Practice viewpoints: AICD, who and when?

Automatic implantable cardioverter-defibrillator (AICD) is a costly but effective treatment modality for the prevention of sudden cardiac death (SCD). Causes of SCD are age-dependent, disease-specific and affected by racial/ethnic differences. Atherosclerotic heart disease (ASHD) is the most frequent underlying disease in individuals ≥35 years old. Available information suggests that Asians have a lower rate of SCD compared with African black individuals and Caucasians. Whether it is for secondary or for primary prevention, physicians should be educated to perform a thorough diagnostic work-up and be able to identify transient and/or reversible causes of lethal ventricular tachyarrhythmias such as acute myocardial infarction, residual ischaemia, electrolyte imbalance, adverse effect of drugs, valvular heart diseases, etc before contemplating AICD implantation. Correction of these reversible causes may avoid the necessity of AICD implantation. The status of left ventricular function is not sufficiently specific for guiding AICD implantation in ASHD patients after acute myocardial infarction. The urgent need is to develop better biological or physiological markers for risk stratification so that patients who would actually benefit from AICD implantation can be readily identified. Such an approach will make the use of AICD more cost-effective. Based on molecular genetic data obtained from patients with inherited structural cardiovascular diseases and malignant arrhythmogenic disorders in which the risk of SCD appears to be gene- and/or mutant-specific, a continuous search for genetic markers for better risk stratification is warranted in patients suffering from ASHD.

Influence of isoproterenol on the accelerated junctional rhythm observed during radiofrequency catheter ablation of atrioventricular nodal slow pathway conduction.

BACKGROUND: Accelerated junctional rhythm (AJR) has been considered as a sensitive but rather nonspecific marker of successful radiofrequency (RF) ablation of slow pathway in patients with atrioventricular nodal reentrant tachycardia (AVNRT). However, AJR also occurs commonly during isoproterenol infusion. We therefore investigated the effect of isoproterenol on the significance of AJR while attempting slow pathway ablation. METHODS: Forty patients with AVNRT underwent slow pathway ablation. Sixty-nine RF applications accompanied by AJR were observed and were separated into 2 groups: applications performed without (group I, n = 26) and with (group II, n = 43) isoproterenol infusion. The specificity of AJR for successful ablation for each group was calculated. RESULTS: The specificity of AJR in groups I and II was 73% (19/26) and 49% (21/43), respectively (P <.05). There was no significant difference between the groups in the atrial electrogram width, atrial/ventricular electrogram amplitude ratio, the time from application onset to AJR emergence, or AJR cycle length. The catheter-tip temperature at AJR emergence was significantly lower (47 degrees C +/- 3 degrees C vs 52 degrees C +/- 3 degrees C, P <.001) and the ratio of junctional beats to total heart beats during RF application was significantly greater (46% +/- 24% vs 33% +/- 18%, P <.05) in group II compared with group I. CONCLUSIONS: Isoproterenol lowers the threshold of AJR emergence during RF application and thereby lowers the specificity of AJR for successful ablation. Complete washout of isoproterenol may therefore improve the specificity of AJR during RF ablation in patients with AVNRT.

Spatial heterogeneity of calcium transient alternans during the early phase of myocardial ischemia in the blood-perfused rabbit heart.

BACKGROUND: Optical mapping of cytosolic calcium transients in intact mammalian hearts is now possible using long-wavelength [Ca(2+)](i) indicators. We propose that beat-to-beat [Ca(2+)](i) transient alternans during ischemia may lead to spatial and temporal heterogeneity of calcium-activated membrane currents. METHODS AND RESULTS: To test this hypothesis, isolated rabbit hearts were loaded with the fluorescent [Ca(2+)](i) indicator, rhod-2 AM, and imaged at 300 frames/sec during blood-perfused ischemic trials. High-quality [Ca(2+)](i) transients were recorded in each of 8 hearts.[Ca(2+)](i) transient alternans was never present in control records but occurred in each of the hearts during ischemia, with onset after 2 to 4 minutes. Alternans was confined to circumscribed regions of the heart surface 5 to 15 mm across. Multiple regions of alternans were found in most hearts, and regions that were out of phase with one another were found in 6 hearts. Quantitative maps of alternans were constructed by calculating an alternans ratio. This ratio behaved as a continuous variable that reached a maximum value in the center of the regions with alternans. CONCLUSIONS: These results demonstrate marked spatial heterogeneity of the [Ca(2+)](i) transient during the early phase of ischemia, which could produce electrical instability and arrhythmias in large mammalian hearts.

