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This study aimed to evaluate the safety and acute effect on markers of cardiac autonomic tone following pulsed electric fields (PEFs) delivered to epicardial ganglionated plexi (GP) during a cardiac surgical procedure. Ablation of GP as a treatment for atrial fibrillation (AF) has shown promise, but thermal ablation energy sources are limited by the risk of inadvertent collateral tissue injury. In acute canine experiments, median sternotomy was performed to facilitate the identification of 5 epicardial GP regions using an anatomy-guided approach. Each site was targeted with saline-irrigated PEF (1000 V, 100 µs, 10 electrocardiogram [ECG]-synchronized pulse sequences). Atrial effective refractory period (AERP) and local electrogram (EGM) amplitude were measured before and after each treatment. Histology was performed on samples from treatment-adjacent structures. In 5 animals, 30 (n = 2) and 60 (n = 3) pulses were successfully delivered to each of the 5 target sites. There was no difference in local atrial EGM amplitude before and after PEF application at each site (1.83 ± 0.41 vs. 1.92 ± 0.53 mV, P = .72). The mean AERP increased from 97 ± 15 ms at baseline to 115 ± 7 ms following treatment at all sites (18.6% increase; 95% confidence interval, 1.9-35.2; P = .037). There were no sustained ventricular arrhythmias or acute evidence of ischemia following delivery. Histology showed complete preservation of adjacent atrial myocardium, phrenic nerves, pericardium, and esophagus. Use of PEF to target regions rich in cardiac GP in open-chest canine experiments was feasible and effective at acutely altering markers of cardiac autonomic tone.
RESUMEN
BACKGROUND: Pulsed electric field (PEF) ablation is an emerging modality for the treatment of cardiac arrhythmias. Data regarding effects on the interventricular septum are limited, and the optimal delivery protocol and electrode configuration remain undefined. OBJECTIVES: This study sought to evaluate the electrophysiological, imaging, and histological characteristics of bipolar direct-current PEF delivered across the interventricular septum. METHODS: PEF was applied between identical solid-tip ablation catheters positioned on either side of the septum in a chronic canine model. Intracardiac and surface electrophysiological data were recorded following delivery. In 4 animals, cardiac magnetic resonance (CMR) was performed early (6 ± 2 days) and late (30 ± 2 days) postablation. After 4 weeks of survival, cardiac specimens were sectioned for histopathological analysis. RESULTS: In 8 canines, PEF was delivered in 27 separate septal sites (45 ± 17 J/site) with either microsecond or nanosecond PEF. Acute complications included transient complete atrioventricular block in 5 animals (63%) after delivery at the anterobasal septum, with right bundle branch block persisting in 3 (38%). Ventricular fibrillation occurred in 1 animal during microsecond but not nanosecond PEF. Postprocedural CMR showed prominent edema and significant left ventricular systolic dysfunction, which recovered with late imaging. At 4 weeks, 36 individual well-demarcated lesions were demonstrated by CMR and histopathology. Lesion depth measured by histology was 2.6 ± 2.1 mm (maximum 10.9 mm and near transmural). CONCLUSIONS: Bipolar PEF ablation of the interventricular septum is feasible and can produce near transmural lesions. Myocardial stunning, edema, and conduction system injury may occur transiently. Further studies are required to optimize safe delivery and efficacious lesions.
Asunto(s)
Ablación por Catéter , Tabique Interventricular , Animales , Bloqueo de Rama , Ablación por Catéter/métodos , Perros , Electroporación , Sistema de Conducción Cardíaco , Tabique Interventricular/diagnóstico por imagen , Tabique Interventricular/cirugíaRESUMEN
BACKGROUND: Mid-myocardial ventricular arrhythmias are challenging to treat. Cardiac electroporation via pulsed electric fields (PEFs) offers significant promise. We therefore tested PEF delivery using screw-in pacemaker leads as proof-of-concept. METHODS: In 5 canine models, we applied nanosecond PEF (pulse width 300 ns) across the right ventricular (RV) septum using a single lead bipolar configuration (n = 2) and between two leads (n = 3). We recorded electrograms (EGMs) prior to, immediately post, and 5 min after PEF. Cardiac magnetic resonance imaging (cMRI) and histopathology were performed at 2 weeks and 1 month. RESULTS: Nanosecond PEF induced minimal extracardiac stimulation and frequent ventricular ectopy that terminated post-treatment; no canines died with PEF delivery. With 1 lead, energy delivery ranged from 0.64 to 7.28 J. Transient ST elevations were seen post-PEF. No myocardial delayed enhancement (MDE) was seen on cMRI. No lesions were noted on the RV septum at autopsy. With 2 leads, energy delivery ranged from 56.3 to 144.9 J. Persistent ST elevations and marked EGM amplitude decreases developed post-PEF. MDE was seen along the septum 2 weeks and 1 month post-PEF. There were discrete fibrotic lesions along the septum; pathology revealed dense connective tissue with < 5% residual cardiomyocytes. CONCLUSIONS: Ventricular electroporation is feasible and safe with an active fixation device. Reversible changes were seen with lower energy PEF delivery, whereas durable lesions were created at higher energies. Central illustration: pulsed electric field delivery into ventricular myocardium with active fixation leads.
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Background: We have demonstrated that a neural network is able to predict a person's age from the electrocardiogram (ECG) [artificial intelligence (AI) ECG age]. However, some discrepancies were observed between ECG-derived and chronological ages. We assessed whether the difference between AI ECG and chronological age (Age-Gap) represents biological ageing and predicts long-term outcomes. Methods and results: We previously developed a convolutional neural network to predict chronological age from ECGs. In this study, we used the network to analyse standard digital 12-lead ECGs in a cohort of 25 144 subjects ≥30 years who had primary care outpatient visits from 1997 to 2003. Subjects with coronary artery disease, stroke, and atrial fibrillation were excluded. We tested whether Age-Gap was correlated with total and cardiovascular mortality. Of 25 144 subjects tested (54% females, 95% Caucasian) followed for 12.4 ± 5.3 years, the mean chronological age was 53.7 ± 11.6 years and ECG-derived age was 54.6 ± 11 years (R 2 = 0.79, P < 0.0001). The mean Age-Gap was small at 0.88 ± 7.4 years. Compared to those whose ECG-derived age was within 1 standard deviation (SD) of their chronological age, patients with Age-Gap ≥1 SD had higher all-cause and cardiovascular disease (CVD) mortality. Conversely, subjects whose Age-Gap was ≤1 SD had lower all-cause and CVD mortality. Results were unchanged after adjusting for CVD risk factors and other survival influencing factors. Conclusion: The difference between AI ECG and chronological age is an independent predictor of all-cause and cardiovascular mortality. Discrepancies between these possibly reflect disease independent biological ageing.