Activation and repolarization of the normal human heart under complete physiological conditions

Ramanathan, Charulatha; Jia, Ping; Ghanem, Raja N.; Ryu, Kyungmoo; Rudy, Yoram

doi:10.1073/pnas.0601533103

Cited by 226 publications

(204 citation statements)

References 29 publications

(55 reference statements)

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“…The leading pacemaker site can, however, move spontaneously along the terminal crest of the right atrium, a phenomenon known as the wandering pacemaker. In open heart surgery, patients and in healthy individuals, the leading pacemaker site has been shown to be located anywhere along the terminal crest between the openings of the superior and inferior caval veins (Boineau et al, 1988;Ramanathan et al, 2004;Ramanathan et al, 2006). Such findings are in agreement with studies on smaller mammals.…”

Section: Introductionsupporting

confidence: 82%

Computer Three‐Dimensional Anatomical Reconstruction of the Human Sinus Node and a Novel Paranodal Area

Chandler

Aslanidi

Buckley

et al. 2011

The Anatomical Record

100

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We have previously shown in rabbit that the pacemaker of the heart (the sinus node) is widespread and matches the wide distribution of the leading pacemaker site within the right atrium. There is, however, uncertainty about the precise location of the pacemaker in human heart, and its spatial relationships with the surrounding right atrial muscle. Therefore, the aim of the current study was to investigate the distribution of the sinus node tissue in a series of healthy human hearts and, for one of the hearts to construct a computer three-dimensional anatomical model of the sinus node, including the likely orientation of myocytes. A combination of experimental techniques-diffusion tensor magnetic resonance imaging (DT-MRI), histology, immunohistochemistry, image processing and computer modelling-was used. Our data show that the sinus node was larger than in previous studies and, most importantly, we identified a previously unknown area running alongside the sinus node (the ''paranodal area"), which is even more extensive than the sinus node. This area possesses properties of both nodal and atrial tissues and may have a role in pacemaking. For example, it could explain the wide spread distribution of the leading pacemaker site in human right atrium, a phenomenon known as the wandering pacemaker observed in clinics. In summary, a Additional Supporting Information may be found in the online version of this article.Abbreviations used: AM ¼ Atrial muscle; ANP ¼ Atrial natriuretic peptide; Ao ¼ Aorta; Cx40, Cx43 ¼ Connexin 40 and 43; 3D ¼ Three-dimensional; DT-MRI ¼ Diffusion tensor magnetic resonance imaging; HCN4 ¼ Ion channel responsible for hyperpolarization-activated or 'funny' current, I f ; IVC ¼ Inferior vena cava; Kir2.1 ¼ Ion channel responsible for background inward rectifier K þ current, I K1 ; Kir6.2 ¼ Ion channel responsible for ATP-sensitive K þ current, I KATP ; Kv1.4 ¼ Ion channel responsible for transient outward K þ current, I to ; LAA ¼ Left atrial appendage; MiRP2 ¼ Accessory protein for K þ channels; N av1.5, Nav 1 ¼ Na þ channel responsible for inward Na þ current, I Na ; PA ¼ Pulmonary artery; PV ¼ Pulmonary vein; RA ¼ Right atrium; RAA ¼ Right atrial appendage; RV ¼ Right ventricle; SCV ¼ Superior caval vein; SK2 ¼ Ion channel responsible for Ca 2þ -activated K þ current, I KCa ; TASK1 Twin-pore domain K þ channel; Tbx3 ¼ Transcription factor; TC ¼ Terminal crest.

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Section: Introductionsupporting

confidence: 82%

Computer Three‐Dimensional Anatomical Reconstruction of the Human Sinus Node and a Novel Paranodal Area

Chandler

Aslanidi

Buckley

et al. 2011

The Anatomical Record

100

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“…Recent investigations in humans have confirmed that the earliest epicardial electrical break-through occurs in the right ventricular free wall and the anterior LV wall, and then travels in an apex-to-base direction (36). The basal posterior wall is the last region to be activated, which occurs during the down-slope of the R-wave (36). The timing and sequence of electrical excitation in the ventricles is influenced by the impulse propagating through the His-Purkinje system and the anistropic nature of myocardium where propagation velocities are faster along rather than across the fibers (35,37).…”

Section: Electrical Sequence Depolarizationmentioning

confidence: 98%

Section: Electrical Sequence Depolarizationmentioning

confidence: 99%

Left Ventricular Form and Function Revisited: Applied Translational Science to Cardiovascular Ultrasound Imaging