Electrophysiologic characteristics of ventricular extrastimulation-induced dissipation of functional bundle branch block associated with supraventricular tachycardia.

INTRODUCTION: Linking-related anterograde functional bundle branch block during supraventricular tachycardia (SVT) is due to repetitive concealed retrograde conduction of impulses from the contralateral bundle branch and can be eliminated by a critically timed premature ventricular beat (PVB). We assessed the electrophysiologic characteristics of PVB-induced dissipation of functional bundle branch block during SVT. METHODS AND RESULTS: During SVT with functional bundle branch block, PVB was delivered from the right ventricular apex, scanning the tachycardia cycle length (CL) with 10-msec decrements in the coupling interval in 14 patients (3 AV nodal reentrant tachycardia and 11 orthodromic AV reciprocating tachycardia). Dissipation was achieved in group 1: functional right bundle branch block (RBBB) in 4, functional left bundle branch block (LBBB) in 4, and both functional RBBB and LBBB in 1 with a dissipation zone occupying 4% to 13% (mean 8.5%) of the tachycardia CL. The outer limits were 22+/-16 msec and 68+/-14 msec < tachycardia CL; the inner limits were 56+/-18 msec and 90+/-24 msec < tachycardia CL for RBBB and LBBB, respectively (both P < 0.05). Dissipation could not be achieved in group 2 (4 RBBB and 1 LBBB) due to CL-dependent bundle branch block and/or local ventricular refractoriness. CONCLUSION: During SVT, functional bundle branch block due to "linking" often can be dissipated by timely PVB delivered from the right ventricular apex within a narrow zone of the tachycardia CL. Our findings suggest that the dissipation zone is affected by the pattern of functional bundle branch block relative to the site of PVB delivery.

Antiarrhythmic agents in facilitating electrical cardioversion of atrial fibrillation and promoting maintenance of sinus rhythm.

Atrial fibrillation (AF) is a prevalent arrhythmia associated with significant morbidity and mortality. Electrical cardioversion of AF is a potentially definitive treatment, but as little as 67% of patients may be successfully cardioverted and, after normal sinus rhythm (NSR) is achieved, AF often recurs. Class IA, IC, and III antiarrhytmic agents are used for both facilitation of electrical cardioversion and subsequent maintenance of NSR. The mechanisms of these agents may be related to suppressing automaticity, prolonging the wavelength of reentrant wavelets, and preventing electrical remodeling. The possibility of proarrhythmia and other adverse effects complicates use of these drugs, and no large trials have been completed to elucidate definite indications. Several factors may predict failure with electrical cardioversion alone (duration of AF, atrial size, age, underlying disease, and factors that affect transthoracic impedance), calling for empiric pharmacotherapy to facilitate cardioversion. For this purpose, class IA agents hold some promise, evidence for class IC agents is conflicting, and class III agents are the most effective. Adverse effects are rare given the short course before cardioversion, but ibutilide, the most efficacious in this regard, may be proarrhythmic after only a single dose. In promoting maintenance of sinus rhythm, antiarrhythmics across the different classes have similar efficacies: NSR may be maintained in approximately 40-65% of patients compared to approximately 30-35% with placebo at 1 year. Amiodarone is distinct in its success, with approximately 60-80% of patients remaining in NSR. For all of these agents, long-term therapy may lead to proarrhythmia or other substantial adverse effects. Finally, a serial antiarrhythmic strategy may be effective, with maintenance of NSR and minimal adverse effects ultimately achieved by trial and error.

T-DNA insertional mutagenesis for functional genomics in rice.

We have produced 22 090 primary transgenic rice plants that carry a T-DNA insertion, which has resulted in 18 358 fertile lines. Genomic DNA gel-blot and PCR analyses have shown that approximately 65% of the population contains more than one copy of the inserted T-DNA. Hygromycin resistance tests revealed that transgenic plants contain an average of 1.4 loci of T-DNA inserts. Therefore, it can be estimated that approximately 25 700 taggings have been generated. The binary vector used in the insertion contained the promoterless beta-glucuronidase (GUS) reporter gene with an intron and multiple splicing donors and acceptors immediately next to the right border. Therefore, this gene trap vector is able to detect a gene fusion between GUS and an endogenous gene, which is tagged by T-DNA. Histochemical GUS assays were carried out in the leaves and roots from 5353 lines, mature flowers from 7026 lines, and developing seeds from 1948 lines. The data revealed that 1.6-2.1% of tested organs were GUS-positive in the tested organs, and that their GUS expression patterns were organ- or tissue-specific or ubiquitous in all parts of the plant. The large population of T-DNA-tagged lines will be useful for identifying insertional mutants in various genes and for discovering new genes in rice.

