Sidorov Veniamin Y, Woods Marcella C, Baudenbacher Franz
Department of Biomedical Engineering, Vanderbilt Institute for Integrative Biosystems Research and Education, Vanderbilt University, VU Station B #351631, Nashville, TN 37235-1631, USA.
J Physiol. 2007 Aug 15;583(Pt 1):237-50. doi: 10.1113/jphysiol.2007.137232. Epub 2007 Jun 14.
The stimulation of cardiac tissue in the recovery phase has significant importance in relation to reentry induction. In the theoretical experiment proposed by Winfree, termed the 'pinwheel' experiment, a point stimulus (S2) is applied in the wake of a freely propagating planar wave (S1). Reentry induced from this S1-S2 pinwheel protocol has been observed experimentally in heart preparations. However, in these experiments, which focused on activation outcomes, only mapping of extracellular voltages has been conducted. The lack of transmembrane potential (Vm) distribution data makes it impossible to analyse the underlying stimulation mechanisms which precede the reentry induction. In this work we sought to elucidate the stimulation mechanisms throughout the heart cycle using the pinwheel protocol. We examined the cardiac tissue responses during and immediately after cathodal stimulation in the refractory wake of a propagating planar wave. The voltage-sensitive dye di-4-ANEPPS was utilized to measure Vm directly from quasi two-dimensional preparations of cryoablated Langendorff-perfused rabbit hearts. Four stimulation mechanisms were observed that depended on the Vm magnitude during S2 cathodal stimulation. Make stimulation always occurred during diastolic stimulation. When stimulation was at the beginning of the relative refractory period (RRP), transitional make-break stimulation was detected. During the RRP the excitation was due to the break mechanism. While approaching the effective refractory period (ERP), the tissue response is characterized by a damped wave mediated response. These four stimulation mechanisms were observed in all hearts whether the S1 planar wave propagation was parallel or perpendicular to the fibre direction. This study is the first examination of Vm and the stimulation mechanisms throughout the cardiac cycle using the pinwheel protocol, and the results have implications in the development and improvement of pacing protocols for artificial cardiostimulators.
心脏组织在恢复阶段的刺激对于折返诱导具有重要意义。在Winfree提出的理论实验(称为“风车”实验)中,在自由传播的平面波(S1)之后施加一个点刺激(S2)。通过这种S1 - S2风车方案诱导的折返已在心脏标本中通过实验观察到。然而,在这些专注于激活结果的实验中,仅进行了细胞外电压的标测。缺乏跨膜电位(Vm)分布数据使得无法分析折返诱导之前的潜在刺激机制。在这项工作中,我们试图使用风车方案阐明整个心动周期的刺激机制。我们研究了在传播平面波的不应期尾迹中阴极刺激期间及之后心脏组织的反应。利用电压敏感染料di - 4 - ANEPPS直接从冷冻消融的Langendorff灌注兔心脏的准二维标本中测量Vm。观察到四种刺激机制,它们取决于S2阴极刺激期间的Vm大小。舒张期刺激时总是发生激发刺激。当刺激处于相对不应期(RRP)开始时,检测到过渡性的激发 - 阻断刺激。在RRP期间,兴奋是由于阻断机制。在接近有效不应期(ERP)时,组织反应的特征是由衰减波介导的反应。无论S1平面波传播方向是与纤维方向平行还是垂直,在所有心脏中都观察到了这四种刺激机制。本研究是首次使用风车方案对整个心动周期的Vm和刺激机制进行研究,其结果对人工心脏起搏器起搏方案的开发和改进具有重要意义。