Different Catheter Ablation Strategy in Vasovagal Syncope: A Single Center, Prospective, Randomized Study

Description

Vasovagal syncope (VVS) is the most common syncope type in clinic, but routine therapy shows no benefits. Cardiac nerve ablation affects the function of cardiovascular system by accurately mapping and ablation of cardiac autonomic ganglion plexus and adjusting cardiac sympathetic-vagal balance. The existing clinical evidence is mostly exploratory or registered clinical studies, and the sample size is small. This study intends to adopt a prospective, randomized controlled study to compare the efficacy of simple left atrial ganglion plexus ablation and left atrial ganglion plexus ablation combined with right atrial ganglion plexus ablation in the treatment of VVS, and to establish the relevant cardiac nerve ablation standards.

This study is a prospective, single-center randomized controlled clinical trial. patients with refractory vasovagal syncope were randomly divided into two groups according to the proportion of 1:1. Group A: simple left atrial ganglion plexus ablation (RAGP + LSGP + LLGP + LIGP + RIGP ablation); B group: left atrial ganglion plexus combined with right atrial ganglion plexus ablation (group A + consolidation ablation of RAGP at the junction of right atrial septum and superior vena cava).

Atrial modeling was established under the guidance of Ensite three-dimensional mapping system, and then MicroPace EPS 320 was used to stimulate and induce the main distribution areas of autonomic ganglia. The high frequency stimulation mode is set as follows: the stimulation frequency is 20 Hz, the voltage is 10 to 20 volts, and the pulse width is 5 milliseconds. The main sites of high frequency stimulation include: the left superior pulmonary vein and the left atrial posterior wall of LSGP, the left inferior pulmonary vein orifice of LIGP, the LLGP, around the right inferior pulmonary vein orifice, the RIGP, around the right superior pulmonary vein and the left atrial junction of the right superior pulmonary vein, the right atrial septum of RAGP, and the superior vena cava junction to stimulate RAGP. Ganglion localization standard: locate the site of vagal response (ventricular arrest, atrioventricular block, RR interval prolongation at least 50%) after high frequency stimulation, and mark it in the three-dimensional model.

Under the guidance of three-dimensional system, the located ganglion plexus was ablated with saline irrigating electrode. The upper limit of power was 40W, the upper limit of temperature was 43 ℃, and the washing rate of saline was 17ml/min. The site of vagal reaction during ablation was defined as the effective ablation site . Denervated interventional therapy. The surgical end point of the treatment was defined as the disappearance of vagal response at the effective ablation site or the ablation of each effective point discharge for at least 30 seconds. Cardiac electrophysiological parameters such as heart rate, AH interval, HV interval, recovery time of sinoatrial node, Wenckebach point of atrioventricular conduction and atrioventricular conduction refractory period were measured before and after ablation.

The patients were followed up at 3 months, 6 months, 12 months and 24 months respectively after ablation procedure, to observe whether there were recurrent syncope and /or pre-syncope (including the time and frequency of recurrent syncope, inducing factors, and whether complicated with fall injury, etc.), and to reassessed tilt test, 24-hour ambulatory electrocardiogram and fill in Short Form-36 (SF-36) and Euroqol (EQ-5D) quality of life score form. To evaluate the safety and efficacy of cardiac nerve ablation in the prevention of refractory vasovagal syncope. The tilt test, the changes of vagus nerve function and the improvement of quality of life before and after were analyzed and compared. To evaluate the efficacy and safety of cardiac nerve ablation strategies, and to explore the role and optimization of RAGP in cardiac nerve ablation.

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