Ernest Lau

Waveform optimization for internal cardioversion of atrial fibrillation

INTRODUCTION A novel atrial defibrillator was developed at the Royal Victoria Hospital in collaboration with the Nanotechnology and Integrated Bio-Engineering Centre, University of Ulster. This device is powered by an external pulse of radiofrequency energy and designed to cardiovert using low-tilt monophasic waveform (LTMW) and low-tilt biphasic waveform (LTBW), 12 milliseconds pulse width. This study compared the safety and efficacy of LTMW with LTBW for transvenous cardioversion of atrial fibrillation (AF). METHODS Patients were anticoagulated with warfarin to maintain International Normalized Ratio between 2 and 3 for 4 weeks prior cardioversion. Warfarin international normalized ratio level was maintained in between 2 and 3 for 4 weeks prior cardioversion. St Judes defibrillating catheter was positioned in the distal coronary sinus and right atrium and connected to the defibrillator via a junction box. After a test shock using a dummy load, the patient was cardioverted in a step-up progression from 50 to 300 V. Shock success was defined as return of sinus rhythm for 30 seconds or more. If cardioversion was unsuccessful at peak voltage, the patient was crossed over to the other arm of the waveform type and cardioverted at peak voltage. RESULTS Thirty patients were randomized equally to LTBW and LTMW (15 each). Seven out of 15 patients (46%) cardioverted to sinus rhythm with LTBW, and 1 (6%) of 15, with LTMW (P = .035). Including crossover patients, 14 patients (46%) converted to sinus rhythm. After crossover, 4 patients were cardioverted with LTBW and 2 with LTMW. Overall mean voltage, current, and energy used for cardioversion were 270.53 ± 35.96 V, 3.68 ± 0.80 A, and 9.12 ± 3.73 J, respectively, and intracardiac impedance was 70.82 ± 13.46 Ω. For patients who were successfully cardioverted, mean voltage, current, energy, and intracardiac impedance were 268.28 ± 42.41 V, 3.52 ± 0.63 A, 8.51 ± 3.16 J, and 73.92 ± 12.01 Ω. There were no major adverse complications during the study. Cardiac markers measured postcardioversion were unremarkable. CONCLUSION Low-tilt biphasic waveform was more efficacious for low-energy transvenous cardioversion of AF. A significant proportion of patients were successfully cardioverted to sinus rhythm with low energy. Radiofrequency-powered defibrillation can be safely used for transvenous cardioversion of AF.

FOLLOW-UP RIATA SCREENING IN NORTHERN IRELAND

The Riata series of leads (St Jude Medical) are defibrillator leads with silicone as the insulation material. In December 2010, Riata & Riata ST leads were no longer marketed. The manufacturer-quoted lead failure rate at this time was 0.47p over 9 years2. However we observed a 15p

An early phase of slow myocardial activation may be necessary in order to benefit from cardiac resynchronization therapy

BACKGROUND Not all patients with a QRS duration longer than 140 milliseconds respond to cardiac resynchronization therapy (CRT). The same QRS duration may correspond to different spatiotemporal patterns of myocardial activation that influence response to CRT. METHODS Electrocardiographic imaging based on 80 chest wall electrodes was used to construct the spatiotemporal myocardial activation map in 46 consecutive patients before CRT. The cumulative percentage of myocardium activated was plotted against time expressed in terms of quintiles of the overall QRS duration. Changes in the left ventricular ejection fraction and end-diastolic diameter, maximum oxygen consumption per minute, brain natriuretic peptide level, and 6-minute walk distance after 6 months of CRT were compared across different patterns with 1-way analysis of variance. RESULTS Data from 34 patients were available for analysis. Four spatiotemporal patterns of myocardial activation could be identified: triphasic (fast-slow-fast) (13), uniform (8), fast-slow (7), and slow-fast (6). The overall QRS duration was similar in the 4 groups (166 +/- 19 vs 138 +/- 21 vs 157 +/- 26 vs 152 +/- 37 milliseconds, P = not significant [NS]). The ejection fraction showed a trend of greater increases for the triphasic (6.5% +/- 7.0%) and slow-fast (15.5% +/- 6.4%) patterns than for the uniform (4.0% +/- 13.3%) and fast-slow (8.0% +/- 6.1%) patterns (P = NS). The end-diastolic diameter showed a trend of greater decreases for the triphasic (-3.7% +/- 5.3%) and slow-fast (-7.0% +/- 6.7%) patterns than for the uniform (0.8% +/- 6.7%) and fast-slow (0.0% +/- 4.6%) patterns (P = NS). The maximum oxygen consumption per minute showed a trend of greater increases for the triphasic (1.2 +/- 4.2 mL/kg/min) and slow-fast (4.1 +/- 2.7 mL/kg/min) patterns than for the uniform (0.1 +/- 4.1 mL/kg/min) and fast-slow (1.0 +/- 2.1 mL/kg/min) patterns (P = NS). The brain natriuretic peptide level decreased significantly more for the triphasic (-450 +/- 1269) and slow-fast (-3121 +/- 1512) patterns than for the uniform (762 +/- 1036) and fast-slow (718 +/- 2530) patterns (P = .0003). The 6-minute walk distance increased significantly more for the triphasic (29 +/- 89) and slow-fast (40 +/- 23) patterns than for the uniform (6 +/- 87) and fast-slow (37 +/- 45) patterns (P = .0003). CONCLUSIONS Different spatiotemporal patterns of myocardial activation exist among patients with broad QRS complex and may affect response to CRT. An early phase of slow myocardial activation (the triphasic fast-slow-fast and the slow-fast patterns) may be necessary for a patient to benefit from CRT.

Inside-out abrasion and contained conductor cable externalization in a defibrillation lead with asymmetric conductor cable lumen distribution

Introduction Inside-out abrasion (IOA) is a distinct mode of insulation damage caused by conductor cables moving relative to the lead body, and may result in conductor cable externalization (CCE) and electric malfunction. IOA/CCE mainly affects defibrillation (DF) leads and has so far been observed only in models with symmetric conductor cable lumen distribution— the Riata and Durata leads by St Jude Medical/Abbott (Sylmar,CA) and theKentrox andLinox leads byBiotronik (Berlin, Germany). This report describes the first case of IOA/ CCE in a DF lead with asymmetric conductor cable lumen distribution: the Sprint Quattro Secure lead by Medtronic (Minneapolis, MN).