levels continued to rise (296 +/- 37 pg/ml; p < 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)

Sympathetic neural responses to induced ventricular tachycardia

Although sympathetic mechanisms play a major role in buffering abrupt arterial pressure reductions, including those that occur during tachyarrhythmias, human sympathetic nervous system responses to ventricular tachycardia have not been measured. Muscle sympathetic nerve activity was recorded directly from the peroneal nerve in 16 patients during diagnostic induction of 19 episodes of sustained monomorphic ventricular tachycardia (average rate 189 beats/min, range 130 to 250). Average systolic and diastolic pressures decreased from 149/78 to 61/49 mm Hg by 10 s and increased toward baseline levels to 88/64 mm Hg by 1 min of ventricular tachycardia. Average sympathetic nerve activity increased by 92% at 10 s in direct proportion to arterial pressure reductions and in inverse proportion to ventricular rate and remained 83% above baseline levels at 1 min. The late recovery of arterial pressure during ventricular tachycardia was related significantly to the magnitude of early sympathetic responses. Sympathetic activity tended to lose its discrete bursting pattern during ventricular tachycardia, and power spectral analysis showed that the large sympathetic peaks at the heart rate frequency present during sinus rhythm are absent during ventricular tachycardia. This study is the first to delineate human sympathetic nervous system responses to ventricular tachycardia. The results suggest that in the patients studied, large early sympathetic surges differed from those that occur during sinus rhythm and contributed to hemodynamic stability during ventricular tachycardia.