Harada Masahide, Honjo Haruo, Yamazaki Masatoshi, Nakagawa Harumichi, Ishiguro Yuko S, Okuno Yusuke, Ashihara Takashi, Sakuma Ichiro, Kamiya Kaichiro, Kodama Itsuo
Dept. of Cardiovascular Research, Research Inst. of Environmental Medicine, Nagoya University,Nagoya, 464-8601, Japan.
Am J Physiol Heart Circ Physiol. 2008 Apr;294(4):H1896-905. doi: 10.1152/ajpheart.00986.2007. Epub 2008 Feb 29.
In cardiac arrest due to ventricular fibrillation (VF), moderate hypothermia (MH, 33 degrees C) has been shown to improve defibrillation success compared with normothermia (NR, 37 degrees C) and severe hypothermia (SH, 30 degrees C). The underlying mechanisms remain unclear. We hypothesized that MH might prevent reentrant excitations rotating around functional obstacles (rotors) that are responsible for the genesis of VF. In two-dimensional Langendorff-perfused rabbit hearts prepared by cryoablation (n = 13), action potential signals were recorded by a high-resolution optical mapping system. During basic stimulation (2.5-5.0 Hz), MH and SH caused significant prolongation of action potential duration and significant reduction of conduction velocity. Wavelength was unchanged at MH, whereas it was shortened significantly at SH at higher stimulation frequencies (4.0-5.0 Hz). The duration of direct current stimulation-induced ventricular tachycardia (VT)/VF was reduced dramatically at MH compared with NR and SH. The spiral wave (SW) excitations documented during VT at NR were by and large organized, whereas those during VT/VF at MH and SH were characterized by disorganization with frequent breakup. Phase maps during VT/VF at MH showed a higher incidence of SW collision (mutual annihilation or exit from the anatomical boundaries), which caused a temporal disappearance of phase singularity points (PS-0), compared with that at NR and SH. There was an inverse relation between PS-0 period in the observation area and VT/VF duration. MH data points were located in a longer PS-0 period and a shorter VT/VF duration zone compared with SH. MH causes a modification of SW dynamics, leading to an increase in the chance of SW collision in favor of self-termination of VT/VF.
在因室颤(VF)导致的心搏骤停中,与正常体温(NR,37摄氏度)和深度低温(SH,30摄氏度)相比,中度低温(MH,33摄氏度)已被证明可提高除颤成功率。其潜在机制仍不清楚。我们推测,中度低温可能会阻止围绕功能性障碍物(转子)旋转的折返激动,而这些转子是室颤发生的原因。在通过冷冻消融制备的二维Langendorff灌注兔心脏(n = 13)中,用高分辨率光学标测系统记录动作电位信号。在基础刺激(2.5 - 5.0 Hz)期间,中度低温和深度低温导致动作电位时程显著延长,传导速度显著降低。在中度低温时波长不变,而在较高刺激频率(4.0 - 5.0 Hz)下深度低温时波长显著缩短。与正常体温和深度低温相比,中度低温时直流电刺激诱发的室性心动过速(VT)/室颤的持续时间显著缩短。正常体温时室性心动过速期间记录到的螺旋波(SW)激动大体上是有组织的,而中度低温和深度低温时室性心动过速/室颤期间的螺旋波激动则表现为无组织且频繁破碎。与正常体温和深度低温相比,中度低温时室性心动过速/室颤期间的相位图显示螺旋波碰撞(相互湮灭或从解剖边界退出)的发生率更高,这导致相位奇点(PS - 0)暂时消失。观察区域内的PS - 0周期与室性心动过速/室颤持续时间呈负相关。与深度低温相比,中度低温的数据点位于更长的PS - 0周期和更短的室性心动过速/室颤持续时间区域。中度低温会改变螺旋波动力学,导致螺旋波碰撞的机会增加,有利于室性心动过速/室颤的自我终止。