Sengupta

Krishnamoorthy

Kořínek

et al. 2007

Journal of the American Society of Echocardiography

283

196

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Tissue Doppler imaging (TDI) and TDI-derived strain imaging are robust physiologic tools used for the noninvasive assessment of regional myocardial function. Due to high temporal and spatial resolution, regional function can be assessed for each phase of the cardiac cycle and within the transmural layers of the myocardial wall. Newer techniques that measure myocardial motion by speckle tracking in grayscale images have overcome the angle dependence of TDI strain, allowing for measurement of 2-dimensional strain and cardiac rotation. TDI, TDI strain, and speckle tracking may provide unique information that deciphers the deformation sequence of complexly oriented myofibers in the left ventricular wall. The data are, however, limited. This review examines the structure and function of the left ventricle relative to the potential clinical application of TDI and speckle tracking in assessing the global mechanical sequence of the left ventricle in vivo.The spiral arrangement of muscle fibers in the heart is reminiscent of spiral and vortex patterns in nature, ranging from small organelles and whirlpools to hurricanes and rotational patterns of the galaxies (1-5). Vortex patterns link two fundamental forms of motion that work in close balance: an inner, rapidly descending swirl and an outer, less rapid, ascending rotation (4) ( Fig. 1 A-C). These counterdirectional movements of a vortex produce suction and expulsion forces that have been exploited for designing energy efficient propellers and turbines (6). Likewise, experimental and mathematical modeling of the clockwise and counterclockwise spiral loops of myofibers in the left ventricle (LV) has shown that counterdirectional geometry provides an efficient distribution of regional stresses and strains (7). Conversely, altered ventricular geometry resulting from cardiac remodeling, regional myocardial dysfunction, or asynchronous conduction distort the efficiency of the loading and expulsion dynamics (8,9). In this review, we associate the LV myofiber architecture to the spatiotemporal sequence of regional deformations occurring during normal cardiac contraction and relaxation. We further elucidate experimental observations, which explore the application of tissue Doppler imaging (TDI) and 2-dimensional ultrasound speckle tracking for delineation of the synchronous mechanical shortening and lengthening sequences of the human LV.Address reprint requests to Marek Belohlavek, Division of Cardiovascular Diseases, Mayo Clinic, 13400 East Shea Boulevard Scottsdale, AZ 85259, E-mail address for author named in reprint line: Belohlavek.marek@mayo.edu Publisher's Disclaimer: This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect th...

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“…28,43,58,60 Recently, both the potential-based approach (for computing epicardial potentials, electrograms, and isochrones) and the activation-time approach were applied and evaluated in human subjects. 28,33,47,49,[57][58][59][60]65,67,[77][78][79] Both methods require discretizing the heart and torso surfaces into continuous non-overlapping mesh elements, a procedure called meshing. Meshing is difficult to apply to irregular surfaces 37 and can introduce mesh-related artifacts, especially in the computation of solutions to the ill-posed 76 electrocardiographic problem, if mesh optimization is not carefully done.…”

Section: Introductionmentioning

confidence: 99%

Application of the Method of Fundamental Solutions to Potential-based Inverse Electrocardiography

2006

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Potential-based inverse electrocardiography is a method for the noninvasive computation of epicardial potentials from measured body surface electrocardiographic data. From the computed epicardial potentials, epicardial electrograms and isochrones (activation sequences), as well as repolarization patterns can be constructed. We term this noninvasive procedure Electrocardiographic Imaging (ECGI). The method of choice for computing epicardial potentials has been the Boundary Element Method (BEM) which requires meshing the heart and torso surfaces and optimizing the mesh, a very time-consuming operation that requires manual editing. Moreover, it can introduce mesh-related artifacts in the reconstructed epicardial images. Here we introduce the application of a meshless method, the Method of Fundamental Solutions (MFS) to ECGI. This new approach that does not require meshing is evaluated on data from animal experiments and human studies, and compared to BEM. Results demonstrate similar accuracy, with the following advantages: 1. Elimination of meshing and manual mesh optimization processes, thereby enhancing automation and speeding the ECGI procedure. 2. Elimination of mesh-induced artifacts. 3. Elimination of complex singular integrals that must be carefully computed in BEM. 4. Simpler implementation. These properties of MFS enhance the practical application of ECGI as a clinical diagnostic tool.

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Activation and repolarization of the normal human heart under complete physiological conditions

Cited by 226 publications

References 29 publications

Computer Three‐Dimensional Anatomical Reconstruction of the Human Sinus Node and a Novel Paranodal Area

Computer Three‐Dimensional Anatomical Reconstruction of the Human Sinus Node and a Novel Paranodal Area

Left Ventricular Form and Function Revisited: Applied Translational Science to Cardiovascular Ultrasound Imaging

Application of the Method of Fundamental Solutions to Potential-based Inverse Electrocardiography

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