Atrial Fibrillation Clinical Trial
Official title:
Circumferential vs Ganglionated Plexi Ablation in Patients With Paroxysmal Atrial Fibrillation: A Randomized Study
The investigators have recently shown that anatomic ganglionated plexi (GP) ablation is inferior to circumferential pulmonary vein (PV) ablation for the treatment of paroxysmal AF. In this study, however, 26% of patients subjected to GP ablation alone without circumferential lesions were free of AF-recurrence up to one year after the ablation procedure. The investigators hypothesized that a combination of circumferential ablation with high-frequency-stimulation-identified GP ablation is superior to conventional circumferential ablation for the prevention of recurrences of paroxysmal atrial fibrillation (AF). The investigators are, therefore, conducting a randomized study comparing conventional circumferential ablation to a combination of circumferential ablation plus specific right and left atrial GP ablation in patients with drug-refractory paroxysmal AF.
Introduction:
In clinical studies, epicardial or endocardial partial ganglionated plexi (GP) ablation may
prevent AF,1-4 and parasympathetic denervation has been proposed as a potential mechanism of
circumferential or antral pulmonary vein (PV) ablation for the treatment of atrial
fibrillation.5,6 However, there have also been reports of a temporary only 7 or even
proarrhythmic effect of this approach by means of increased vulnerability of
vagally-mediated AF,8,9 or ablation-related macro-reentrant left atrial tachycardias.10
Thus, the potential contribution of GP modification to clinical success of circumferential
or antral pulmonary vein ablation that unavoidably affects adjacent GP is not known. Few
publications exist on isolated GP ablation with variable results in terms of eliminating
paroxysmal or persistent AF.11-13 We have recently shown that anatomically-oriented regional
ablation at the areas of GP is superior to selective GP ablation, following identification
of GP by high-frequency stimulation, conferring success rates comparable to these of
pulmonary vein (PV) isolation procedures.13 We hypothesized that GP ablation guided by both
HF stimulation and anatomical orientation is superior to PV isolation in patients with
paroxysmal AF. We also aimed at comparing these two approaches with a combination of GP
ablation and PV isolation. We are, therefore, conducting a randomized study comparing the
three techniques in patients with drug-refractory paroxysmal AF.
Methods:
Patients with symptomatic, paroxysmal AF were randomized to three groups:
Group 1. Patients are subjected to conventional PV isolation through circumferential
ablation 1-2 cm from the PV ostium.
Group 2. Patients are subjected to specific, HF stimulation-guided and anatomic ablation of
the main right and left atrial GP.
Group 3. Patients are subjected to specific, HF stimulation-guided and anatomic ablation of
the main right and left atrial GP followed by PV isolation.
Group 1. PV isolation. Circumferential ablation around the antra of the PV with the aid of
electroanatomical mapping (Carto, Biosence-Webster) at a distance of approximately 1-2 cm
from the ostia of the left and right PVs (46°C, 35W, 17 mL/min, Stockert, Biosense Webster),
aimed at a voltage reduction by > 80% or a peak to peak bipolar electrogram <0.1 mV.
End-point of both approaches is verification of PV isolation with demonstration of entry and
exit block. The area encircled by circumferential ablation will be calculated using the
software provided by the CARTO system.
Group 2. GP ablation. The anatomic areas of GP are identified in the right and left atrium.
Anatomic locations of GP were considered around the PV: anterior right (ARGP), inferior
right (IRGP), left superior (LSGP), and left inferior GP (LIGP). In addition the following
GP were considered: The GP at the crux of the left atrium which is probably near or in
continuation with the IRGP (2-3 cm below the lower edge of RIPV), expanding both toward the
mitral annulus and inferior aspect of the LA posterior wall (cruxGP). This GP was also
approached from the crux of the RA, behind the tendon of Tadaro/Eustachian ridge and the
coronary sinus ostium. The GP at the septal-posterior aspect of the junction of the RA with
the SVC (this GP may actually correspond to the 3rd fat pad located at the junction of
SVC-RA-right PA-aorta).14-18 Following anatomic orientation, precise determination of the
location of parasympathetic GP is accomplished by high-frequency stimulation.19 Patients are
deeply sedated with diamorphine and diazepam without intubation, and high-frequency
stimulation is delivered with a Grass stimulator at 1,200 bpm (20 Hz) with a pulse width of
10 ms at 20 V. A predominant parasympathetic response is defined as induction of AV block (>
2 sec) and hypotension or prolongation of the R-R interval by >50% during AF, following a 5
seconds application of high-frequency stimulation.19 Before applying high-frequency
stimulation to inferior GP, extra care is taken to ensure that the catheter tip is not on
the annulus to avoid induction of ventricular fibrillation. Verification of catheter
position is accomplished by examination of recorded electrograms and anatomic location on
both lateral views on CARTO. The sequence of GP ablation is: LS GP, LI GP, ARGP GP, IRGP,
right anterior GP and the crux GP situated in the RA. After each ablation lesion (46°C, 35W
for 60 seconds, 17 mL/min), parasympathetic response is reassessed by high-frequency
stimulation. End-point for radiofrequency delivery is abolition of parasympathetic response.
Following specific GP ablation, anatomical ablation is performed as previously described, in
a way that the designated anatomic areas of GP are ablated.
Group 3. GP ablation and PV isolation. Following specific and anatomic GP ablation as
previously described, PV isolation is accomplished either by circumferential or antral
ablation.
At the end of the ablation procedure in both groups, AF or atrial flutter induction is
attempted by isoproterenol infusion and high left atrial pacing. Induction of atrial
fibrillation is registered but does not necessitate additional ablation. Induction of right,
isthmus-dependent atrial flutter is dealt with cavotricuspid isthmus ablation. Left atrial
flutters will be studied by means of entrainment from the mitral isthmus and the adjacent
posterior wall. Since a considerable percentage of these arrhythmias disappear with time,20
they will be ablated only if sustained (> 3 minutes) and associated with 1:1 ventricular
response.
Follow-up. Patients will be prospectively assessed for recurrence of AF or other atrial
arrhythmia. As part of our routine AF ablation protocol, all patients are receiving beta
blockers, whereas all patients are kept on amiodarone and warfarin for 3 months
post-ablation. Patients will be subjected to monthly clinical assessment and ambulatory
electrocardiographic monitoring for 2 years. All patients are instructed to maintain
personal records with descriptions of every episode of symptomatic palpitations and, in case
of persistent arrhythmia episodes, to obtain trans-telephonic or electrocardiographic
documentation of the underlying rhythm. Patients will be encouraged to use trans-telephonic
monitoring even when their symptoms are not typical for recurrent AF. A successful outcome
over the follow-up period is defined as the lack of electrocardiographically recorded AF,
and no AF or other atrial arrhythmia on Holter, and subjective symptomatic improvement after
a 3-month blanking period.
Heart rate variability will be measured at 6, 12, 18 and 24 months after ablation.
;
Allocation: Randomized, Endpoint Classification: Safety/Efficacy Study, Intervention Model: Factorial Assignment, Masking: Open Label, Primary Purpose: Treatment
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