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希氏束起搏时 His-Purkinje 系统的厚度出现纵向分离和转变,导致体表心电图出现各种 QRS 波形态:基于临床观察的模拟研究。

Longitudinal dissociation and transition in thickness of the His-Purkinje system cause various QRS waveforms of surface ECG under His bundle pacing: A simulation study based on clinical observations.

机构信息

UT-Heart Inc, Setagaya-ku, Tokyo, Japan.

The University of Tokyo Future Center Initiative, Kashiwa, Chiba, Japan.

出版信息

J Cardiovasc Electrophysiol. 2019 Nov;30(11):2582-2590. doi: 10.1111/jce.14191. Epub 2019 Sep 27.

DOI:10.1111/jce.14191
PMID:31535752
Abstract

AIMS

His bundle pacing (HBP) is a feasible and reliable alternative to conventional right ventricular pacing (RVP), but associated ECG (electrocardiogram) changes have not been well-studied. This study aimed to determine the mechanisms underlying ECG changes associated with HBP using patient-specific multiscale heart simulations.

METHODS

ECGs were recorded in two patients who were treated by HBP under a native rhythm and HBP at high and low voltages. We created patient-specific multiscale simulation heart models of these patients and performed ECG simulation under these conditions. Using these results and detailed information on the electrical field around the pacing lead, we investigated mechanisms underlying the observed ECG changes.

RESULTS

Heart simulations successfully reproduced ECGs under a native rhythm for both cases. In case 1, nonselective HBP produced a left bundle branch (LBB) block pattern, which was reproduced as a selective right bundle branch (RBB) pacing. However, in case 2, ECG under nonselective HBP showed an RBB block pattern, which could not be reproduced by the commonly used framework. Findings on the electrical field and anatomy of the His bundle and its branches suggested that longitudinal dissociation of the His bundle and transition of thickness in the stem of the LBB caused a conduction delay in the RBB to produce these ECG changes in this patient.

CONCLUSION

Variations in the anatomy of the His bundle and its branches may underlie the diverse ECG responses to HBP. These variations should be taken into account when performing this therapy.

摘要

目的

希氏束起搏(HBP)是一种可行且可靠的替代传统右心室起搏(RVP)的方法,但与之相关的心电图(ECG)变化尚未得到充分研究。本研究旨在使用患者特异性心脏多尺度模拟来确定与 HBP 相关的心电图变化的机制。

方法

对两名接受希氏束起搏治疗的患者(在窦性心律下和高、低电压下进行 HBP)进行了心电图记录。我们为这两名患者创建了患者特异性心脏多尺度模拟模型,并在这些条件下进行了心电图模拟。利用这些结果和起搏导线周围电场的详细信息,我们研究了观察到的心电图变化的机制。

结果

心脏模拟成功地再现了这两个病例的窦性心律下的心电图。在病例 1 中,非选择性 HBP 产生了左束支(LBB)阻滞模式,这被再现为选择性右束支(RBB)起搏。然而,在病例 2 中,非选择性 HBP 下的心电图显示出 RBB 阻滞模式,这不能用常用的框架来再现。对希氏束及其分支的电场和解剖结构的研究结果表明,希氏束的纵向分离和 LBB 干的厚度变化导致了 RBB 的传导延迟,从而在该患者中产生了这些心电图变化。

结论

希氏束及其分支的解剖结构的变化可能是 HBP 引起不同心电图反应的基础。在进行这种治疗时,应考虑这些变化。

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Longitudinal dissociation and transition in thickness of the His-Purkinje system cause various QRS waveforms of surface ECG under His bundle pacing: A simulation study based on clinical observations.希氏束起搏时 His-Purkinje 系统的厚度出现纵向分离和转变,导致体表心电图出现各种 QRS 波形态:基于临床观察的模拟研究。
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