Atrial fibrillation catheter ablation

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: Cafer Zorkun, M.D., Ph.D. [2] Vendhan Ramanujam M.B.B.S [3]

Overview

In patients with atrial fibrillation where rate control drugs are ineffective and it is not possible to restore sinus rhythm using cardioversion, non-pharmacological alternatives are available. One of the techniques used is called as catheter ablation, where the bundle of cells that pace the heart in the atrioventricular node, are destroyed using radiofrequency energy source, the dominant energy source for catheter ablation. Cryoablation has more recently been developed as a tool for AF ablation procedures.[1] Balloon-based ultrasound ablation and laser based ablation systems have also been developed for AF ablation.[2][3][4][5] Other energy sources and tools are in various stages of development and/or clinical investigation.

Indications for Catheter and Surgical Ablation

Ablation of atrial fibrillation is recommended when the primary indication is the presence of symptomatic AF, which is refractory or intolerant to at least one class I or III antiarrhythmic medication. The indications are stratified as class I, class IIa, class IIb, and class III indications.[6]

Class I Indications

In symptomatic paroxysmal AF patients who are either refractory or intolerant to at least one class I or III antiarrhythmic medication, catheter ablation is recommended.

Class IIa Indications

  • In symptomatic persistent AF patients who are either refractory or intolerant to at least one class I or III antiarrhythmic medication, catheter ablation is reasonable.
  • In symptomatic paroxysmal AF patients, prior to initiation of antiarrhythmic drug therapy with either class I or III antiarrhythmic agent, catheter ablation is reasonable.
  • In patients who are undergoing surgery for other indications with symptomatic paroxysmal AF, refractory or intolerant to at least one class I or III antiarrhythmic medication, surgical ablation is reasonable.
  • In patients who are undergoing surgery for other indications with symptomatic persistent AF, refractory or intolerant to at least one class I or III antiarrhythmic medication, surgical ablation is reasonable.
  • In patients who are undergoing surgery for other indications with symptomatic longstanding persistent AF, refractory or intolerant to at least one class I or III antiarrhythmic medication, surgical ablation is reasonable.
  • In patients who are undergoing surgery for other indications with symptomatic paroxysmal AF prior to initiation of antiarrhythmic drug therapy with either class I or III antiarrhythmic agent, surgical ablation is reasonable.
  • In patients who are undergoing surgery for other indications with symptomatic persistent AF prior to initiation of antiarrhythmic drug therapy with either class I or III antiarrhythmic agent, surgical ablation is reasonable.

Class IIb Indications

  • In symptomatic longstanding persistent AF patients who are either refractory or intolerant to at least one class I or III antiarrhythmic medication, catheter ablation may be considered.
  • In patients with symptomatic persistent AF prior to initiation of antiarrhythmic drug therapy with a class I or III antiarrhythmic medication, catheter ablation may be considered.
  • In patients with symptomatic longstanding persistent AF prior to initiation of antiarrhythmic drug therapy with a class I or III antiarrhythmic medication, catheter ablation may be considered.
  • In patients who are undergoing surgery for other indications with symptomatic longstanding persistent AF prior to initiation of antiarrhythmic drug therapy with a class I or III antiarrhythmic agent, surgical ablation may be considered.
  • In symptomatic paroxysmal AF patients who are either refractory or intolerant to at least one class I or III antiarrhythmic medication, stand alone surgical ablation may be considered if they have not failed catheter ablation but prefer a surgical approach.
  • In symptomatic paroxysmal AF patients who are either refractory or intolerant to at least one class I or III antiarrhythmic medication, stand alone surgical ablation may be considered if they have failed one or more attempts at catheter ablation.
  • In symptomatic persistent AF patients who are either refractory or intolerant to at least one class I or III antiarrhythmic medication, stand alone surgical ablation may be considered if they have not failed catheter ablation but prefer a surgical approach.
  • In symptomatic persistent AF patients who are either refractory or intolerant to at least one class I or III antiarrhythmic medication, stand alone surgical ablation may be considered if they have failed one or more attempts at catheter ablation.
  • In symptomatic longstanding persistent AF patients who are either refractory or intolerant to at least one class I or III antiarrhythmic medication, stand alone surgical ablation may be considered if they have not failed catheter ablation but prefer a surgical approach.
  • In symptomatic longstanding persistent AF patients who are either refractory or intolerant to at least one class I or III antiarrhythmic medication, stand alone surgical ablation may be considered if they have failed one or more attempts at catheter ablation.

