Benjamin O'Brien1,2,3, Damian C Balmforth4, Ross J Hunter4, Richard J Schilling4. 1. London AF Centre, London Bridge Hospital, London, UK. ben.obrien@bartshealth.nhs.uk. 2. Outcomes Research Consortium, Cleveland, OH, USA. ben.obrien@bartshealth.nhs.uk. 3. Department of Perioperative Medicine, St Bartholomew's Hospital, 1st Floor KGV Wing, London, EC1A 7BE, UK. ben.obrien@bartshealth.nhs.uk. 4. London AF Centre, London Bridge Hospital, London, UK.
Abstract
PURPOSE: Guidelines recommend that radiation exposure during AF catheter ablation procedures should be 'as low as reasonably achievable' (ALARA), particularly since many patients may have multiple procedures. Consequently, avoiding radiation exposure altogether must, if safe to do so, be the ultimate goal. The primary objective was to determine the feasibility and efficacy of fluoroscopy-free AF ablation compared to the fluoroscopy-assisted procedure. METHODS: Patients underwent AF ablation using commercially available technology with no routine pre-procedural imaging. The use of non-fluoroscopic imaging/mapping technologies permitted us to initially reduce x-ray exposure before eliminating its use altogether. This evolution of our practice proceeded in two stages: a 9-month period of optimising our fluoroscopy-free ablation protocol followed by a 9-month period during which we set out to complete the whole procedure routinely without fluoroscopy. We describe the protocol developed and report salient endpoints, such as complications, procedure times, patient experience, and procedural success rates. RESULTS: During the study period, fluoroscopy-free AF ablation was attempted in 69 patients: 24 in the 9-month 'development phase' and 45 in the 'implementation phase'. During the development phase, 13 of 24 patients (54%) were treated without the use of fluoroscopy. In the implementation phase, 45 patients underwent AF ablation of which 42 (93.3%) were fluoroscopy-free. A detailed description is given of the three cases in which fluoroscopy had to be used despite an intention not to. CONCLUSIONS: Fluoroscopy-free complex ablation procedures for the treatment of atrial fibrillation are safe and feasible in most patients.
PURPOSE: Guidelines recommend that radiation exposure during AF catheter ablation procedures should be 'as low as reasonably achievable' (ALARA), particularly since many patients may have multiple procedures. Consequently, avoiding radiation exposure altogether must, if safe to do so, be the ultimate goal. The primary objective was to determine the feasibility and efficacy of fluoroscopy-free AF ablation compared to the fluoroscopy-assisted procedure. METHODS:Patients underwent AF ablation using commercially available technology with no routine pre-procedural imaging. The use of non-fluoroscopic imaging/mapping technologies permitted us to initially reduce x-ray exposure before eliminating its use altogether. This evolution of our practice proceeded in two stages: a 9-month period of optimising our fluoroscopy-free ablation protocol followed by a 9-month period during which we set out to complete the whole procedure routinely without fluoroscopy. We describe the protocol developed and report salient endpoints, such as complications, procedure times, patient experience, and procedural success rates. RESULTS: During the study period, fluoroscopy-free AF ablation was attempted in 69 patients: 24 in the 9-month 'development phase' and 45 in the 'implementation phase'. During the development phase, 13 of 24 patients (54%) were treated without the use of fluoroscopy. In the implementation phase, 45 patients underwent AF ablation of which 42 (93.3%) were fluoroscopy-free. A detailed description is given of the three cases in which fluoroscopy had to be used despite an intention not to. CONCLUSIONS: Fluoroscopy-free complex ablation procedures for the treatment of atrial fibrillation are safe and feasible in most patients.
Entities:
Keywords:
ALARA (as low as reasonably achievable); Ablation; Atrial fibrillation; Fluoroscopy; Radiation
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