Organization of ventricular fibrillation in the human heart: experiments and models

Tusscher, Kirsten H. W. J. ten; Mourad, Ayman; Nash, Martyn P.; Clayton, Richard H.; Bradley, C P; Paterson, DJ; Hren, R.; Hayward, Martin; Panfilov, Alexander V.; Taggart, Peter

doi:10.1113/expphysiol.2008.044065

Cited by 76 publications

(77 citation statements)

References 41 publications

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“…Sudden cardiac death caused by cardiac arrhythmias is the most common cause of death in the industrialized world, and, in most cases, this is due to ventricular fibrillation (VF) (73). It has been shown in clinical and experimental studies (11,17,26,41,46,62,68,70) that VF occurs as a result of the onset of turbulent electrical activation patterns of the heart that are underpinned by multiple reentrant sources of excitation. Mechanisms behind the onset of reentrant sources in the heart and processes resulting in breakup of these sources into complex turbulent activation patterns are of great interest, e.g., in the design of therapeutic strategies to prevent or treat cardiac arrhythmias.…”

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confidence: 99%

Electromechanical wavebreak in a model of the human left ventricle

Keldermann

Nash

Gelderblom

et al. 2010

American Journal of Physiology-Heart and Circulatory Physiology

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100

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Keldermann RH, Nash MP, Gelderblom H, Wang VY, Panfilov AV. Electromechanical wavebreak in a model of the human left ventricle. Am J Physiol Heart Circ Physiol 299: H134 -H143, 2010. First published April 16, 2010; doi:10.1152/ajpheart.00862.2009In the present report, we introduce an integrative three-dimensional electromechanical model of the left ventricle of the human heart. Electrical activity is represented by the ionic TP06 model for human cardiac cells, and mechanical activity is represented by the NiedererHunter-Smith active contractile tension model and the exponential Guccione passive elasticity model. These models were embedded into an anatomic model of the left ventricle that contains a detailed description of cardiac geometry and the fiber orientation field. We demonstrated that fiber shortening and wall thickening during normal excitation were qualitatively similar to experimental recordings. We used this model to study the effect of mechanoelectrical feedback via stretch-activated channels on the stability of reentrant wave excitation. We found that mechanoelectrical feedback can induce the deterioration of an otherwise stable spiral wave into turbulent wave patterns similar to that of ventricular fibrillation. We identified the mechanisms of this transition and studied the three-dimensional organization of this mechanically induced ventricular fibrillation. ventricular fibrillation; computer simulations; mechanics; electrophysiology; mechanoelectrical feedback; stretch-activated channels MECHANICAL ACTIVITY of the heart is initiated by electrical waves of excitation that propagate through the heart and initiate cardiac contraction. Abnormal excitation of the heart may result in cardiac arrhythmias and the loss of mechanical pump function, leading to sudden cardiac death. Sudden cardiac death caused by cardiac arrhythmias is the most common cause of death in the industrialized world, and, in most cases, this is due to ventricular fibrillation (VF) (73). It has been shown in clinical and experimental studies (11,17,26,41,46,62,68,70) that VF occurs as a result of the onset of turbulent electrical activation patterns of the heart that are underpinned by multiple reentrant sources of excitation. Mechanisms behind the onset of reentrant sources in the heart and processes resulting in breakup of these sources into complex turbulent activation patterns are of great interest, e.g., in the design of therapeutic strategies to prevent or treat cardiac arrhythmias.One of the important factors that affects electrical excitation of the heart is mechanoelectrical feedback. It has been shown that mechanical deformation alters the electrical properties of myocytes via stretch-activated channels (59), which can change the shape of the action potential in response to stretch (34, 37). Mechanoelectric feedback has been studied in the clinical community for well over a century (for reviews, see Refs. 34,37,38) and may have both proarrhythmic and antiarrhythmic consequences. However, the mechanisms underlying these ph...

