CrossTalk proposal: Rotors have been demonstrated to drive human atrial fibrillation

It is our pleasure to debate this important and clinically relevant topic. Atrial fibrillation (AF) is a leading cause of hospitalization and death (Calkins et al. 2012), and the need to improve AF therapy is urgent and requires dramatic advances in our mechanistic understanding. Decades of research have not dented the incidence of AF, now at epidemic proportions (Calkins et al. 2012), nor reduced its morbidity and mortality with the laudable exception of antithrombotic therapy (Calkins et al. 2012). AF is initiated by triggers from regions including the pulmonary veins (Calkins et al. 2012), then sustained by specific mechanisms. We will present substantial evidence that these sustaining mechanisms include localized rotors in many patients. Our position that ‘rotors have been demonstrated to drive human AF’ summarizes a century of bench-to-bedside studies, culminating in recent multicentre clinical trials in which ablation of AF rotors has eliminated AF and improved patient outcomes. Conversely, there is a paucity of evidence supporting the opposing notion: that disorganized activity per se sustains AF without underlying driving mechanisms. Many studies that propose disorganized mechanisms are limited to ‘long-standing persistent AF’. Conversely, we provide evidence for a comprehensive mechanistic framework in which rotors sustain AF across clinical ‘classes’. The terms paroxysmal AF (self-limiting), persistent and longstanding persistent AF (continuous for >7 days and >1 year, respectively) are highly dependent on how often ECGs are obtained, since AF is often asymptomatic (Charitos et al. 2012) and patients with persistent AF may spontaneously present in sinus rhythm (Calkins et al. 2012) and could thus be reclassified as paroxysmal AF (Jahangir et al. 2007). While AF appears disorganized on the ECG, the atria clearly exhibit regions of spatio-temporal organization and disorganization. The debate on whether disorganization in AF is caused (‘driven’) by sources (Pandit Narayan et al. 2012b), or by localized physical pressure (Tzou et al. 2011). Propagation vectors in AF repeat reproducibly over time (Gerstenfeld et al. 1992) and exhibit consistent spatio-temporal features (Sahadevan et al. 2004; Sanders et al. 2005; Atienza et al. 2009). These observations are difficult to reconcile with disorganized sustaining mechanisms, yet support spatially localized AF-sustaining regions in these patients. Direct evidence for localized AF-sustaining mechanisms, including rotors, has been established in a variety of experimental systems. Optical mapping that utilizes voltage-sensitive dyes and contemporary signal-processing algorithms (Gray et al. 1998) has demonstrated AF rotors producing spatial gradients in the distribution of dominant atrial frequencies, the highest frequency lying at the rotor location (Fig. 1; Mansour et al. 2001). Clinical interventions show that ablation of high dominant frequency sites that eliminates left-to-right atrial frequency gradients predicts long-term freedom from AF (Atienza et al. 2009). Direct clinical evidence for rotors now exists in patients with paroxysmal, persistent and longstanding persistent AF. Since human AF is spatially non-uniform, we used bi-atrial basket catheters (Narayan et al. 2013b) to simultaneously map much larger areas than in previous studies (de Groot et al. 2010) and then applied phase analysis to detect regions that activate sequentially but may be obscured by the fibrillatory milieu. Simultaneous analysis of wide areas increases the sensitivity to detect rotors that precess (show limited meander), and is essential to prove or disprove their existence. Yet, to the best of our knowledge, simultaneous analysis of wide areas is absent in studies supporting disorganized mechanisms (de Groot et al. 2010; Lee et al. 2014). Although higher spatial resolution would be welcome, we reasoned from minimum bi-atrial (Narayan et al. 2012a) repolarization (∼110 ms) and conduction velocity (∼40 cm s−1) that human atria can support 1:1 conduction from a rotor in circuit paths as short as ∼4–5 cm (Rensma et al. 1988). Clinical electrode spacing can map such reentry (Rappel Miller et al. 2013), and laboratories worldwide have identified rotors in human AF using diverse methods, including phase mapping (Ghoraani et al. 2013; Haissaguerre et al. 2013; Lin et al. 2013; Lee et al. 2014). Studies are defining how localized ablation eliminates AF, possibly analogous to the proven elimination of micro-reentrant atrial tachycardia by focal ablation. While it is often