Class III Indications

In symptomatic paroxysmal or persistent or longstanding persistent AF patients, prior to initiation of antiarrhythmic drug therapy with a class I or III antiarrhythmic agent, stand alone surgical ablation is not recommended.

Recommendations Regarding Catheter Ablation Technique

  • The cornerstone for most AF ablation procedures are ablation strategies that target the pulmonary veins and/or pulmonary vein antrum.
  • While targeting the pulmonary veins, electrical isolation should be the goal.
  • Electrical isolation requires, at a minimum, assessment and demonstration of entrance block into the pulmonary vein.
  • Monitoring for pulmonary vein reconduction for 20 minutes following initial pulmonary vein isolation should be considered.
  • Careful identification of the pulmonary vein ostia is mandatory to avoid ablation within the pulmonary veins.
  • If a focal trigger is identified outside a pulmonary vein at the time of an AF ablation procedure, ablation of that focal trigger should be considered.
  • If additional linear lesions are applied, operators should consider using mapping and pacing maneuvers to assess for line completeness.
  • Ablation of the cavotricuspid isthmus (fibrous tissue in the lower right atrium between the inferior vena cava and the tricuspid valve) is recommended in patients with a history of typical atrial flutter or inducible cavotricuspid isthmus dependent atrial flutter.
  • If patients with long standing persistent AF are approached, operators should consider more extensive ablation based on linear lesions or complex fractionated electrograms.
  • It is recommended that radiofrequency power be reduced when creating lesions along the posterior wall near the esophagus.

Radiofrequency Ablation

To control rate it is possible to destroy the bundle of cells connecting the upper and lower chambers of the heart - the atrioventricular node - which regulates heart rate, and to implant a pacemaker instead. A more complex technique, which avoids the need for a pacemaker, involves ablating groups of cells near the pulmonary veins where atrial fibrillation is thought to originate, or creating more extensive lesions in an attempt to prevent atrial fibrillation from establishing itself.[6]

Ablation is a newer technique and has shown some promise for cases of recurrent AF that are unresponsive to conventional treatments. Radiofrequency ablation (RFA) uses radiofrequency energy to destroy abnormal electrical pathways in heart tissue. RF energy is delivered by way of a transvenous electrode catheter. The energy emitting probe (electrode) is placed into the heart through a catheter inserted into veins in the groin or neck. Electrodes that can detect electrical activity from inside the heart are also inserted, and the electrophysiologist uses these to map an area of the heart in order to locate the abnormal electrical activity before eliminating the responsible tissue. Most AF ablations consist of isolating the electrical pathways from the pulmonary veins (PV),[7] which are located on the posterior wall of the left atrium. All other veins from the body (including neck and groin) lead to the right atrium, so in order to get to the left atrium the catheters must get across the atrial septum. This is done by piercing a small hole in the septal wall. This is called a transseptal approach. Once in the left atrium, the physician may perform Wide Area Circumferential Ablation (WACA) to electrically isolate the PVs from the left atrium.[8]

Some more recent approaches to ablating AF is to target sites that are particularly disorganized in both atria as well as in the coronary sinus (CS). These sites are termed Complex Fractionated Atrial Electrogram (CFAE) sites.[9] It is believed by some that the CFAE sites are the cause of AF, or a combination of the PVs and CFAE sites are to blame. Most tissues exposed to temperatures of 50 C or higher for more than several seconds will show irreversible coagulation necrosis, and evolve into non-conducting myocardial scar. High power delivery, good electrode–tissue contact and adequate ablation duration promote the formation of larger lesions and improve procedure efficacy.

