Arrhythmia Section, Cardiology Department, Thorax Institute, Hospital Clínic and IDIBAPS (Institut d'Investigació Agustí Pi i Sunyer), C/Villarroel 170, 08036 Barcelona, Catalonia, Spain.
Europace. 2018 Feb 1;20(2):337-346. doi: 10.1093/europace/euw325.
Identification of local abnormal electrograms (EGMs) during ventricular tachycardia substrate ablation (VTSA) is challenging when they are hidden within the far-field signal. This study analyses whether the response to a double ventricular extrastimulus during substrate mapping could identify slow conducting areas that are hidden during sinus rhythm.
Consecutive patients (n = 37) undergoing VTSA were prospectively included. Bipolar EGMs with >3 deflections and duration <133 ms were considered as potential hidden slow conduction EGMs (HSC-EGM) if located within/surrounding the scar area. Whenever a potential HSC-EGM was identified, a double ventricular extrastimulus was delivered. If the local potential delayed, it was annotated as HSC-EGM. The incidence of HSC-EGM in core, border-zone, and normal-voltage regions was determined. Ablation was delivered at conducting channel entrances and HSC-EGMs. VT inducibility after VTSA obtained was compared with data from a historic control group. 2417 EGMs were analyzed. 575 (23.7%) qualified as potential HSC-EGM, and 198 of them were tagged as HSC-EGMs. Scars in patients with HSC-EGMs (n = 21, 56.7%) were smaller (35.424.7 vs 67.639.1 cm2; P = 0.006) and more heterogeneous (core/scar area ratio 0.250.2 vs 0.450.19; P = 0.02). 28.8% of HSC-EGMs were located in normal-voltage tissue; 81.3% were targeted for ablation. Patients undergoing VTSA incorporating HSC analysis needed less radiofrequency time (17.411 vs 2310.7 minutes; P = 0.016) and had a lower rate of VT inducibility after VTSA than the historic controls (24.3% vs 50%; P = 0.018).
Ventricular tachycardia substrate ablation incorporating HSC analysis allowed further arrhythmic substrate identification (especially in normal-voltage areas) and reduced RF time and VT inducibility after VTSA.
在心室性心动过速基质消融(VTSA)期间,当局部异常电图(EGM)隐藏在远场信号中时,识别它们具有挑战性。本研究分析了基质标测过程中双心室早搏刺激能否识别窦性心律时隐藏的缓慢传导区域。
连续纳入 37 例行 VTSA 的患者。如果位于瘢痕区域内/周围且具有 >3 个波峰和 <133 ms 时程的双极 EGM 被认为是潜在的隐匿性缓慢传导 EGM(HSC-EGM)。只要识别出潜在的 HSC-EGM,就会给予双心室早搏刺激。如果局部电位延迟,则将其标记为 HSC-EGM。确定核心区、交界区和正常电压区的 HSC-EGM 发生率。在传导通道入口和 HSC-EGM 处进行消融。比较 VTSA 后诱导 VT 的发生率与历史对照组的数据。分析了 2417 个 EGM。575 个(23.7%)符合潜在 HSC-EGM 标准,其中 198 个被标记为 HSC-EGM。HSC-EGM 患者(n=21,56.7%)的疤痕较小(35.424.7 比 67.639.1 cm2;P=0.006)且更不均匀(核心/疤痕面积比 0.250.2 比 0.450.19;P=0.02)。28.8%的 HSC-EGM 位于正常电压组织中;81.3%的 HSC-EGM 被靶向消融。接受包含 HSC 分析的 VTSA 的患者需要的射频时间更少(17.411 比 2310.7 分钟;P=0.016),并且 VTSA 后诱导 VT 的发生率低于历史对照组(24.3%比 50%;P=0.018)。
包含 HSC 分析的心室性心动过速基质消融可进一步识别心律失常基质,并减少射频时间和 VTSA 后 VT 的诱导率。
