确定猪心肌梗死计算心室模型的解剖和电生理细节要求。

Determining anatomical and electrophysiological detail requirements for computational ventricular models of porcine myocardial infarction.

机构信息

Department of Biomedical Engineering, School of Biomedical Engineering & Imaging Sciences, King's College London, UK.

出版信息

Comput Biol Med. 2022 Feb;141:105061. doi: 10.1016/j.compbiomed.2021.105061. Epub 2021 Nov 26.

DOI:10.1016/j.compbiomed.2021.105061

PMID:34915331

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8819160/

Abstract

BACKGROUND

Computational models of the heart built from cardiac MRI and electrophysiology (EP) data have shown promise for predicting the risk of and ablation targets for myocardial infarction (MI) related ventricular tachycardia (VT), as well as to predict paced activation sequences in heart failure patients. However, most recent studies have relied on low resolution imaging data and little or no EP personalisation, which may affect the accuracy of model-based predictions.

OBJECTIVE

To investigate the impact of model anatomy, MI scar morphology, and EP personalisation strategies on paced activation sequences and VT inducibility to determine the level of detail required to make accurate model-based predictions.

METHODS

Imaging and EP data were acquired from a cohort of six pigs with experimentally induced MI. Computational models of ventricular anatomy, incorporating MI scar, were constructed including bi-ventricular or left ventricular (LV) only anatomy, and MI scar morphology with varying detail. Tissue conductivities and action potential duration (APD) were fitted to 12-lead ECG data using the QRS duration and the QT interval, respectively, in addition to corresponding literature parameters. Paced activation sequences and VT induction were simulated. Simulated paced activation and VT inducibility were compared between models and against experimental data.

RESULTS

Simulations predict that the level of model anatomical detail has little effect on simulated paced activation, with all model predictions comparing closely with invasive EP measurements. However, detailed scar morphology from high-resolution images, bi-ventricular anatomy, and personalized tissue conductivities are required to predict experimental VT outcome.

CONCLUSION

This study provides clear guidance for model generation based on clinical data. While a representing high level of anatomical and scar detail will require high-resolution image acquisition, EP personalisation based on 12-lead ECG can be readily incorporated into modelling pipelines, as such data is widely available.

摘要

背景

基于心脏磁共振和电生理学（EP）数据构建的心脏计算模型已显示出预测心肌梗死（MI）相关室性心动过速（VT）风险和消融靶点的潜力，以及预测心力衰竭患者起搏激活序列的潜力。然而，最近的大多数研究都依赖于低分辨率的成像数据和很少或没有 EP 个性化，这可能会影响基于模型预测的准确性。

目的

研究模型解剖结构、MI 疤痕形态和 EP 个性化策略对起搏激活序列和 VT 可诱导性的影响，以确定进行准确基于模型预测所需的详细程度。

方法

从一组患有实验性 MI 的六头猪中获取成像和 EP 数据。构建了包含心室解剖结构的计算模型，包括双心室或左心室（LV）仅解剖结构，以及具有不同细节的 MI 疤痕形态。使用 QRS 持续时间和 QT 间期分别拟合组织电导率和动作电位持续时间（APD）到 12 导联心电图数据，此外还使用了相应的文献参数。模拟起搏激活和 VT 诱导。比较模型之间以及与实验数据之间的模拟起搏激活和 VT 可诱导性。

结果

模拟预测模型解剖细节水平对模拟起搏激活的影响很小，所有模型预测与侵入性 EP 测量结果非常接近。然而，需要详细的疤痕形态从高分辨率图像，双心室解剖结构和个性化组织电导率来预测实验性 VT 结果。

结论

这项研究为基于临床数据的模型生成提供了明确的指导。虽然代表高水平的解剖学和疤痕细节将需要高分辨率的图像采集，但基于 12 导联心电图的 EP 个性化可以很容易地纳入建模管道，因为这种数据广泛可用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e20c/8819160/0a297595b608/gr1.jpg

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确定猪心肌梗死计算心室模型的解剖和电生理细节要求。

Determining anatomical and electrophysiological detail requirements for computational ventricular models of porcine myocardial infarction.

机构信息

出版信息

BACKGROUND

OBJECTIVE

METHODS

RESULTS

CONCLUSION

背景

目的

方法

结果

结论

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