Significant complications can occur during AF ablation if high radiofrequency power is administered in an uncontrolled fashion. The increased risk of AF ablation compared to ablation of other arrhythmias may be attributed to the great surface area of tissue ablated, the large cumulative energy delivery, the risk of systemic thromboembolism, and the close location of structures susceptible to collateral injury, such as phrenic nerve, pulmonary veins, and esophagus. Thrombus, char formation and intramural steam pops can also occur. Conventional radiofrequency electrodes were employed earlier. But comparative trials against conventional radiofrequency electrodes have demonstrated that irrigated tip and large tip radiofrequency technologies have increased efficacy and decreased procedure duration.[10]

Cryoablation

Cryoablation is a new technique which uses cryothermal energy as an alternative energy source. In cryoablation, tissue freezing coolant, liquid nitrous oxide is delivered under pressure through a catheter where it changes to gas, resulting in cooling of surrounding tissue. Tissue injury results from tissue freezing with a creation of ice crystals within the cell that disrupts cell membranes and interrupts both cellular metabolism and any electrical activity in that cell. Interruption of microvascular perfusion also produces cell death by interrupting blood flow. More recently, a number of point-by-point and balloon-based cryoablation systems have been developed.[11][12] Point-by-point cryoablation approach is proved to be associated with low complication rate, but the procedure is lengthy, and the long-term efficacy is limited. This ultimately paved way for the development of a cryoablation balloon ablation catheter.

Regional blood flow around the tip of the catheter or balloon influences the achievement of optimal cryoablation. Continuous blood flow reduces the chance of achieving a fullthickness cryoablation. Because of this, complete vein occlusion is required during the procedure.

Ultrasound Ablation

Although radiofrequency ablation and cryoablation are the two standard ablation systems used for catheter ablation of AF today, balloon-based ultrasound ablation have also been developed for AF ablation. The first of the balloon ablation systems to be approved for clinical use is the focused ultrasound ablation system that uses high intensity focused ultrasound (HIFU).[13][14]

Laser Ablation

Balloon based laser ablation system involving a compliant balloon ablation catheter are being developed through which arcs of laser energy are delivered under visual guidance. Small clinical trials have demonstrated the safety and effectiveness of this ablation system, which is now approved for use in Europe and is entering a pivotal randomized clinical trial in the United States.[15][5]

Anticoagulation Strategies

AF patients are at increased risk of thromboembolism during, immediately following, and for several weeks to months after their ablation. Thus careful attention to anticoagulation of patients before, during, and after ablation for AF is important to avoid the occurrence of a thromboembolic event.

Pre Ablation

  • In patients who are in AF for 48 hours or longer or for an unknown duration, three weeks of systemic anticoagulation at a therapeutic level prior to the procedure is required.[16]
  • Prior to the ablation procedure a TEE should be performed in them.
  • TEE in patients who are in sinus rhythm at the time of ablation or patients with AF who are in AF but have also been in AF for 48 hours or less prior to AF ablation may be considered, but it is not mandatory.
  • A left atrial thrombus found during TEE is a contraindication to catheter ablation of AF.
  • Catheter ablation of AF on a patient who is therapeutically anticoagulated with warfarin should also be considered.[16]

During Ablation

  • Heparin should be administered prior to or immediately following transseptal puncture during AF ablation procedures.[17]
  • AF ablation in a patient who is systemically anticoagulated with warfarin does not alter the need for intravenous heparin to maintain a therapeutic activated clotting time (300 to 400 seconds) during the procedure.
  • Administration of protamine following ablation to reverse heparin should be considered.

