Increased intraventricular pressures are as harmful as the electrophysiological substrate of heart failure in favoring sustained reentry in the swine heart.

BACKGROUND: Heart failure (HF) electrophysiological remodeling (HF-ER) often includes the effect of chronically increased intraventricular pressures (IVPs) and promotes ventricular tachycardia/ventricular fibrillation (VT/VF). In addition, acutely increased IVPs have been associated with a higher rate of VT/VF episodes in chronic HF. OBJECTIVE: We hypothesized that increased IVPs and/or an ionic-imbalanced (acidified), catecholamine-rich (adrenergic) milieu (AA milieu) may contribute as much as HF-ER to the substrate for reentry in HF. We used a porcine model of tachycardiomyopathy and evaluated the individual/combined contributions of (1) increased IVPs, (2) HF-ER, and (3) an AA milieu. METHODS: HF-ER was induced in 7 pigs by rapid pacing. Seven pigs were used as controls. Hearts were isolated and Langendorff perfused. Programmed ventricular stimulation was conducted under low or increased IVP and normal/AA milieu (4 combinations). Epicardial optical mapping was used to quantify conduction velocity (CV), action potential duration (APD), and dispersion of repolarization (DoR). RESULTS: HF-ER decreased CV (-34%; P = .002) and increased APD (11%; P = .024) and DoR (21%; P = .007). Increased IVP amplified DoR (36%; P < .001) and decreased CV (-17%; P = .001) and APD (-8%; P < .001). The AA milieu consistently modified only APD (-9%; P < .001) and led to amplified inter-/intra-subject heterogeneity. Increased IVP similarly raised the odds of inducing sustained VT/VF as the presence of HF-ER (>6-fold). CONCLUSION: By magnifying DoR, decreasing CV, and shortening APD, increased IVP was as harmful as HF-ER in favoring the substrate for sustained reentry in this model. The AA milieu contributed to a much lesser extent. Thus, a stricter control of IVP might be postulated as a useful add-on antiarrhythmic strategy in HF.

Morphological and thermodynamic comparison of the lesions created by 4 open-irrigated catheters in 2 experimental models.

INTRODUCTION: New generation open-irrigated catheters aim to improve irrigation efficiency. This may change lesion patterns, challenging operators. Indeed, safety issues have recently arisen. We aimed to experimentally assess 4 open-irrigated catheters, comparing lesion size, safety, and heat transfer. METHODS: The thigh lesion model was employed in 6 anesthetized pigs to assess the morphology of perpendicular and tangential lesions (n = 140) created by the newer catheters ThermoCool® SF, CoolFlex™, and Blazer™ Open-Irrigated, and the standard ThermoCool®, at a constant power of 30 W (60 seconds). To evaluate the propensity for deep-tissue overheating, a set of 120 applications were performed at 50 W (180 seconds) comparing pop rates. Thermal assessment of the lesion generation process (20 W, 60 seconds, n = 32) was performed with an infrared camera on bovine ventricular tissue. RESULTS: At 30 W, the newer catheters showed lower temperature readings compared with the ThermoCool®. No major efficacy or safety differences were found at tangential applications; however, at perpendicular applications: (1) the SF at 17 mL/min better preserved the superficial layers and focused its maximum thermal effect deeper, but at recommended flow rates (8 mL/min) it generated the largest superficial lesions; (2) CoolFlex™ created smaller lesions than SF and readily induced steam pops at 50 W without temperature control; and (3) no major differences were found comparing Blazer™ Open-Irrigated and ThermoCool®. CONCLUSIONS: The lower temperature readings in the newer catheters make them more prone to deliver the maximum programmed power. Under experimental conditions, the SF catheter focuses its maximum effect deeper and the CoolFlex™ can be more prone to induce steam pops at high power settings.

KATP channel opening accelerates and stabilizes rotors in a swine heart model of ventricular fibrillation.

AIMS: The mechanisms underlying ventricular fibrillation (VF) are still disputed. Recent studies have highlighted the role of KATP-channels. We hypothesized that, under certain conditions, VF can be driven by stable and epicardially detectable rotors in large hearts. To test our hypothesis, we used a swine model of accelerated VF by opening KATP-channels with cromakalim. METHODS AND RESULTS: Optical mapping, spectral analysis, and phase singularity tracking were performed in eight perfused swine hearts during VF. Pseudo-bipolar electrograms were computed. KATP-channel opening almost doubled the maximum dominant frequency (14.3 ± 2.2 vs. 26.5 ± 2.8 Hz, P < 0.001) and increased the maximum regularity index (0.82 ± 0.05 vs. 0.94 ± 0.04, P < 0.001), the density of rotors (2.0 ± 1.4 vs. 16.0 ± 7.0 rotors/cm²×s, P < 0.001), and their maximum lifespans (medians: 368 vs. ≥3410 ms, P < 0.001). Persistent rotors (≥1 movie = 3410 ms) were found in all hearts after cromakalim (mostly coinciding with the fastest and highest organized areas), but they were not epicardially visible at baseline VF. A 'beat phenomenon' ruled by inter-domain frequency gradients was observed in all hearts after cromakalim. Acceleration of VF did not reveal any significant regional preponderance. Complex fractionated electrograms were not found in areas near persistent rotors. CONCLUSION: Upon KATP-channel opening, VF consisted of rapid and highly organized domains mainly due to stationary rotors, surrounded by poorly organized areas. A 'beat phenomenon' due to the quasi-periodic onset of drifting rotors was observed. These findings demonstrate the feasibility of a VF driven by stable rotors in hearts whose size is similar to the human heart. Our model also showed that complex fractionation does not seem to localize stationary rotors.