Sudden cardiac death syndrome: diagnosis and management.

Sudden cardiac death (SCD) can be caused by a variety of cardiac and noncardiac disorders. The diagnostic work-up includes detailed history, physical examination, electrocardiography (ECG), chemistry panel, 24-hour Holter ECG recording, and echocardiography. In selected patients, treadmill-exercise testing, electrophysiologic study, cardiac catheterization with coronary angiography, magnetic resonance imaging, and endomyocardial biopsy are performed. The treatment strategy is rationalized according to the underlying disorder and clinical presentation. Correction of reversible causes such as hypoxia, myocardial ischemia, electrolyte imbalance, congestive heart failure, and proarrhythmic effects of drugs is essential. In patients with arteriosclerotic heart disease, coronary revascularization, using percutaneous coronary angioplasty with stenting or aortocoronary bypass grafting, and optimization of hemodynamics are often necessary. For survivors of SCD syndrome (secondary prevention), implantation of a cardioverter/defibrillator (ICD) is the treatment of choice, with or without adjunct antiarrhythmic drug therapy. Reduction of the sympathetic influence such as with beta-adrenergic blockade and control of hypertension or congestive heart failure may abate the triggering mechanism, thereby reducing the rate of arrhythmia reemergence. Because of the ease of the implantation technique and refined programmability, the current trend is to apply ICD therapy in patients deemed at high risk of SCD, with the aim of primary prevention.

Comparison of a novel rectilinear biphasic waveform with a damped sine wave monophasic waveform for transthoracic ventricular defibrillation. ZOLL Investigators.

OBJECTIVES: We compared the efficacy of a novel rectilinear biphasic waveform, consisting of a constant current first phase, with a damped sine wave monophasic waveform during transthoracic defibrillation. BACKGROUND: Multiple studies have shown that for endocardial defibrillation, biphasic waveforms have a greater efficacy than monophasic waveforms. More recently, a 130-J truncated exponential biphasic waveform was shown to have equivalent efficacy to a 200-J damped sine wave monophasic waveform for transthoracic ventricular defibrillation. However, the optimal type of biphasic waveform is unknown. METHODS: In this prospective, randomized, multicenter trial, 184 patients who underwent ventricular defibrillation were randomized to receive a 200-J damped sine wave monophasic or 120-J rectilinear biphasic shock. RESULTS: First-shock efficacy of the biphasic waveform was significantly greater than that of the monophasic waveform (99% vs. 93%, p = 0.05) and was achieved with nearly 60% less delivered current (14 +/- 1 vs. 33 +/- 7 A, p < 0.0001). Although the efficacy of the biphasic and monophasic waveforms was comparable in patients with an impedance < 70 ohms (100% [biphasic] vs. 95% [monophasic], p = NS), the biphasic waveform was significantly more effective in patients with an impedance > or = 70 ohms (99% [biphasic] vs. 86% [monophasic], p = 0.02). CONCLUSIONS: This study demonstrates a superior efficacy of rectilinear biphasic shocks as compared with monophasic shocks for transthoracic ventricular defibrillation, particularly in patients with a high transthoracic impedance. More important, biphasic shocks defibrillated with nearly 60% less current. The combination of increased efficacy and decreased current requirements suggests that biphasic shocks as compared with monophasic shocks are advantageous for transthoracic ventricular defibrillation.

Effects of adenosine A1-receptor activation on torsade de pointes in rabbits.