Post Ablation

  • In patients who are not therapeutically anticoagulated with warfarin at the time of AF ablation, low molecular weight heparin or intravenous heparin should be used to resume the systemic anticoagulation with warfarin following AF ablation.
  • Initiation of a direct thrombin or factor Xa inhibitor after ablation may be considered as an alternative post procedure anticoagulation strategy.[18]
  • A reduction in the dose of low molecular weight heparin (0.5 mg/kg) should be considered because of the increased risk of post procedure bleeding following a full dose (1 mg/kg bid).
  • Systemic anticoagulation with warfarin or a direct thrombin or factor Xa inhibitor is recommended for at least two months following an AF ablation procedure. But decisions regarding the continuation of systemic anticoagulation for more than two months following ablation should be based on the patients risk factors for stroke. Discontinuation of systemic anticoagulation therapy post ablation is not recommended in patients who are at high risk of stroke.
  • Patients in whom discontinuation of systemic anticoagulation is being considered should consider undergoing continuous ECG monitoring to screen for asymptomatic AF.

Outcomes and Efficacy of Catheter Ablation

Efficacy and risks of catheter ablation of atrial fibrillation are areas of active debate. A worldwide survey of the outcomes of 8745 ablation procedures[19] demonstrated a 52% success rate (ranging from 14.5% to 76.5% among centers), with an additional 23.9% of patients becoming asymptomatic with addition of an antiarrhythmic medication. In 27.3% of patients, more than one procedure was required to attain these results. There was at least one major complication in 6% of patients. A thorough discussion of results of catheter ablation was published in 2007;[20] it notes that results are widely variable, due in part to differences in technique, follow-up, definitions of success, use of antiarrhythmic therapy, and in experience and technical proficiency.

Complications of Catheter Ablation

Catheter ablation of AF is one of the most complex interventional electrophysiologic procedures. Therefore the risk associated with AF ablation is higher. The following are complications associated with catheter ablation of AF.[21]

