Division of Cardiology, Department of Internal Medicine, The Jikei University School of Medicine, 3-19-18 Nishishinbashi, Minato-ku, Tokyo, Japan.
CHU Bordeaux, IHU Lyric, Université de Bordeaux, Bordeaux, France.
Europace. 2019 Jul 1;21(7):1039-1047. doi: 10.1093/europace/euz034.
The circuit of pulmonary vein-gap re-entrant atrial tachycardia (PV-gap RAT) after atrial fibrillation ablation is sometimes difficult to identify by conventional mapping. We analysed the detailed circuit and electrophysiological features of PV-gap RATs using a novel high-resolution mapping system.
This multicentre study investigated 27 (7%) PV-gap RATs in 26 patients among 378 atrial tachycardias (ATs) mapped with Rhythmia™ system in 281 patients. The tachycardia cycle length (TCL) was 258 ± 52 ms with P-wave duration of 116 ± 28 ms. Three types of PV-gap RAT circuits were identified: (A) two gaps in one pulmonary vein (PV) (unilateral circuit) (n = 17); (B) two gaps in the ipsilateral superior and inferior PVs (unilateral circuit) (n = 6); and (C) two gaps in one PV with a large circuit around contralateral PVs (bilateral circuit) (n = 4). Rhythmia™ mapping demonstrated two distinctive entrance and exit gaps of 7.6 ± 2.5 and 7.9 ± 4.1 mm in width, respectively, the local signals of which showed slow conduction (0.14 ± 0.18 and 0.11 ± 0.10m/s) with fragmentation (duration 86 ± 27 and 78 ± 23 ms) and low-voltage (0.17 ± 0.13 and 0.17 ± 0.21 mV). Twenty-two ATs were terminated (mechanical bump in one) and five were changed by the first radiofrequency application at the entrance or exit gap. Moreover, the conduction time inside the PVs (entrance-to-exit) was 138 ± 60 ms (54 ± 22% of TCL); in all cases, this resulted in demonstrating P-wave with an isoelectric line in all leads.
This is the first report to demonstrate the detailed mechanisms of PV-gap re-entry that showed evident entrance and exit gaps using a high-resolution mapping system. The circuits were variable and Rhythmia™-guided ablation targeting the PV-gap can be curative.
肺静脉-间隙折返性房性心动过速(PV-gap RAT)在心房颤动消融后有时难以通过常规标测确定。我们使用一种新的高分辨率标测系统分析了 PV-gap RAT 的详细环路和电生理特征。
这项多中心研究在 281 名患者中使用 Rhythmia™系统对 378 例房性心动过速(ATs)进行标测,其中 27 例(7%)为 PV-gap RATs,涉及 26 名患者。心动过速周期长度(TCL)为 258±52ms,P 波持续时间为 116±28ms。确定了三种 PV-gap RAT 环路类型:(A)同一肺静脉(PV)内的两个间隙(单侧环路)(n=17);(B)同侧上、下 PV 内的两个间隙(单侧环路)(n=6);和(C)同一 PV 内的两个间隙,伴有对侧 PV 周围的大环路(双侧环路)(n=4)。Rhythmia™标测显示,入口和出口的宽度分别为 7.6±2.5mm 和 7.9±4.1mm,局部信号显示缓慢传导(0.14±0.18 和 0.11±0.10m/s)伴有碎裂(持续时间 86±27ms 和 78±23ms)和低电压(0.17±0.13 和 0.17±0.21mV)。22 例 AT 终止(1 例机械性隆起),5 例在入口或出口间隙首次射频消融后发生改变。此外,PV 内的传导时间(入口到出口)为 138±60ms(TCL 的 54±22%);在所有情况下,这导致所有导联中 P 波均呈等电线路。
这是第一项使用高分辨率标测系统显示明显入口和出口间隙的 PV-gap 折返详细机制的报告。环路是可变的,针对 PV-gap 的 Rhythmia™引导消融可能是有效的。