PURPOSE: We tested whether the adenosine A1 receptor agonist, R-PIA, suppressed torsade de pointes (TdP) induced by the delayed rectifier potassium channel blocker clofilium. Furthermore, we studied the underlying mechanism: beta-adrenergic antagonism or ATP-sensitive K+ channel (IK-ATP) opening. METHODS: In anesthetized rabbits, TdP was induced by simultaneous infusion of clofilium and the alpha1-adrenoceptor agonist methoxamine. Four groups were studied: (1) saline infusion after TdP induction; (2) R-PIA (1.3 mg/kg) infusion; (3) R-PIA infusion after propranolol (2 micromol/kg) pretreatment; (4) R-PIA infusion after glibenclamide (10 micromol/kg) pretreatment. RESULTS: TdP suppression rate was 0% in group 1, 78% in group 2 (p<0.01 vs. group 1), 67% in group 3 (p<0.05 vs. group 1, p = NS vs. group 2), 33% in group 4 (p = NS vs. group 1, p = 0.08 vs. group 2). TdP induction coincided with increased QT/QTc duration and QT dispersion. TdP suppression coincided with reduced QT dispersion, but further QT/QTc lengthening. CONCLUSIONS: R-PIA suppressed TdP, not by beta-adrenergic antagonism, but mostly by IK-ATP opening. QT dispersion correlated better with TdP induction/suppression than QT/QTc duration.

Effect of adenosine and verapamil in catecholamine-induced accelerated atrioventricular junctional rhythm: insights into the underlying mechanism.

Accelerated AV junctional rhythm is postulated to be due to enhanced automaticity of a high AV junctional focus. The adenosine response of this rhythm was tested in 17 patients (7 males, 12-83 years). The indications of electrophysiology study were nonspecific palpitation (n = 5), unexplained syncope (n = 6), postablation of accessory pathways (n = 4), and postmodification of AV nodal reentry tachycardia (n = 2). The sinus node and AV nodal functions were normal. Pacing and programmed electrical stimulation failed to induce any arrhythmia at baseline. The accelerated junctional rhythm (cycle length = 553 +/- 134 ms) was initiated spontaneously in all patients after isoproterenol infusion (1-2 micrograms/min). It was not suppressible by overdrive pacing. Cessation of isoproterenol infusion terminated the rhythm in all patients. Adenosine (6 mg) reproducibly terminated the accelerated junctional rhythm in all patients. In six patients, adenosine suppressed the junctional rhythm without producing AV nodal block. In the other 11 patients, the junctional rhythm was terminated prior to the occurrence of AV nodal block. Verapamil was tested in ten patients and 5 mg of intravenous verapamil terminated the junctional rhythm in all patients. In conclusion, the mechanism of catecholamine-induced accelerated AV junctional rhythm is most likely enhanced automaticity, and catecholamine-induced accelerated AV junctional automaticity is sensitive to adenosine and verapamil. Adenosine appears to have differential effects on catecholamine-enhanced AV junctional automaticity and AV nodal conduction. This suggests that, under catecholamine stimulation, adenosine may have different mechanisms of action on AV nodal conduction and automaticity.

KN-93, an inhibitor of multifunctional Ca++/calmodulin-dependent protein kinase, decreases early afterdepolarizations in rabbit heart.

The multifunctional Ca++/calmodulin-dependent protein kinase II (CaM kinase) mediates Ca++-induced augmentation of L-type Ca++ current (ICa); therefore it may act as a proarrhythmic signaling molecule during early afterdepolarizations (EADs) due to ICa. To investigate the hypothesis that ICa-dependent EADs are favored by CaM kinase activation EADs were induced with clofilium in isolated rabbit hearts. All EADs were rapidly terminated with ICa antagonists. Hearts were pretreated with the CaM kinase inhibitor KN-93 or the inactive analog KN-92 (0.5 microM) for 10 min before clofilium exposure. EADs were significantly suppressed by KN-93 (EADs present in 4/10 hearts) compared to KN-92 (EADs present in 10/11 hearts) (P =.024). There were no significant differences in parameters favoring EADs such as monophasic action potential duration or heart rate in KN-93- or KN-92-treated hearts. CaM kinase activity in situ increased 37% in hearts with EADs compared to hearts without EADs (P =.015). This increase in CaM kinase activity was prevented by pretreatment with KN-93. In vitro, KN-93 potently inhibited rabbit myocardial CaM kinase activity (calculated Ki 100 microM). The actions of KN-93 and KN-92 on ICa and other repolarizing K+ currents did not explain preferential EAD suppression by KN-93. These data show a novel association between CaM kinase activation and EADs and are consistent with the hypothesis that the ICa and CaM kinase activation both contribute to EADs in this model.

Demonstration of a posterior atrial input to the atrioventricular node during sustained anterograde slow pathway conduction.

