Qu Z, Garfinkel A, Chen P S, Weiss J N
Cardiovascular Research Laboratory, UCLA, Los Angeles, CA 90095-1760, USA.
Circulation. 2000 Oct 3;102(14):1664-70. doi: 10.1161/01.cir.102.14.1664.
T-wave alternans, which is associated with the genesis of cardiac fibrillation, has recently been related to discordant action potential duration (APD) alternans. However, the cellular electrophysiological mechanisms responsible for discordant alternans are poorly understood.
We simulated a 2D sheet of cardiac tissue using phase 1 of the Luo-Rudy cardiac action potential model. A steep (slope >1) APD restitution curve promoted concordant APD alternans and T-wave alternans without QRS alternans. When pacing was from a single site, discordant APD alternans occurred only when the pacing rate was fast enough to engage conduction velocity (CV) restitution, producing both QRS and T-wave alternans. Tissue heterogeneity was not required for this effect. Discordant alternans markedly increases dispersion of refractoriness and increases the ability of a premature stimulus to cause localized wavebreak and induce reentry. In the absence of steep APD restitution and of CV restitution, sustained discordant alternans did not occur, but reentry could be induced if there was marked electrophysiological heterogeneity. Both discordant APD alternans and preexisting APD heterogeneity facilitate reentry by causing the waveback to propagate slowly.
Discordant alternans arises dynamically from APD and CV restitution properties and markedly increases dispersion of refractoriness. Preexisting and dynamically induced (via restitution) dispersion of refractoriness independently increase vulnerability to reentrant arrhythmias. Reduction of dynamically induced dispersion by appropriate alteration of electrical restitution has promise as an antiarrhythmic strategy.
T波交替与房颤的发生有关,最近又与动作电位时程(APD)的不一致交替相关。然而,导致不一致交替的细胞电生理机制尚不清楚。
我们使用Luo-Rudy心脏动作电位模型的第1相模拟了二维心脏组织片。陡峭的(斜率>1)APD恢复曲线促进了一致的APD交替和T波交替,而无QRS波交替。当从单个部位起搏时,只有起搏频率足够快以激活传导速度(CV)恢复时才会出现不一致的APD交替,同时产生QRS波和T波交替。这种效应不需要组织异质性。不一致的交替显著增加了不应期离散度,并增加了过早刺激引起局部波破碎和诱发折返的能力。在没有陡峭的APD恢复和CV恢复的情况下,不会出现持续的不一致交替,但如果存在明显的电生理异质性,则可诱发折返。不一致的APD交替和预先存在的APD异质性都会通过使波返传播缓慢而促进折返。
不一致交替由APD和CV恢复特性动态产生,并显著增加不应期离散度。预先存在的和动态诱导的(通过恢复)不应期离散度独立增加了发生折返性心律失常的易感性。通过适当改变电恢复来减少动态诱导的离散度有望成为一种抗心律失常策略。
