通过单极电极连续刺激心脏组织后出现的非持续性折返。

Nonsustained reentry following successive stimulation of cardiac tissue through a unipolar electrode.

作者信息

Roth B J

机构信息

Dept. of Physics & Astronomy: Vanderbilt University, Nashville, TN 37235, USA.

出版信息

J Cardiovasc Electrophysiol. 1997 Jul;8(7):768-78. doi: 10.1111/j.1540-8167.1997.tb00835.x.

DOI:10.1111/j.1540-8167.1997.tb00835.x

PMID:9255684

Abstract

INTRODUCTION

Using numerical simulations, we predict that nonsustained reentry occurs following a strong, premature stimulus through a unipolar electrode.

METHODS AND RESULTS

Our simulations were based on the bidomain model of cardiac tissue, and the active membrane properties were represented by the Beeler-Reuter model. An outwardly propagating wavefront was excited by an initial stimulus (S1). A second stimulus (S2) was then applied through the same electrode. Nonsustained reentry or reentrant-like behavior followed the S2 stimulus for both cathodal and anodal stimulation, and were associated with "break" stimulation but not with "make" stimulation. The direction of spiral-wave rotation was reversed when the polarity of the stimulus was reversed. These complex dynamics occur only for a narrow window of S1-S2 intervals. During anodal S2 stimulation, two different modes of reentry exist. Our simulations also explain the "no response" phenomenon.

CONCLUSION

Our mathematical model predicts that both anodal and cathodal unipolar S2 stimulation results in reentry. This behavior arises from an interaction of virtual anodes and cathodes surrounding the stimulating electrode.

摘要

引言

通过数值模拟，我们预测在通过单极电极施加强的过早刺激后会发生非持续性折返。

方法与结果

我们的模拟基于心脏组织的双域模型，活性膜特性由Beeler-Reuter模型表示。初始刺激（S1）激发向外传播的波前。然后通过同一电极施加第二个刺激（S2）。对于阴极和阳极刺激，S2刺激后均出现非持续性折返或类似折返的行为，且与“断”刺激相关，而与“通”刺激无关。当刺激极性反转时，螺旋波旋转方向也反转。这些复杂动力学仅在S1 - S2间期的狭窄窗口内出现。在阳极S2刺激期间，存在两种不同的折返模式。我们的模拟还解释了“无反应”现象。

结论

我们的数学模型预测，阳极和阴极单极S2刺激均会导致折返。这种行为源于刺激电极周围虚拟阳极和阴极的相互作用。

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通过单极电极连续刺激心脏组织后出现的非持续性折返。

Nonsustained reentry following successive stimulation of cardiac tissue through a unipolar electrode.

作者信息

机构信息

出版信息

INTRODUCTION

METHODS AND RESULTS

CONCLUSION

引言

方法与结果

结论

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