OBJECTIVES: This study sought to demonstrate electrophysiologic evidence for the existence of different anatomic atrial input sites of fast and slow conduction pathways in patients with dual atrioventricular (AV) node physiology. BACKGROUND: Although a separate posterior exit site exists for a retrograde slow AV node pathway, it remains unresolved whether a separate atrial input site into the AV node actually exists in patients with dual anterograde AV node pathway physiology. METHODS: In 10 patients with dual AV node pathway physiology, atrial pacing at three chosen drive cycle lengths (DCL1, DCL2 and DCL3) was performed at an anterior site (A) just above the His bundle recording site and at a posterior atrial site (P) just below the coronary sinus ostium. DCL3 was chosen as the one cycle length that resulted in a long AH interval consistent with slow pathway conduction. The stimulus to His bundle conduction times (SH) at both sites (SH(P) and SH(A), respectively) and their differences (deltaSH = SH(P) - SH(A)) at each of the three drive cycle lengths were analyzed. RESULTS: The mean +/- SD deltaSH values for DCL1 and DCL2 measured 9 +/- 16 and 8 +/- 18 ms, respectively, and the mean deltaSH value at DCL3 measured -34 +/- 24 ms, which was significantly different from the mean deltaSH values at DCL1 and DCL2 (both p < 0.05). CONCLUSIONS: The significant change in the deltaSH (SH(P) - SH(A)) value during slow pathway conduction could be accounted for by a corresponding shift of anterograde input from an anterior to a posterior entry site to the AV node. These findings support the notion that a separate anterograde entry site of the slow pathway does exist in patients with dual AV node pathway physiology.

Multiple atrioventricular nodal pathways in humans: electrophysiologic demonstration and characterization.

INTRODUCTION: Multiple AV nodal pathway physiology can be demonstrated in certain patients with clinical AV reentrant tachycardia. METHODS AND RESULTS: Evidence suggesting multiple AV nodal pathway conduction was present in seven (two males; age range 15 to 75 years) of 78 patients (9%) who underwent electrophysiologic studies for AV nodal tachycardia. The presence of two discrete discontinuities in the AV nodal conduction curves suggested triple AV nodal pathway conduction. Detailed mapping of their retrograde atrial activation sequence was performed along the tricuspid annulus from the coronary sinus ostium to the His-bundle electrogram recording site. Three zones (anterior, middle, and posterior) correspond to the upper, middle, and lower third of the triangle of Koch, respectively. The fast pathway exits were determined as anterior (4/7) or middle (3/7), the intermediate pathway exits as middle (4/7) or posterior (3/7), and the slow pathway exits as middle (1/7) or posterior (6/7). Other evidence suggesting multiple AV nodal pathway conduction includes: (1) triple ventricular depolarizations from a single atrial impulse; (2) sequential dual ventricular echoes; (3) spontaneous transformation between the slow-fast and fast-slow forms of AV nodal reentrant tachycardia; and (4) persistent cycle length alternans during AV nodal reentrant tachycardia. In four patients, all three pathways were shown to be involved in AV nodal echoes or reentrant tachycardia. CONCLUSION: Multiple AV nodal pathways are not uncommon and can be identified by careful electrophysiologic elucidation and mapping technique.

The role of intravenous amiodarone in the management of cardiac arrhythmias.

PURPOSE: To review the electropharmacology, clinical applications, side effects, and hemodynamic profile of intravenous amiodarone. DATA SOURCES: The MEDLINE database was searched for English-language material, including reports of clinical trials and in vivo studies, review articles, and abstracts presented at national symposia, that was published between 1985 and 1996. Bibliographies of textbooks and articles were also examined. STUDY SELECTION: Studies that reported on the efficacy, toxicity, and hemodynamic profile of intravenous amiodarone and studies that examined the pharmacologic behavior of intravenous amiodarone in laboratory models were reviewed. DATA EXTRACTION: Study design and quality and relevant data on efficacy of suppression and treatment of arrhythmias with oral and intravenous amiodarone therapy, the reported mechanisms of antiarrhythmic effect, and hemodynamic changes seen with therapy were analyzed. DATA SYNTHESIS: Amiodarone is a unique antiarrhythmic agent that is now available in oral and intravenous forms in the United States. The use of intravenous amiodarone in the short-term treatment of life-threatening or hemodynamically unstable rhythm disturbances has generated much interest. Amiodarone has many electropharmacologic actions, some of which differ between the oral and intravenous forms. The wide clinical application of amiodarone includes treatment and prevention of supraventricular and ventricular arrhythmias and arrhythmias related to myocardial infarction. Intravenous amiodarone is effective for supraventricular and ventricular arrhythmias that are resistant to other antiarrhythmic agents. The effectiveness of intravenous amiodarone as short-term treatment also suggests that the drug has an important role in protocols of advanced cardiac life support. Intravenous amiodarone seems to have an overall favorable hemodynamic profile and does not produce many of the unwanted long-term side effects associated with oral therapy. CONCLUSION: Intravenous amiodarone shows much promise for the short-term treatment of unstable arrhythmias. Its favorable hemodynamic effects and minimal short-term side effects make it an attractive option in the management of cardiac arrhythmias.

