Atrial Fibrillation Clinical Trial
Official title:
Cavotricuspid Isthmusblock and Circumferential Pulmonary Vein Isolation in Patients With Atrial Fibrillation
Atrial fibrillation (AF) is the most common cardiac arrhythmia. Pulmonary vein isolation
(PVI) in the left atrium using radiofrequency energy is a new and promising non-medical
treatment in patients with symptomatic AF with reported success rates of 65 % to 90 %
depending on AF classification and ablation procedure. However, the risk of recurrence has
led to suggestions of how to improve the clinical outcome by tailoring a more efficient
ablation procedure. A prospective, randomised study with 150 patients with symptomatic AF
referred for PVI has been initiated and patients are allocated to PVI alone (75 patients) or
PVI with additional ablation in the right atrium (75 patients). Patients undergo extensive
monitoring of the heart rhythm during follow-up to document symptomatic or asymptomatic AF
or atrial flutter. The presence of asymptomatic AF after PVI could potentially affect the
management of the anticoagulation therapy in these patients. The structural and functional
changes in the atria after PVI is characterized by new imaging techniques (Tissue Doppler
Imaging(TDI))of the atria and cardiac neurohormones. TDI may be an effective tool for
characterising changes in the left atrial function after PVI. Neurohormones may provide new
information regarding the changes in left atrial function and clinical outcome after PVI in
patients with AF.
We hypothesize that:
- Among patients with predominant atrial fibrillation, PVI with additional ablation in
the right atrium is associated with better outcome, i.e. freedom of symptomatic
AF/atrial flutter overall.
- Asymptomatic AF and atrial flutter occur frequently after PVI.
- Left atrial volume and systolic function correlates to AF recurrence after PVI.
- Neurohormones levels correlates to AF recurrence after PVI.
BACKGROUND:
Atrial fibrillation (AF) is the most common cardiac arrhythmia. Medical treatment is often
inefficient or associated with side effects. Pulmonary vein isolation (PVI) in the left
atrium using radiofrequency energy is a new and promising non-medical treatment in patients
with symptomatic AF with reported success rates of 65 % to 90 % depending on AF
classification and ablation procedure (1).
Circumferential PVI appears to be the superior ablation technique in patients with AF (2).
However, the risk of recurrence has led to suggestions of how to improve the clinical
outcome by tailoring a more efficient ablation procedure. Patients with AF often have
coexisting atrial flutter (3), but it is uncertain if patients referred for PVI can benefit
from additional cavotricuspid isthmusblock (CTI) which is the traditional ablation treatment
of atrial flutter. A recent study indicates that PVI reduces both AF and atrial flutter by
eliminating sharing triggers in the pulmonary veins (4). Other investigators showed that
patients with AF and atrial flutter prior or during PVI had high risk of recurrent atrial
flutter during follow-up, and that successful PVI did not reduce the risk of recurrent
atrial flutter (3). The current approach in our lab is to perform additional CTI in cases of
documented atrial flutter, but CTI may potentially improve the overall outcome (freedom of
symptomatic arrhythmia) in patients without documented atrial flutter, especially since most
symptomatic periods are undocumented.
A prospective, randomised study with 150 patients with symptomatic AF referred for PVI has
been initiated and patients are allocated to PVI alone (75 patients) or PVI with additional
CTI (75 patients). Patients undergo extensive Holter monitoring during follow-up to document
symptomatic or asymptomatic AF or atrial flutter. Patients with AF have a high incidence of
asymptomatic AF which correlates to an increased risk of tromboembolic complications (5).
The presence of aymptomatic AF after PVI could potentially affect the management of the
anticoagulation therapy in these patients.
The structural and functional changes in the atria after PVI have been described in few
studies. To our knowledge, Tissue Doppler Imaging (TDI) and neurohormones (NT-pro-BNP and
ANP) have not previously been used in characterising the left atrial function after PVI. New
echocardiographic modalities such as TDI have been introduced in the characterisation of the
left ventricle systolic function in ischemic heart disease and congestive heart failure. TDI
has been used for characterising the global and segmental atrial systolic function in
healthy individuals (6), and TDI may be an effective tool for characterising changes in the
left atrial function after PVI.
Neurohormones are produced in the left ventricle/atrium, and patients with AF have elevated
levels due to atrial stretch. Cardioversion from AF to sinus rhythm is associated with
normalisation of the BNP/ANP levels (7), and BNP is an independent risk factor of developing
AF in patients with mild congestive heart failure (8). Neurohormones may therefore provide
new information regarding the changes in left atrial function and clinical outcome after PVI
in patients with AF.
PURPOSE:
- To investigate the effect of additional cavotricuspid isthmusblock in patients with AF
referred for circumferential pulmonary vein isolation.
- To investigate the incidence of asymptomatic AF and atrial flutter after ablation by
extensive Holter monitoring.
- To characterise left atrial volume and function before and after PVI by
echocardiographic assessment (TDI) and measurements of neurohormones (NT-pro-BNP and
ANP).
HYPOTHESIS:
- Among patients with predominant AF, PVI with additional cavotricuspidal isthmusblock is
associated with better outcome, i.e. freedom of symptomatic AF/atrial flutter overall.
- Asymptomatic AF and atrial flutter occur frequently after PVI.
- Left atrial volume and systolic function correlates to AF recurrence after PVI.