References

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  2. Meininger, GR.; Calkins, H.; Lickfett, L.; Lopath, P.; Fjield, T.; Pacheco, R.; Harhen, P.; Rodriguez, ER.; Berger, R. (2003). "Initial experience with a novel focused ultrasound ablation system for ring ablation outside the pulmonary vein". J Interv Card Electrophysiol. 8 (2): 141–8. PMID 12766506. Unknown parameter |month= ignored (help)
  3. Metzner, A.; Chun, KR.; Neven, K.; Fuernkranz, A.; Ouyang, F.; Antz, M.; Tilz, R.; Zerm, T.; Koektuerk, B. (2010). "Long-term clinical outcome following pulmonary vein isolation with high-intensity focused ultrasound balloon catheters in patients with paroxysmal atrial fibrillation". Europace. 12 (2): 188–93. doi:10.1093/europace/eup416. PMID 20089752. Unknown parameter |month= ignored (help)
  4. Neven, K.; Schmidt, B.; Metzner, A.; Otomo, K.; Nuyens, D.; De Potter, T.; Chun, KR.; Ouyang, F.; Kuck, KH. (2010). "Fatal end of a safety algorithm for pulmonary vein isolation with use of high-intensity focused ultrasound". Circ Arrhythm Electrophysiol. 3 (3): 260–5. doi:10.1161/CIRCEP.109.922930. PMID 20504943. Unknown parameter |month= ignored (help)
  5. 5.0 5.1 Metzner, A.; Schmidt, B.; Fuernkranz, A.; Wissner, E.; Tilz, RR.; Chun, KR.; Neven, K.; Konstantinidou, M.; Rillig, A. (2011). "One-year clinical outcome after pulmonary vein isolation using the novel endoscopic ablation system in patients with paroxysmal atrial fibrillation". Heart Rhythm. 8 (7): 988–93. doi:10.1016/j.hrthm.2011.02.030. PMID 21354329. Unknown parameter |month= ignored (help)
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  11. Friedman, PL.; Dubuc, M.; Green, MS.; Jackman, WM.; Keane, DT.; Marinchak, RA.; Nazari, J.; Packer, DL.; Skanes, A. (2004). "Catheter cryoablation of supraventricular tachycardia: results of the multicenter prospective frosty trial". Heart Rhythm. 1 (2): 129–38. doi:10.1016/j.hrthm.2004.02.022. PMID 15851143. Unknown parameter |month= ignored (help)
  12. Tse, HF.; Reek, S.; Timmermans, C.; Lee, KL.; Geller, JC.; Rodriguez, LM.; Ghaye, B.; Ayers, GM.; Crijns, HJ. (2003). "Pulmonary vein isolation using transvenous catheter cryoablation for treatment of atrial fibrillation without risk of pulmonary vein stenosis". J Am Coll Cardiol. 42 (4): 752–8. PMID 12932615. Unknown parameter |month= ignored (help)
  13. Metzner, A.; Chun, KR.; Neven, K.; Fuernkranz, A.; Ouyang, F.; Antz, M.; Tilz, R.; Zerm, T.; Koektuerk, B. (2010). "Long-term clinical outcome following pulmonary vein isolation with high-intensity focused ultrasound balloon catheters in patients with paroxysmal atrial fibrillation". Europace. 12 (2): 188–93. doi:10.1093/europace/eup416. PMID 20089752. Unknown parameter |month= ignored (help)
  14. Neven, K.; Schmidt, B.; Metzner, A.; Otomo, K.; Nuyens, D.; De Potter, T.; Chun, KR.; Ouyang, F.; Kuck, KH. (2010). "Fatal end of a safety algorithm for pulmonary vein isolation with use of high-intensity focused ultrasound". Circ Arrhythm Electrophysiol. 3 (3): 260–5. doi:10.1161/CIRCEP.109.922930. PMID 20504943. Unknown parameter |month= ignored (help)
  15. Dukkipati, SR.; Neuzil, P.; Skoda, J.; Petru, J.; d'Avila, A.; Doshi, SK.; Reddy, VY. (2010). "Visual balloon-guided point-by-point ablation: reliable, reproducible, and persistent pulmonary vein isolation". Circ Arrhythm Electrophysiol. 3 (3): 266–73. doi:10.1161/CIRCEP.109.933283. PMID 20504945. Unknown parameter |month= ignored (help)
  16. 16.0 16.1 Gopinath, D.; Lewis, WR.; Di Biase, L.; Natale, A. (2011). "Pulmonary vein antrum isolation for atrial fibrillation on therapeutic coumadin: special considerations". J Cardiovasc Electrophysiol. 22 (2): 236–9. doi:10.1111/j.1540-8167.2010.01940.x. PMID 21044211. Unknown parameter |month= ignored (help)
  17. Asbach, S.; Biermann, J.; Bode, C.; Faber, TS. (2011). "Early Heparin Administration Reduces Risk for Left Atrial Thrombus Formation during Atrial Fibrillation Ablation Procedures". Cardiol Res Pract. 2011: 615087. doi:10.4061/2011/615087. PMID 21747989.
  18. Mega, JL.; Braunwald, E.; Wiviott, SD.; Bassand, JP.; Bhatt, DL.; Bode, C.; Burton, P.; Cohen, M.; Cook-Bruns, N. (2012). "Rivaroxaban in patients with a recent acute coronary syndrome". N Engl J Med. 366 (1): 9–19. doi:10.1056/NEJMoa1112277. PMID 22077192. Unknown parameter |month= ignored (help)
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  22. Hsu, LF.; Jaïs, P.; Hocini, M.; Sanders, P.; Scavée, C.; Sacher, F.; Takahashi, Y.; Rotter, M.; Pasquie, JL. (2005). "Incidence and prevention of cardiac tamponade complicating ablation for atrial fibrillation". Pacing Clin Electrophysiol. 28 Suppl 1: S106–9. doi:10.1111/j.1540-8159.2005.00062.x. PMID 15683473. Unknown parameter |month= ignored (help)
  23. Ernst, S.; Ouyang, F.; Goya, M.; Löber, F.; Schneider, C.; Hoffmann-Riem, M.; Schwarz, S.; Hornig, K.; Müller, KM. (2003). "Total pulmonary vein occlusion as a consequence of catheter ablation for atrial fibrillation mimicking primary lung disease". J Cardiovasc Electrophysiol. 14 (4): 366–70. PMID 12741706. Unknown parameter |month= ignored (help)


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