Intracoronary arterial occlusion: a novel technique potentially useful for ablation of cardiac arrhythmias.

To develop a new technique for ablating arrhythmias by interrupting coronary perfusion of the myocardium, we studied six mongrel dogs, weighing 20-35 kg. Under angiographic guidance a microcatheter (1.0 mm diameter) was introduced into a branch of the left anterior descending or posterior descending coronary artery. A detachable platinum coil (0.0254 cm diameter, 3 cm length) soldered onto a stainless-steel delivery wire (Guglielmi) was inserted through the microcatheter and advanced to occlude the arterial branch. A 0.5-mA electric current applied to the proximal end of the delivery wire resulted in intravascular thrombosis due to attraction of the negatively charged blood cells, platelets, and fibrinogen to the positively charged platinum coil. In approximately 4.5 minutes, as the thrombus was formed, electric current dissolved the soldering and detached the platinum coil from the delivery wire. Electrocardiograms showed focal ST-T changes but no ventricular tachyarrhythmias. Pathologic studies revealed thrombosis around the platinum coil and well-demarcated focal ischemia/infarction that was correlated with elevation of cardiac enzymes. We conclude that intracoronary arterial embolization and electrothrombosis using an electrolytic platinum coil can be selectively performed in a very small coronary arterial branch, resulting in a limited area of myocardial damage. This technique is potentially useful for ablating arrhythmias and may be safer and more controllable than intracoronary alcohol infusion.

Clinical efficacy of propantheline bromide in neurocardiogenic syncope: pharmacodynamic implications.

The pharmacological response with tilt-table testing predicts long-term efficacy in neurocardiogenic syncope. However, beta-blockers for neurocardiogenic syncope are often not tolerated or are ineffective. Since cholinergic tone is important in the efferent part of the neurocardiogenic reflex, we investigated the pharmacodynamics and efficacy of propantheline bromide in preventing neurocardiogenic syncope. We studied 16 patients (11 males) with a mean age of 48.8 (+/- 15.1) years with presyncope or syncope and who had positive baseline tilt-table studies at a mean of 15.8 (+/- 10.3) minutes into the upright 60 degrees tilt. They were given propantheline bromide orally, an anticholinergic agent, at a dose of 64.3 (+/- 21.8) mg/day for 7 days, and tilt-table testing was repeated 1 hour after readministration of propantheline bromide, 30 mg orally. After propantheline bromide treatment, 13 of 16 patients (81%) had no inducible presyncope or syncope on repeat tilt-table testing. In this group of responders, the mean minimum heart rate during upright tilt-table testing increased from 43.2 (+/- 77.3) beats/min to 77.3 (+/- 17.2) beats/min after propantheline bromide (p < 0.005). More significantly, the minimum mean arterial blood pressure increased from 42.2 (+/- 25) mmHg to 81.3 (+/- 16.7) mmHg (p < 0.0005) during upright tilt. At a follow-up of 15.2 (+/- 7.4) months, in the responder group (12 patients with long-term follow-up), the average dose of propantheline bromide was 32.5 (+/- 23.8) mg/day, which was significantly reduced from the initial dose (p < 0.05). A clinical recurrence of symptoms occurred in only 4 out of 12 patients on propantheline bromide (33%), none of which were directly attributable to drug failure. It was concluded from this study that propantheline bromide is highly effective in preventing neurocardiogenic syncope. In addition, propantheline bromide's effectiveness is more than would be expected by prevention of cardioinhibition in neurocardiogenic syncope and would support a role for direct cholinergic control of vascular tone.