assumed that Maze surgery supports disorganized mechanisms (Moe et al. 1964), the numbers of lesions (Cox et al. 1991) are insufficient to constrain dozens or hundreds of the wavelets proposed (de Groot et al. 2010). Since rotors need ‘elbow room’ (typically 2× the centre of rotation or ∼5–10 mm), Maze may in fact simply prevent rotors from sustaining. Indeed, one original motivation for Maze was to intersect relatively large reentrant drivers (Cox et al. 1991). Notably, studies supporting AF disorganization involved few patients (n = 49) (de Groot et al. 2010), and mapped only 10–21 cm2 or <10–20% of MRI-defined left atrial areas (100–138 cm2) (Jadidi et al. 2013). It is unclear why this work (de Groot et al. 2010) consistently fails to show any rotational activity in human AF, since others now show rotations of varying duration depending on the size of the mapping plaque and technique (Ghoraani et al. 2013; Haissaguerre et al. 2013; Lin et al. 2013; Narayan et al. 2013b; Lee et al. 2014). It is possible that activation mapping of these difficult-to-interpret AF electrograms (Fig. 1; de Groot et al. 2010) obscures rotation evident in other approaches (e.g. phase mapping). Importantly, to the best of our knowledge, interventions have never been used to prove that disorganization is an AF-sustaining mechanism rather than just a bystander to another mechanism (e.g. rotors). Finally, the disorganized AF hypothesis is inconsistent with and cannot easily explain the wealth of clinical and experimental data supporting localized AF sources in at least some patients as discussed above. Rotors have been proven to sustain AF in patients in all clinical subtypes and numerous animal models. These data come from various groups using diverse methods with interventions and long-term outcomes to prove causality. The opposing contention, that rotors do not exist but that AF is sustained by disorganization without driving sources, is supported only circumstantially by experiments with important technical limitations, in a small numbers of patients, and with no proof of causality. Mapping and therapy of AF rotors has already substantially improved clinical outcomes in multicentre trials. Future work should define how electrical, structural or neural remodelling contributes to the formation of AF sources and disorganization from them to remaining tissue. Readers are invited to give their views on this and the accompanying CrossTalk articles in this issue by submitting a brief comment. Comments may be posted up to 6 weeks after publication of the article, at which point the discussion will close and authors will be invited to submit a ‘final word’. To submit a comment, go to http://jp.physoc.org/letters/submit/jphysiol;592/15/3163 Sanjiv M. Narayan is Professor of Medicine at the University of California San Diego, where he treats patients with heart rhythm disorders. He was trained in software engineering and neuroscience in addition to cardiology and clinical electrophysiology. He directs an actively funded translational laboratory that uses bioengineering solutions to understand arrhythmia mechanisms, and has pioneered unique therapies for cardiac fibrillation. He has authored or co-authored over 152 original papers and review articles. José Jalife is the Cyrus and Jane Farrehi Professor of Cardiovascular Research and Professor of Internal Medicine at the University of Michigan. He is a leader in the study of mechanisms of cardiac arrhythmias. His work has led to major advances toward elucidating the molecular and cellular bases of atrial fibrillation, ventricular fibrillation and sudden cardiac death. He has published more than 300 original papers and review articles, and has edited/authored 15 books, including the internationally acclaimed Cardiac Electrophysiology: From Cell to Bedside, now in its sixth edition. Please note: The publisher is not responsible for the content or functionality of any supporting information supplied by the authors. Any queries (other than missing content) should be directed to the corresponding author for the article. S. M. Narayan is co-author of intellectual property owned by the University of California Regents and licensed to Topera Inc. (San Diego, CA, USA). Topera does not sponsor any research, including that presented here. S. M. Narayan holds equity in Topera, and reports having received honoraria from Medtronic, St Jude Medical and Biotronik. J. Jalife serves on the Scientific Advisory Board of Topera, Inc. The authors' work is supported by National Heart, Lung, and Blood Institute grants HL103800 and HL83559 (S.M.N.) and the Leducq Foundation (J.J.).