心电图的正向问题:解决了吗?
Forward problem of electrocardiography: is it solved?
作者信息
Bear Laura R, Cheng Leo K, LeGrice Ian J, Sands Gregory B, Lever Nigel A, Paterson David J, Smaill Bruce H
机构信息
From the Auckland Bioengineering Institute (L.R.B., L.K.C., I.J.L., G.B.S., N.A.L., D.J.P., B.H.S.), Department of Physiology (I.J.L., D.J.P., B.H.S.), and Department of Medicine (N.A.L.), University of Auckland, Auckland, New Zealand; L'Institut de Rythmologie et Modélisation Cardiaque IHU-LIRYC, Université de Bordeaux, CRCTB U1045; Université de Bordeaux, Centre de Recherche Cardio-Thoracique de Bordeaux U1045; and Inserm U1045, Centre de Recherche Cardio-Thoracique de Bordeaux, Bordeaux, France (L.R.B.); Green Lane Cardiovascular Service, Auckland City Hospital, Auckland, New Zealand (N.A.L.); and Department of Physiology, Anatomy, and Genetics, University of Oxford, Oxford, United Kingdom (D.J.P.).
出版信息
Circ Arrhythm Electrophysiol. 2015 Jun;8(3):677-84. doi: 10.1161/CIRCEP.114.001573. Epub 2015 Apr 1.
BACKGROUND
The relationship between epicardial and body surface potentials defines the forward problem of electrocardiography. A robust formulation of the forward problem is instrumental to solving the inverse problem, in which epicardial potentials are computed from known body surface potentials. Here, the accuracy of different forward models has been evaluated experimentally.
METHODS AND RESULTS
Body surface and epicardial potentials were recorded simultaneously in anesthetized closed-chest pigs (n=5) during sinus rhythm, and epicardial and endocardial ventricular pacing (65 records in total). Body surface potentials were simulated from epicardial recordings using experiment-specific volume conductor models constructed from magnetic resonance imaging. Results for homogeneous (isotropic electric properties) and inhomogeneous (incorporating lungs, anisotropic skeletal muscle, and subcutaneous fat) forward models were compared with measured body surface potentials. Correlation coefficients were 0.85±0.08 across all animals and activation sequences with no significant difference between homogeneous and inhomogeneous solutions (P=0.85). Despite this, there was considerable variance between simulated and measured body surface potential distributions. Differences between the body surface potential extrema predicted with homogeneous forward models were 55% to 78% greater than observed (P<0.05) and attenuation of potentials adjacent to extrema were 10% to 171% greater (P<0.03). The length and orientation of the vector between potential extrema were also significantly different. Inclusion of inhomogeneous electric properties in the forward model reduced, but did not eliminate these differences.
CONCLUSIONS
These results demonstrate that homogeneous volume conductor models introduce substantial spatial inaccuracies in forward problem solutions. This probably affects the precision of inverse reconstructions of cardiac potentials, in which this assumption is made.
背景
心外膜电位与体表电位之间的关系定义了心电图的正向问题。正向问题的稳健公式对于解决逆向问题至关重要,逆向问题是根据已知的体表电位计算心外膜电位。在此,已通过实验评估了不同正向模型的准确性。
方法与结果
在窦性心律期间,对麻醉的闭胸猪(n = 5)同时记录体表电位和心外膜电位,并进行心外膜和心室内膜起搏(共65次记录)。使用由磁共振成像构建的特定实验体积导体模型,从心外膜记录模拟体表电位。将均匀(各向同性电特性)和非均匀(纳入肺、各向异性骨骼肌和皮下脂肪)正向模型的结果与测量的体表电位进行比较。所有动物和激活序列的相关系数为0.85±0.08,均匀和非均匀解之间无显著差异(P = 0.85)。尽管如此,模拟和测量的体表电位分布之间仍存在相当大的差异。均匀正向模型预测的体表电位极值之间的差异比观察到的大55%至78%(P<0.05),极值附近电位的衰减大10%至171%(P<0.03)。电位极值之间向量的长度和方向也有显著差异。在正向模型中纳入非均匀电特性可减少但不能消除这些差异。
结论
这些结果表明,均匀体积导体模型在正向问题解决方案中引入了大量空间误差。这可能会影响在此假设下心脏电位逆向重建的精度。
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