Virtual cell and tissue dynamics of ectopic activation of the ventricles

Benson, Alan P.; Halley, Graeme; Li, Pan; Tong, Wing Chiu; Holden, Arun V.

doi:10.1063/1.2404634

Cited by 25 publications

(20 citation statements)

References 42 publications

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“…I ion in equation (1.1)) given by the rat ventricular model of Pandit et al [67], for epicardial excitation at a point analogous to that for figure 5. Space steps were 0.2 mm isotropic as defined by the DT-MRI dataset, and equation (1.1) was solved with a forward-time centred-space method using an operator splitting technique and an adaptive time step (see [26,68] for details). The qualitative similarity between the experimental and computed maps-compare figures 5a,b and 6b,c-provides a partial validation for our computational models where geometry and architecture are constructed using data obtained from DT-MRI.…”

Section: Models Of Ventricular Geometry and Simulationsmentioning

confidence: 99%

Construction and validation of anisotropic and orthotropic ventricular geometries for quantitative predictive cardiac electrophysiology

et al. 2010

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Reaction -diffusion computational models of cardiac electrophysiology require both dynamic excitation models that reconstruct the action potentials of myocytes as well as datasets of cardiac geometry and architecture that provide the electrical diffusion tensor D, which determines how excitation spreads through the tissue. We illustrate an experimental pipeline we have developed in our laboratories for constructing and validating such datasets. The tensor D changes with location in the myocardium, and is determined by tissue architecture. Diffusion tensor magnetic resonance imaging (DT-MRI) provides three eigenvectors e i and eigenvalues l i at each voxel throughout the tissue that can be used to reconstruct this architecture. The primary eigenvector e 1 is a histologically validated measure of myocyte orientation (responsible for anisotropic propagation). The secondary and tertiary eigenvectors (e 2 and e 3 ) specify the directions of any orthotropic structure if l 2 is significantly greater than l 3 -this orthotropy has been identified with sheets or cleavage planes. For simulations, the components of D are scaled in the fibre and cross-fibre directions for anisotropic simulations (or fibre, sheet and sheet normal directions for orthotropic tissues) so that simulated conduction velocities match values from optical imaging or plunge electrode experiments. The simulated pattern of propagation of action potentials in the models is partially validated by optical recordings of spatio-temporal activity on the surfaces of hearts. We also describe several techniques that enhance components of the pipeline, or that allow the pipeline to be applied to different areas of research: Q ball imaging provides evidence for multi-modal orientation distributions within a fraction of voxels, infarcts can be identified by changes in the anisotropic structure-irregularity in myocyte orientation and a decrease in fractional anisotropy, clinical imaging provides human ventricular geometry and can identify ischaemic and infarcted regions, and simulations in human geometries examine the roles of anisotropic and orthotropic architecture in the initiation of arrhythmias.

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Section: Models Of Ventricular Geometry and Simulationsmentioning

confidence: 99%

Construction and validation of anisotropic and orthotropic ventricular geometries for quantitative predictive cardiac electrophysiology

et al. 2010

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“…Integration details for the models can be found in [7]. Figure 1 shows action potentials recorded from single endocardial human cell models at 1 Hz pacing, for control and ischaemic conditions plus the component parts of ischaemia in isolation.…”

Section: Methodsmentioning

confidence: 99%

“…Parameter changes were made to simulate the individual component changes seen during ischaemia -hyperkalaemia, acidosis and anoxia -as in Shaw & Rudy [6], but with extracellular potassium during hyperkalaemia set to [K + ] o = 10 mM and with an 80% reduction in the maximal conductance of the ATP-sensitive K + current I K(ATP) to ensure realistic changes in resting membrane potential and action potential duration (APD) respectively (see Results). These cell models were incorporated into a heterogeneous 15 mm one-dimensional strand model of the human left ventricular wall [7]. Propagation of electrical excita- tion in such a model of cardiac tissue is described by…”

Section: Methodsmentioning

confidence: 99%

Quantifying the effects of ischaemia on electrophysiology and the ST segment of the ECG in human virtual ventricular cells and tissues

Benson

Hodgson

Bernus

et al. 2008

2008 Computers in Cardiology

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We have developed human virtual cell and tissue models of ischaemia, and used these models to quantify electrophysiological and ECG ST segment changes during subendocardial and global ischaemia. Our investigation has highlighted key differences with previous computational studies based on animal models: (i) propagation failure in the human model occurs with a smaller degree of hyperkalaemia compared to previously used animal models, due to differences in sodium channels kinetics; (ii) the human model is more sensitive to repolarising potassium currents during phase 3 repolarisation than the previously used animal models, and therefore the magnitude of the ATPsensitive potassium current must be smaller in the human model to produce similar changes in action potential duration during ischaemia; and (iii) unlike in animal models where hyperkalaemia was identified as the major component of ST segment depression, we find in the human model that both anoxia and hyperkalaemia are responsible.

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“…Such wedge and whole ventricle simulations of cardiac electrophysiology are now tractable and extremely useful, as the data they provide can be dissected in time and space, and by parameters. This allows a detailed examination of the effects of cardiac structure on propagation of excitation [9], the elucidation of mechanisms underlying arrhythmias [7,8,15], and gives an additional means of interpreting the results from experimental studies [59]. Propagation of electrical excitation in cardiac tissue can be described by the non-linear cable equation, a reaction-diffusion-type partial differential equation:…”

Section: Introductionmentioning

confidence: 99%

Reconstruction and Quantification of Diffusion Tensor Imaging-Derived Cardiac Fibre and Sheet Structure in Ventricular Regions used in Studies of Excitation Propagation

Benson

Gilbert

et al. 2008

Math. Model. Nat. Phenom.

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Abstract. Detailed descriptions of cardiac geometry and architecture are necessary for examining and understanding structural changes to the myocardium that are the result of pathologies, for interpreting the results of experimental studies of propagation, and for use as a three-dimensional orthotropically anisotropic model for the computational reconstruction of propagation during arrhythmias. Diffusion tensor imaging (DTI) provides a means to reconstruct fibre and sheet orientation throughout the ventricles. We reconstruct and quantify canine cardiac architecture in selected regions of the left and right ventricular free walls and the inter-ventricular septum. Fibre inclination angle rotates smoothly through the wall in all regions, from positive in the endocardium to negative in the epicardium. However, fibre transverse and sheet angles show large variability in basal regions. Additionally, regions where two populations (positive and negative) of sheet structure merge are identified. From these data, we conclude that a single DTI-derived atlas model of ventricular architecture should be applicable to modelling propagation in wedges from the equatorial and apical left ventricle, and allow comparisons to experimental studies carried out in wedge preparations. However, due to inter-individual variability in basal regions, a library of individual DTI models of basal wedges or of the whole ventricles will be required.

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Virtual cell and tissue dynamics of ectopic activation of the ventricles

Cited by 25 publications

References 42 publications

Construction and validation of anisotropic and orthotropic ventricular geometries for quantitative predictive cardiac electrophysiology

Construction and validation of anisotropic and orthotropic ventricular geometries for quantitative predictive cardiac electrophysiology

Quantifying the effects of ischaemia on electrophysiology and the ST segment of the ECG in human virtual ventricular cells and tissues

Reconstruction and Quantification of Diffusion Tensor Imaging-Derived Cardiac Fibre and Sheet Structure in Ventricular Regions used in Studies of Excitation Propagation

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