确定心脏双域电导率值的方法:进展与挑战。
Approaches for determining cardiac bidomain conductivity values: progress and challenges.
机构信息
School of Environment and Science, and Queensland Micro- and Nanotechnology Centre, Griffith University, Nathan, QLD, 4111, Australia.
出版信息
Med Biol Eng Comput. 2020 Dec;58(12):2919-2935. doi: 10.1007/s11517-020-02272-z. Epub 2020 Oct 22.
Abstract
Modelling the electrical activity of the heart is an important tool for understanding electrical function in various diseases and conduction disorders. Clearly, for model results to be useful, it is necessary to have accurate inputs for the models, in particular the commonly used bidomain model. However, there are only three sets of four experimentally determined conductivity values for cardiac ventricular tissue and these are inconsistent, were measured around 40 years ago, often produce different results in simulations and do not fully represent the three-dimensional anisotropic nature of cardiac tissue. Despite efforts in the intervening years, difficulties associated with making the measurements and also determining the conductivities from the experimental data have not yet been overcome. In this review, we summarise what is known about the conductivity values, as well as progress to date in meeting the challenges associated with both the mathematical modelling and the experimental techniques. Graphical abstract Epicardial potential distributions, arising from a subendocardial ischaemic region, modelled using conductivity data from the indicated studies.
摘要
心脏电活动建模是理解各种疾病和传导障碍中心电功能的重要工具。显然,为了使模型结果有用,有必要为模型提供准确的输入,特别是常用的双域模型。然而,只有三组四个实验确定的心脏心室组织电导率值,而且这些值不一致,是在大约 40 年前测量的,在模拟中经常产生不同的结果,并且不能完全表示心脏组织的三维各向异性性质。尽管在这期间进行了努力,但在进行测量以及从实验数据中确定电导率方面的困难尚未克服。在这篇综述中,我们总结了已知的电导率值,以及在应对与数学建模和实验技术相关的挑战方面的最新进展。
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