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confidence: 99%

Electromechanical wavebreak in a model of the human left ventricle

Keldermann

Nash

Gelderblom

et al. 2010

American Journal of Physiology-Heart and Circulatory Physiology

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100

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“…As illustrated in Fig. 2, the representation of the anatomy of the upper or lower chambers of the heart (whole atria or whole ventricles models) is obtained from imaging modalities such as MRI and histology using segmentation techniques to obtain a binary image that defines the boundaries of the cardiac tissue (11,75,76,97,102,111). The binary image is then used to generate a volumetric mesh by applying a discretization process in space necessary to conduct the simulations, as described in the next section.…”

Section: Multiscale Models and Simulations In Cardiac Electrophysiologymentioning

confidence: 99%

“…With respect to whole organ models, the process of iteration between experiments and simulations has been crucial, for example, to improving the understanding of important human health phenomena such as the dynamics of ventricular fibrillation (15,24,97), the most dangerous type of lethal arrhythmia, and the success and failure of electrical defibrillation, the only effective therapy against sudden cardiac death (98). In both cases, whole ventricular electrophysiology simulations were successfully combined with clinical and experimental methods to bring two important advantages.…”

Section: H150 Bridging Experiments Models and Simulations In Electrmentioning

confidence: 99%

“…First, the high spatiotemporal resolution data on the three-dimensional electrophysiological activity of the ventricles obtained from the simulations overcome limitations of clinical or experimental recordings, which are often restricted to low spatiotemporal resolution and/or just the surface of the heart. Second, computer models and simulations provide the ability to dissect the relative importance of different factors, which result in the identification of key properties such as the minimal action potential duration for ventricular fibrillation (96,97) or ventricular anatomy and structure for defibrillation (81,98). These novel findings could point toward new avenues for the preven- tion of ventricular fibrillation, both pharmacologically and electrically.…”

Section: H150 Bridging Experiments Models and Simulations In Electrmentioning

confidence: 99%

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Bridging experiments, models and simulations: an integrative approach to validation in computational cardiac electrophysiology

Carusi

Burrage

Rodríguez

2012

American Journal of Physiology-Heart and Circulatory Physiology

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Carusi A, Burrage K, Rodríguez B. Bridging experiments, models and simulations: an integrative approach to validation in computational cardiac electrophysiology. Am J Physiol Heart Circ Physiol 303: H144 -H155, 2012. First published May 11, 2012; doi:10.1152/ajpheart.01151.2011.-Computational models in physiology often integrate functional and structural information from a large range of spatiotemporal scales from the ionic to the whole organ level. Their sophistication raises both expectations and skepticism concerning how computational methods can improve our understanding of living organisms and also how they can reduce, replace, and refine animal experiments. A fundamental requirement to fulfill these expectations and achieve the full potential of computational physiology is a clear understanding of what models represent and how they can be validated. The present study aims at informing strategies for validation by elucidating the complex interrelations among experiments, models, and simulations in cardiac electrophysiology. We describe the processes, data, and knowledge involved in the construction of whole ventricular multiscale models of cardiac electrophysiology. Our analysis reveals that models, simulations, and experiments are intertwined, in an assemblage that is a system itself, namely the model-simulation-experiment (MSE) system. We argue that validation is part of the whole MSE system and is contingent upon 1) understanding and coping with sources of biovariability; 2) testing and developing robust techniques and tools as a prerequisite to conducting physiological investigations; 3) defining and adopting standards to facilitate the interoperability of experiments, models, and simulations; 4) and understanding physiological validation as an iterative process that contributes to defining the specific aspects of cardiac electrophysiology the MSE system targets, rather than being only an external test, and that this is driven by advances in experimental and computational methods and the combination of both. computational physiology; systems biology; computer simulations; whole ventricular models; cardiac electrophysiology COMPUTATIONAL PHYSIOLOGY belongs to the broad family of research in the life sciences referred to as systems biology. As with other domains of systems biology, it considers biological processes as systems of interacting components, and draws upon mathematical and computational modeling to bring these into new configurations with experimentation. It shares the basic commitments of systems biology to nonreductionist or integrative principles, geared towards the exploration of emergence and nonlinear interactions among components and between levels (12,16,41,49,53,71,88). From a sociological point of view, it is also a mode of research that depends on a high degree of interdisciplinary collaboration, where the increased sophistication of computational modeling in the life sciences can elicit high expectations but also skepticism sometimes, thus making collaboration more difficult (19,20,...

