Di Diego J M, Antzelevitch C
Masonic Medical Research Laboratory, Utica, NY 13504.
Circulation. 1993 Sep;88(3):1177-89. doi: 10.1161/01.cir.88.3.1177.
Pinacidil is known to augment a time-independent outward current in cardiac tissues by activating the ATP-regulated potassium channels. Activation of this current, IK-ATP, is thought to be responsible for increased potassium permeability in ischemia. The contribution of IK-ATP activation to arrhythmogenesis and the role of activation of this current in suppression of arrhythmias are areas of great interest and debate. Because electrical depression attending myocardial ischemia is more accentuated in ventricular epicardium than in endocardium, we endeavored to contrast the effects of pinacidil-induced IK-ATP activation on the electrophysiology of canine ventricular epicardium and endocardium.
Standard microelectrode techniques were used. Pinacidil (1 to 5 mumol/L) produced a marked dispersion of repolarization and refractoriness in isolated canine ventricular epicardium as well as between epicardium and endocardium. In endocardium, pinacidil abbreviated action potential duration (APD90) and refractoriness by 8.0 +/- 2.3%. In epicardium, the effects of pinacidil were nonhomogeneous. At some sites, pinacidil induced an all-or-none repolarization at the end of phase 1 of the action potential, resulting in 55.5 +/- 8.7% abbreviation of APD90 and refractoriness. Adjacent to these were sites at which the dome was maintained with only minor changes in APD and refractoriness. Extrasystolic activity displaying features of reentry was observed in isolated sheets of epicardium (63.2%) after exposure to pinacidil (1 to 5 mumol/L) but never in its absence. Dispersion of repolarization and ectopic activity was most readily induced in epicardium by a slowing of the stimulation rate in the presence of pinacidil. Electrical homogeneity was restored and arrhythmias abolished after washout of pinacidil or addition of either a transient outward current blocker, 4-aminopyridine, or a blocker of the ATP-regulated potassium channels, glybenclamide.
Our data suggest that the activation of IK-ATP can produce a marked dispersion of repolarization and refractoriness in epicardium as well as between epicardium and endocardium, leading to the development of extrasystolic activity via a mechanism that we have called phase 2 reentry. The available data also suggest that blockade of the transient outward current and/or the ATP-regulated potassium channels may be useful antiarrhythmic interventions under ischemic or "ATP depleted" conditions.
已知吡那地尔可通过激活ATP调节的钾通道增强心脏组织中与时间无关的外向电流。这种电流(IK-ATP)的激活被认为是缺血时钾通透性增加的原因。IK-ATP激活对心律失常发生的作用以及该电流激活在心律失常抑制中的作用是备受关注和存在争议的领域。由于心肌缺血时的电抑制在心室心外膜比心内膜更明显,我们致力于对比吡那地尔诱导的IK-ATP激活对犬心室心外膜和心内膜电生理的影响。
采用标准微电极技术。吡那地尔(1至5 μmol/L)在离体犬心室心外膜以及心外膜与心内膜之间产生了明显的复极化和不应期离散。在心内膜,吡那地尔使动作电位时程(APD90)和不应期缩短了8.0±2.3%。在心外膜,吡那地尔的作用不均匀。在一些部位,吡那地尔在动作电位1期结束时诱导全或无复极化,导致APD90和不应期缩短55.5±8.7%。与之相邻的部位,动作电位圆顶得以维持,APD和不应期仅有轻微变化。在暴露于吡那地尔(1至5 μmol/L)后的离体心外膜片(63.2%)中观察到了具有折返特征的期前收缩活动,但在未使用吡那地尔的情况下从未观察到。在存在吡那地尔的情况下,刺激频率减慢最易在心外膜诱导复极化离散和异位活动。冲洗掉吡那地尔或加入瞬时外向电流阻滞剂4-氨基吡啶或ATP调节的钾通道阻滞剂格列本脲后,电均匀性得以恢复,心律失常消失。
我们的数据表明,IK-ATP的激活可在心外膜以及心外膜与心内膜之间产生明显的复极化和不应期离散,通过一种我们称为2期折返的机制导致期前收缩活动的发生。现有数据还表明,在缺血或“ATP耗竭”条件下,阻断瞬时外向电流和/或ATP调节的钾通道可能是有用的抗心律失常干预措施。