- ANP/NT-pro-BNP levels correlates to AF recurrence after PVI.
DESIGN AND MATERIALS:
A prospective, randomised study with 150 patients referred to PVI due to symptomatic
paroxysmal or persistent AF. Patients are randomised to circumferential PVI with (75
patients) or without (75 patients) cavotricuspid isthmusblock in the right atrium. Follow up
period of 12 months.
Eighty of the included patients (40 with paroxysmal and 40 with persistent AF) undergo
TDI-echocardiography and neurohormonal measurements.
METHOD:
Admission:
- History, physical examination, medication.
- Echocardiographic characterisation of left atrial function and volume and left
ventricle systolic and diastolic function (TDI in 80 patients).
- NT-pro-BNP/ANP measurements (in 80 patients).
- Questionnaire (SF-36).
- Circumferential PVI. Patients are randomised to PVI with or without cavotricuspid
isthmusblock.
Ablation:
One quadripolar 5-F catheter (St. Jude Medical) is placed in the right ventricular apex and
a decapolar catheter (Biosense Webster) in the coronary sinus. Transseptal access to the
left atrium is achieved by the use of a SL1 sheath (St. Jude Medical). Three-dimensional
maps of the left atrium are constructed with a quadripolar D-curve mapping catheter (3.5-mm
Navistar, Biosense Webster) with the use of a non-fluoroscopic navigation system (CARTO,
Biosense-Webster). Patients are heparinized using an initial dose of 100 IE/kg with an
additional 1000 IE/hour. Radiofrequency energy is delivered via the 4-mm mapping catheter.
Ablation lines are deployed circumferentially around the pulmonary veins (PV) approximately
0.5 cm from the ostia. After ablation, remapping is performed during sinus rhythm or pacing
from the coronary sinus. In case of AF during ablation, patients are cardioverted to sinus
rhythm before remapping. The criteria of successful ablation is the elimination of
potentials > 0.1 mV within the lesions determined by voltage maps.
Ultimately, the cavotricuspid ishtmusblock is performed with the ablation catheter. The
position of the catheter is established using fluoroscopy or CARTO-mapping. Ishtmusblock is
verified by double potentials during coronary sinus (CS) pacing, an activation detour by
pacing either side of the line, and differential pacing techniques.
Follow-up:
- 24 hours heart rhythm monitoring.
- Clinical control after 3,6 and 12 months
- 1 week Holter monitoring after 3, 6 and 12 months
- NT-pro-BNP/ANP measurements after 3 and 12 months
- Echocardiography after 3 and 12 months 2D Echocardiography M-mode of the left ventricle
and atrium in parasternal view Left atrium enddiastolic and endsystolic volume using
Simpson biplane in apical 4 and 2-chamber view Left ventricle enddiastolic and
endsystolic volume using Simpson biplane in apical 4 and 2-chamber view Color M-mode
Transmitral flow (Pulsed Wave Doppler) E- og A-peak velocity, E/A ratio og
E-decelerationtime Atrial emptying fraction = A velocity time integral (VTI)/total
velocity time integral (VTI)
Tissue Doppler echocardiography (TDI) Segmental atrial velocity and amplitude of right and
left atrium Framerate over 100 fps
Five points in the apical 4-chamber projection:
- 2 in the right atrium (lateral annular and superior)
- 3 in the left atrium (septal annular, superior and lateral annular) Three points in the
apical 2 chamber view in the left atrium (posterior annular, superior and annular
anterior)
STATISTICS:
The sample size is calculated on the basis of the following assumptions:
A type 1 error and type 2 error of 5 % and 20 %, respectively, are accepted. The statistical
power is 80%. Thirty-five percent of patients with AF had coexisting atrial flutter in a
population who were referred to PVI (3). Patients undergoing CTI due to atrial flutter have
10 % risk of recurrence. During follow-up, 90 % versus 70 % (without CTI) of the patients
are expected to be free of symptoms related to atrial flutter. Based on these parameters,
the sample size is 72 patients included in each group. Overall, 150 patients are included
due to expected loss of patients during follow-up.
In 2003, ninety-five patients were treated with PVI in Skejby Hospital which has increased
to 150 patients in 2004. The production is expected to increase further during the following
years.
PRACTICAL CONSIDERATIONS:
The PhD protocol has been approved by The Faculty of Health Science at the University of
Aarhus and the Local Committee of Ethics in Aarhus. The study was initiated in December 2004
and at he moment 8 patients have been included. The Institute of Clinical Experimental
Research at the University Hospital of Aarhus has donated 6 months salary to Dr. Jacob
Pontoppidan.
The inclusion period is 12 months. Patients are followed 12 months. Finally, 12 months are
expected for dataprocessing and publications. At least 3 publications in international
peer-reviewed journals are expected.
The measurements of neurohormones are performed by the Department of Clinical Biochemistry
and the biochemical laboratory at the Department of Nephrology, Skejby Hospital. The
echocardiographic analyses including TDI are performed by Dr. Pontoppidan, who is
experienced in this technique. The electrophysiologists in the Department of Cardiology,
Skejby University Hospital of Aarhus, perform the ablation procedures as described above.
;
Allocation: Randomized, Endpoint Classification: Efficacy Study, Intervention Model: Parallel Assignment, Masking: Open Label, Primary Purpose: Treatment
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