Department of Physiology, University of Debrecen, 4012 Debrecen, Hungary.
Basic Res Cardiol. 2010 May;105(3):315-23. doi: 10.1007/s00395-009-0082-7. Epub 2010 Feb 3.
Class III antiarrhythmic agents exhibit reverse rate-dependent lengthening of the action potential duration (APD). In spite of the several theories developed so far to explain this reverse rate-dependency (RRD), its mechanism has not yet been clarified. The aim of the present work was to further elucidate the mechanisms responsible for RRD in mammalian ventricular myocardium. Action potentials were recorded using conventional sharp microelectrodes from human, canine, rabbit and guinea pig ventricular myocardium in a rate-dependent manner varying the cycle length (CL) between 0.3 and 5 s. Rate-dependent drug effects were studied using agents known to lengthen or shorten action potentials, and these drug-induced changes in APD were correlated with baseline APD values. Both drug-induced lengthening (by dofetilide, sotalol, E-4031, BaCl(2), veratrine, BAY K 8644) and shortening (by mexiletine, tetrodotoxin, lemakalim) of action potentials displayed RRD, i.e., changes in APD were greater at longer than at shorter CLs. In rabbit, where APD is a biphasic function of CL, the drug-induced APD changes were proportional to baseline APD values but not to CL. Similar results were obtained when repolarization was modified by injection of inward or outward current pulses in isolated canine cardiomyocytes. In each case the change in APD was proportional to baseline APD (i.e., that measured before the superfusion of drug or injection of current). Also, the net membrane current (I (net)), determined from the action potential waveform at the middle of the plateau, was inversely proportional to APD and consequently with to CL. The results indicate that RRD is a common characteristic of all the drugs tested regardless of the modified ion current species. Thus, drug-induced RRD can be considered as an intrinsic property of cardiac membranes based on the inverse relationship between I (net) and APD.
III 类抗心律失常药物表现出动作电位时程(APD)的反向频率依赖性延长。尽管目前已经提出了几种理论来解释这种反向频率依赖性(RRD),但其机制尚未阐明。本工作的目的是进一步阐明哺乳动物心室心肌中RRD 的机制。使用传统的锋利微电极,从人类、犬、兔和豚鼠的心室心肌中以依赖于速率的方式记录动作电位,通过改变周期长度(CL)在 0.3 至 5 秒之间变化。使用已知延长或缩短动作电位的药物研究药物的速率依赖性作用,并且将这些药物引起的 APD 变化与基线 APD 值相关联。动作电位的药物诱导延长(通过多非利特、索他洛尔、E-4031、BaCl2、藜芦碱、BAY K 8644)和缩短(通过美西律、河豚毒素、莱卡利姆)都表现出 RRD,即 APD 的变化在较长的 CL 下比在较短的 CL 下更大。在兔中,APD 是 CL 的双相函数,药物引起的 APD 变化与基线 APD 值成正比,但与 CL 无关。在分离的犬心肌细胞中,通过向内或向外电流脉冲注射来修饰复极时,也得到了相似的结果。在每种情况下,APD 的变化与基线 APD 成正比(即在药物灌注或电流注射之前测量的 APD)。此外,从平台中期动作电位波形确定的净膜电流(I(net))与 APD 成反比,因此与 CL 成反比。结果表明,RRD 是所有测试药物的共同特征,与所修饰的离子电流种类无关。因此,药物引起的 RRD 可以被认为是基于 I(net)和 APD 之间的反比关系的心脏膜的固有特性。
