Cabo C, Pertsov A M, Baxter W T, Davidenko J M, Gray R A, Jalife J
Department of Pharmacology, SUNY Health Science Center, Syracuse 13210.
Circ Res. 1994 Dec;75(6):1014-28. doi: 10.1161/01.res.75.6.1014.
We have investigated the role of wave-front curvature on propagation by following the wave front that was diffracted through a narrow isthmus created in a two-dimensional ionic model (Luo-Rudy) of ventricular muscle and in a thin (0.5-mm) sheet of sheep ventricular epicardial muscle. The electrical activity in the experimental preparations was imaged by using a high-resolution video camera that monitored the changes in fluorescence of the potentiometric dye di-4-ANEPPS on the surface of the tissue. Isthmuses were created both parallel and perpendicular to the fiber orientation. In both numerical and biological experiments, when a planar wave front reached the isthmus, it was diffracted to an elliptical wave front whose pronounced curvature was very similar to that of a wave front initiated by point stimulation. In addition, the velocity of propagation was reduced in relation to that of the original planar wave. Furthermore, as shown by the numerical results, wave-front curvature changed as a function of the distance from the isthmus. Such changes in local curvature were accompanied by corresponding changes in velocity of propagation. In the model, the critical isthmus width was 200 microns for longitudinal propagation and 600 microns for transverse propagation of a single planar wave initiated proximal to the isthmus. In the experiments, propagation depended on the width of the isthmus for a fixed stimulation frequency. Propagation through an isthmus of fixed width was rate dependent both along and across fibers. Thus, the critical isthmus width for propagation was estimated in both directions for different frequencies of stimulation. In the longitudinal direction, for cycle lengths between 200 and 500 milliseconds, the critical width was < 1 mm; for 150 milliseconds, it was estimated to be between 1.3 and 2 mm; and for the maximum frequency of stimulation (117 +/- 15 milliseconds), it was > 2.5 mm. In the transverse direction, critical width was between 1.78 and 2.32 mm for a basic cycle length of 200 milliseconds. It increased to values between 2.46 and 3.53 mm for a basic cycle length of 150 milliseconds. The overall results demonstrate that the curvature of the wave front plays an important role in propagation in two-dimensional cardiac muscle and that changes in curvature may cause slow conduction or block.
我们通过追踪在二维心室肌离子模型(罗-鲁迪模型)和薄(0.5毫米)的绵羊心室心外膜肌片中形成的狭窄峡部衍射的波前,研究了波前曲率对传播的作用。实验制剂中的电活动通过使用高分辨率摄像机成像,该摄像机监测组织表面电位染料di-4-ANEPPS荧光的变化。峡部的创建方向既与纤维方向平行,也与纤维方向垂直。在数值实验和生物学实验中,当平面波前到达峡部时,它会衍射为椭圆形波前,其明显的曲率与点刺激引发的波前非常相似。此外,传播速度相对于原始平面波的速度降低。此外,数值结果表明,波前曲率随距峡部距离的变化而变化。局部曲率的这种变化伴随着传播速度的相应变化。在模型中,对于在峡部近端起始的单个平面波,纵向传播的临界峡部宽度为200微米,横向传播的临界峡部宽度为600微米。在实验中,对于固定的刺激频率,传播取决于峡部的宽度。通过固定宽度峡部的传播在纤维方向和跨纤维方向上均与频率有关。因此,针对不同的刺激频率,在两个方向上都估计了传播的临界峡部宽度。在纵向方向上,对于200至500毫秒之间的周期长度,临界宽度小于1毫米;对于150毫秒,估计在1.3至2毫米之间;对于最大刺激频率(117±15毫秒),临界宽度大于2.5毫米。在横向方向上,对于200毫秒的基本周期长度,临界宽度在1.78至2.32毫米之间。对于150毫秒的基本周期长度,临界宽度增加到2.46至3.53毫米之间。总体结果表明,波前曲率在二维心肌传播中起重要作用,并且曲率变化可能导致缓慢传导或阻滞。
