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室性心动过速期间折返环不同区域细胞的重塑。

Remodeling in cells from different regions of the reentrant circuit during ventricular tachycardia.

作者信息

Baba Shigeo, Dun Wen, Cabo Candido, Boyden Penelope A

机构信息

Department of Pharmacology, Center for Molecular Therapeutics, Columbia University, New York, NY, USA.

出版信息

Circulation. 2005 Oct 18;112(16):2386-96. doi: 10.1161/CIRCULATIONAHA.105.534784. Epub 2005 Oct 3.

DOI:10.1161/CIRCULATIONAHA.105.534784

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4289139/

Abstract

BACKGROUND

Anisotropic reentrant excitation occurs in the remodeled substrate of the epicardial border zone (EBZ) of the 5-day infarcted canine heart. Reentry is stabilized because of the formation of functional lines of block. We hypothesized that regional differences of ionic currents in cells of the EBZ form these lines of block. Therefore, we first mapped reentrant circuits of sustained tachycardias, then dispersed cells (infarct zone cells, IZs) from the central common pathway of the circuit (IZc) as well as from the other side of the line of block (outer pathway, IZo) for study.

METHODS AND RESULTS

We mapped reentrant circuits in the EBZ of infarcted hearts during sustained ventricular tachycardias (>30 seconds, n=17 episodes, cycle lengths=218+/-7.9 ms). INa density was reduced in both IZc and IZo, and the kinetic properties of IZc INa were markedly altered versus IZo. Structural remodeling of the sodium channel protein Nav1.5 occurred in IZs, with cell surface localization differing from normal cells. Both IZc and IZo have similar but reduced ICaL, whereas IZc showed changes in Ca2+ current kinetics with an acceleration of current decay. Computer simulations of the 2D EBZ showed that incorporating only differences between INa in IZc and IZo prevented stability of the reentrant circuit. Incorporating only differences between ICaL in the IZc and IZo cells also prevented stability of the circuit. However, incorporating both INa and ICaL current differences stabilized the simulated reentrant circuit, and lines of block formed between the 2 distinct regions.

CONCLUSIONS

Despite differences in INa and ICaL properties in cells of the center and outer pathways of a reentrant circuit, the resulting changes in effective refractory periods tend to stabilize reentry in this remodeled substrate.

摘要

背景

各向异性折返激动发生在梗死后5天的犬心外膜边界区（EBZ）的重塑基质中。由于功能性阻滞线的形成，折返得以稳定。我们推测EBZ细胞中离子电流的区域差异形成了这些阻滞线。因此，我们首先绘制了持续性心动过速的折返环路，然后从环路的中央共同径路（IZc）以及阻滞线的另一侧（外侧径路，IZo）分离细胞（梗死区细胞，IZs）进行研究。

方法与结果

我们在持续性室性心动过速（>30秒，n = 17次发作，周期长度 = 218±7.9毫秒）期间绘制了梗死心脏EBZ中的折返环路。IZc和IZo中的钠电流密度均降低，与IZo相比，IZc钠电流的动力学特性发生了显著改变。梗死区钠通道蛋白Nav1.5发生了结构重塑，其细胞表面定位与正常细胞不同。IZc和IZo的L型钙电流（ICaL）相似但降低，而IZc的钙电流动力学发生了变化，电流衰减加速。二维EBZ的计算机模拟显示，仅纳入IZc和IZo之间钠电流的差异会阻止折返环路的稳定性。仅纳入IZc和IZo细胞之间ICaL的差异也会阻止环路的稳定性。然而，同时纳入钠电流和ICaL电流差异可使模拟的折返环路稳定，并在两个不同区域之间形成阻滞线。

结论

尽管折返环路中央和外侧径路细胞中的钠电流和ICaL特性存在差异，但有效不应期的相应变化倾向于使这种重塑基质中的折返稳定。