Christopher M. Andrews, B. Cupps, M. Pasque, Y. Rudy
{"title":"Electromechanics of the Normal Human Heart In Situ.","authors":"Christopher M. Andrews, B. Cupps, M. Pasque, Y. Rudy","doi":"10.1161/CIRCEP.119.007484","DOIUrl":null,"url":null,"abstract":"November 2019 1 Knowledge of the spatiotemporal relationship between electrical excitation and mechanical contraction in the human heart is essential for understanding cardiac physiology and disease. However, electromechanical data from nondiseased human hearts are currently lacking. The present study is the first to combine Electrocardiographic Imaging (ECGI; a noninvasive method for cardiac electrophysiology mapping) with tagged magnetic resonance imaging (MRI) to study the electromechanics of healthy adult hearts in situ. This also represents the largest ECGI study of healthy adults to date. We provide 3-dimensional data of the normal cardiac electrical and mechanical activation sequences, obtained from the same hearts under complete physiological conditions. These are important baseline data for studies and diagnosis of cardiac disorders and for constraining computer models of the human heart. Twenty healthy adults were enrolled at Washington University in St. Louis. Healthy volunteer demographics are provided in Table I in the Data Supplement. The study was approved by the Human Research Protection Office at Washington University in St. Louis. All participants provided written informed consent. Data are available upon reasonable request. The ECGI method, developed and validated in our laboratory, was described previously.1 A schematic of the procedure is presented in Figure I in the Data Supplement. The method consists of recording ≈250 simultaneous ECGs from the torso, using electrode strips. Heart-torso geometries of subjects were imaged using a navigated anatomic MRI sequence. Electrode positions were marked with MRIvisible capsules. ECG recordings were combined with the heart-torso geometries to construct epicardial potentials and unipolar epicardial electrograms. Local activation times were computed from electrograms using the minimum dV/dt during the QRS, and recovery times using the maximum dV/dt during the T wave. Activation-recovery intervals (ARIs), a surrogate of local action potential duration, were computed by subtracting the local activation time from the local recovery time. Activation and recovery maps were edited based on overall sequence and neighboring electrograms. Tagged MR images were obtained and analyzed using previously described methods.2 ECG-gated images were obtained in short-axis and long-axis views for a complete cardiac cycle beginning at end diastole. Tagged and nontagged images were acquired during the same breath hold to ensure similar anatomic positioning. Tag lines in the myocardium were tracked and 3-dimensional displacements were calculated from the movement of intramural tag surface intersection points during systole. StressCheck software (ESRD, Inc, St. Louis, MO) was used to compute strain values throughout the left ventricle. Additional details of the ECGI and tagged MRI analyses are provided in the Data Supplement. SPECIAL REPORT","PeriodicalId":10167,"journal":{"name":"Circulation: Arrhythmia and Electrophysiology","volume":"223 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2019-11-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"5","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Circulation: Arrhythmia and Electrophysiology","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1161/CIRCEP.119.007484","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 5
Abstract
November 2019 1 Knowledge of the spatiotemporal relationship between electrical excitation and mechanical contraction in the human heart is essential for understanding cardiac physiology and disease. However, electromechanical data from nondiseased human hearts are currently lacking. The present study is the first to combine Electrocardiographic Imaging (ECGI; a noninvasive method for cardiac electrophysiology mapping) with tagged magnetic resonance imaging (MRI) to study the electromechanics of healthy adult hearts in situ. This also represents the largest ECGI study of healthy adults to date. We provide 3-dimensional data of the normal cardiac electrical and mechanical activation sequences, obtained from the same hearts under complete physiological conditions. These are important baseline data for studies and diagnosis of cardiac disorders and for constraining computer models of the human heart. Twenty healthy adults were enrolled at Washington University in St. Louis. Healthy volunteer demographics are provided in Table I in the Data Supplement. The study was approved by the Human Research Protection Office at Washington University in St. Louis. All participants provided written informed consent. Data are available upon reasonable request. The ECGI method, developed and validated in our laboratory, was described previously.1 A schematic of the procedure is presented in Figure I in the Data Supplement. The method consists of recording ≈250 simultaneous ECGs from the torso, using electrode strips. Heart-torso geometries of subjects were imaged using a navigated anatomic MRI sequence. Electrode positions were marked with MRIvisible capsules. ECG recordings were combined with the heart-torso geometries to construct epicardial potentials and unipolar epicardial electrograms. Local activation times were computed from electrograms using the minimum dV/dt during the QRS, and recovery times using the maximum dV/dt during the T wave. Activation-recovery intervals (ARIs), a surrogate of local action potential duration, were computed by subtracting the local activation time from the local recovery time. Activation and recovery maps were edited based on overall sequence and neighboring electrograms. Tagged MR images were obtained and analyzed using previously described methods.2 ECG-gated images were obtained in short-axis and long-axis views for a complete cardiac cycle beginning at end diastole. Tagged and nontagged images were acquired during the same breath hold to ensure similar anatomic positioning. Tag lines in the myocardium were tracked and 3-dimensional displacements were calculated from the movement of intramural tag surface intersection points during systole. StressCheck software (ESRD, Inc, St. Louis, MO) was used to compute strain values throughout the left ventricle. Additional details of the ECGI and tagged MRI analyses are provided in the Data Supplement. SPECIAL REPORT
1了解人类心脏电兴奋和机械收缩之间的时空关系对于理解心脏生理学和疾病至关重要。然而,目前缺乏来自未患病人类心脏的机电数据。本研究首次将心电图成像(ECGI;用标记磁共振成像(MRI)原位研究健康成人心脏的电力学。这也是迄今为止对健康成人进行的最大规模的ECGI研究。我们提供了在完全生理条件下从同一颗心脏获得的正常心脏电和机械激活序列的三维数据。这些是研究和诊断心脏疾病以及限制人类心脏的计算机模型的重要基线数据。20名健康的成年人在圣路易斯的华盛顿大学注册。健康志愿者的人口统计资料载于《数据补充》表一。这项研究得到了圣路易斯华盛顿大学人类研究保护办公室的批准。所有参与者均提供书面知情同意书。如有合理要求,可提供资料。ECGI方法,在我们的实验室开发和验证,前面有描述该过程的示意图见数据补充中的图1。该方法包括使用电极条从躯干同时记录约250个心电图。使用导航解剖MRI序列对受试者的心脏-躯干几何形状进行成像。用mri可见胶囊标记电极位置。心电图记录与心躯干几何形状相结合,构建心外膜电位和单极心外膜电图。局部激活时间用QRS期间最小dV/dt的电图计算,恢复时间用T波期间最大dV/dt的电图计算。激活-恢复间隔(ARIs)是局部动作电位持续时间的替代物,通过从局部恢复时间减去局部激活时间来计算。激活和恢复图是根据整个序列和邻近的电图编辑的。使用先前描述的方法获得标记的MR图像并进行分析心电门控图像在短轴和长轴视图获得完整的心脏周期从舒张末期开始。在同一屏气期间获得标记和未标记的图像,以确保相似的解剖定位。跟踪心肌内的标签线,并根据收缩期内标签面交点的运动计算三维位移。使用StressCheck软件(ESRD, Inc, St. Louis, MO)计算整个左心室的应变值。ECGI和标记MRI分析的更多细节见数据补充。特别报道