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“…The rabbit heart shares with the human heart ion currents responsible for depolarization and repolarization, demonstrates an AP shape similar to that of the human, and has been successfully used in transgenic models (3,42). Furthermore, the rabbit heart appears to most resemble the human heart with respect to wave dynamics during complex arrhythmia such as ventricular fibrillation (46,64). Complex wave dynamics of ventricular fibrillation are most suitably investigated with high resolution optical mapping techniques using charged-coupled device cameras or photodiode arrays (9 -11, 34, 44, 56).…”

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confidence: 99%

A novel, minimally invasive, segmental myocardial infarction with a clear healed infarct borderzone in rabbits

Ziv

Schofield

Lau

et al. 2012

American Journal of Physiology-Heart and Circulatory Physiology

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G. A novel, minimally invasive, segmental myocardial infarction with a clear healed infarct borderzone in rabbits. Am J Physiol Heart Circ Physiol 302: H2321-H2330, 2012. First published March 23, 2012 doi:10.1152/ajpheart.00031.2012.-Ventricular arrhythmias in the setting of a healed myocardial infarction have been studied to a much lesser degree than acute and subacute infarction, due to the pericardial scarring, which results from the traditional open-chest techniques used for myocardial infarction (MI) induction. We sought to develop a segmental MI with low perioperative mortality in the rabbit that allows optimal visualization and therefore improved study of the infarction borderzone. Rabbits underwent MI using endovascular coil occlusion of the first obtuse marginal artery. Three weeks postprocedure, we evaluated our model by echocardiography and electrophysiology studies, optical mapping of isolated hearts, and histological studies. Seventeen rabbits underwent the protocol (12 MI and 5 sham) with a 92% survival to completion of the study (11 MI and 5 sham). MI rabbits demonstrated wall motion abnormalities on echocardiography while shams did not. At electrophysiological study, two MI rabbits had inducible ventricular tachycardia and one had inducible ventricular fibrillation. Isolated hearts demonstrated no pericardial scarring with a smooth, easily identifiable infarct borderzone. Optical mapping of the borderzone region showed successful mapping of peri-infarct reentry formation, with ventricular fibrillation inducible in 11 of 11 MI hearts and 1 of 5 sham hearts. We demonstrate successful high resolution mapping in the borderzone, showing delayed conduction in this region corresponding to late deflections in the QRS on ECG. We report the successful development of a minimally invasive MI via targeted coil delivery to the obtuse marginal artery with an exceptionally high rate of procedural survival and an arrhythmogenic phenotype. This model mimics human post-MI on echocardiography, gross pathology, histology, and electrophysiology.arrhythmia; optical mapping; ventricular tachycardia SUDDEN CARDIAC DEATH (SCD) remains a major public health issue constituting an estimated 20% of deaths in industrialized countries (31,40,49). In autopsy series, nearly 50% of SCD victims have had healed myocardial infarction (MI; Refs. 24, 69). The majority of sudden deaths after MI occur due to ventricular tachyarrhythmias (26). Post-MI ventricular arrhythmias have been studied extensively in animal models. The animal studies suggest the epicardial borderzone as a key player in the formation of reentrant ventricular tachyarrhythmias due to changes in tissue structure, ion channels, and gap junctions that slow conduction and generate anisotropy (6,21,22,35,47,65,67). While these studies have greatly enhanced our understanding of post-MI arrhythmias, our understanding of the arrhythmia mechanisms in healed infarct remains limited because most of studies used 5 days postinfarction, not a fully healed post-MI heart. In additio...

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Organization of ventricular fibrillation in the human heart: experiments and models

Cited by 76 publications

References 41 publications

Electromechanical wavebreak in a model of the human left ventricle

Electromechanical wavebreak in a model of the human left ventricle

Bridging experiments, models and simulations: an integrative approach to validation in computational cardiac electrophysiology

A novel, minimally invasive, segmental myocardial infarction with a clear healed infarct borderzone in rabbits

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