Skanes A C, Mandapati R, Berenfeld O, Davidenko J M, Jalife J
Departments of Pharmacology, and Pediatrics, SUNY Health Science Center at Syracuse, Syracuse, NY, USA.
Circulation. 1998 Sep 22;98(12):1236-48. doi: 10.1161/01.cir.98.12.1236.
The activation patterns that underlie the irregular electrical activity during atrial fibrillation (AF) have traditionally been described as disorganized or random. Recent studies, based predominantly on statistical methods, have provided evidence that AF is spatially organized. The objective of this study was to demonstrate the presence of spatial and temporal periodicity during AF.
We used a combination of high-resolution video imaging, ECG recordings, and spectral analysis to identify sequential wave fronts with temporal periodicity and similar spatial patterns of propagation during 20 episodes of AF in 6 Langendorff-perfused sheep hearts. Spectral analysis of AF demonstrated multiple narrow-band peaks with a single dominant peak in all cases (mean, 9.4+/-2.6 Hz; cycle length, 112+/-26 ms). Evidence of spatiotemporal periodicity was found in 12 of 20 optical recordings of the right atrium (RA) and in all (n=19) recordings of the left atrium (LA). The cycle length of spatiotemporal periodic waves correlated with the dominant frequency of their respective optical pseudo-ECGs (LA: R2=0.99, slope=0.94 [95% CI, 0.88 to 0.99]; RA: R2=0.97, slope=0.92 [95% CI, 0.80 to 1.03]). The dominant frequency of the LA pseudo-ECG alone correlated with the global bipolar atrial EG (R2=0.76, slope=0.75 [95% CI, 0.52 to 0.99]). In specific examples, sources of periodic activity were seen as rotors in the epicardial sheet or as periodic breakthroughs that most likely represented transmural pectinate muscle reentry. However, in the majority of cases, periodic waves were seen to enter the mapping area from the edge of the field of view.
Reentry in anatomically or functionally determined circuits forms the basis of spatiotemporal periodic activity during AF. The cycle length of sources in the LA determines the dominant peak in the frequency spectra in this experimental model of AF.
传统上,心房颤动(AF)期间不规则电活动的激活模式被描述为无序或随机的。最近的研究主要基于统计方法,提供了AF在空间上是有组织的证据。本研究的目的是证明AF期间存在空间和时间周期性。
我们结合高分辨率视频成像、心电图记录和频谱分析,在6个Langendorff灌注的绵羊心脏的20次AF发作期间,识别具有时间周期性和相似空间传播模式的连续波前。AF的频谱分析在所有病例中均显示多个窄带峰值,其中有一个主峰(平均值为9.4±2.6Hz;周期长度为112±26ms)。在右心房(RA)的20次光学记录中的12次以及左心房(LA)的所有(n = 19)记录中发现了时空周期性的证据。时空周期波的周期长度与其各自光学伪心电图的主导频率相关(LA:R2 = 0.99,斜率 = 0.94 [95% CI,0.88至0.99];RA:R2 = 0.97,斜率 = 0.92 [95% CI,0.80至1.03])。仅LA伪心电图的心主导频率与整体双极心房电图相关(R2 = 0.76,斜率 = 0.75 [95% CI,0.52至0.99])。在具体实例中,周期性活动源表现为心外膜片层中的转子或最可能代表透壁梳状肌折返的周期性突破。然而,在大多数情况下,周期性波是从视野边缘进入映射区域的。
在解剖学或功能确定的回路中的折返构成了AF期间时空周期性活动的基础。在这个AF实验模型中,LA中源的周期长度决定了频谱中的主峰。
