Optimization of shocking lead configuration for transvenous atrial defibrillation

Introduction: High atrial defibrillation energy requirements (ADER) in patients with chronic atrial fibrillation (AF) may limit the acceptance of transvenous atrial defibrillation, We evaluated an optimized defibrillation electrode configuration that could help to reduce the ADER in patients with AF, Methods and Results: We tested ten different configurations in nine dogs with AF (3.33 +/- 2.92 days) induced by rapid atrial pacing. The configurations were: right atria! (RA) appendage as anode and coronary sinus (CS) as cathode; RE and innominate vein (I) as anode to CS (cathode); RA-CS (anode) to I(cathode); I-CS (anode) to RA (cathode); RA and left lateral subcutaneous patch (P) as anode to CS (cathode); RA-CS (anode) to P (cathode); P-CS (anode) to RA (cathode); superior vena cava (SVC) and CS (anode) to RA (cathode); RA-CS (anode) to SVC (cathode); and RA-SVC (anode) to CS (cathode), ADER was defined as the voltage needed to defibrillate the atria in 10% to 90% of 20 consecutive shocks. Three lead systems had ADER lower than the RA (anode) to CS (cathode) configuration, which required a mean of 143 +/- 58 volts. These three were: RA-SVC (anode) to CS (cathode) 103 +/- 29 V; I-CS (anode) to RA (cathode) 129 +/- 39 V; and P-CS (anode) to RA (cathode) 130 +/- 35 V. The remaining configurations had ADER higher than the RA (anode)to CS (cathode) configuration. Conclusion: Adding an additional shocking electrode may reduce ADER when compared with the RA (anode) to GS (cathode) configuration This concept could be incorporated into future implantable atrial defibrillators or used for refractory patients undergoing temporary transvenous cardioversion.