Rectification of the Background Potassium Current

Samie, Faramarz H.; Berenfeld, Omer; Anumonwo, Justus M.B.; Mironov, Sergey; Udassi, Sharda; Beaumont, Jacques; Taffet, Steven M.; Pertsov, Arkady M.; Jalife, José

doi:10.1161/hh2401.100818

Cited by 248 publications

(62 citation statements)

References 36 publications

(34 reference statements)

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“…Some areas excite at higher rates than others and the DFs organize in clearly demarcated domains. As demonstrated in hearts from guinea pigs and mice (4,13), the frequency of the vortices, or their rotation period (1/frequency), closely matched the frequency of fibrillation or cycle length calculated from the DF maps or the ECG. However, please note that the highest DF domain decreases with increasing body size (mouse, 38 Hz; guinea pig, 26 Hz; rabbit, 15 Hz; human, 6.8 Hz).…”

Section: Resultssupporting

confidence: 63%

“…One school of thought suggests that, during fibrillation, the electrical waves propagate through the ventricles at random, with no underlying deterministic organization (2,3). Others postulate that, although VF is complex, it is maintained by organized electrical vortices, called ''rotors,'' that spin at exceedingly high frequencies around a central core region (4). Waves shed by the rotors take a spiral shape near the core but may turn into disorganized patterns of propagation known as ''fibrillatory conduction'' in the rotor's periphery (4).…”

mentioning

confidence: 99%

“…Others postulate that, although VF is complex, it is maintained by organized electrical vortices, called ''rotors,'' that spin at exceedingly high frequencies around a central core region (4). Waves shed by the rotors take a spiral shape near the core but may turn into disorganized patterns of propagation known as ''fibrillatory conduction'' in the rotor's periphery (4). Based on normal electrophysiology and anatomy, it is suggested that all mammalian hearts are built on the same template (5), and fibrillation has been shown to occur in the hearts of all mammalian species studied to date, from the mouse to the horse.…”

mentioning

confidence: 99%

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Universal scaling law of electrical turbulence in the mammalian heart

Noujaim

Berenfeld

Kalifa

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

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Many biological processes, such as metabolic rate and life span, scale with body mass (BM) according to the universal law of allometric scaling: Y ‫؍‬ aBM b (Y, biological process; b, scaling exponent). We investigated whether the temporal properties of ventricular fibrillation (VF), the major cause of sudden and unexpected cardiac death, scale with BM. By using high-resolution optical mapping, numerical simulations and metaanalysis of VF data in 11 mammalian species, we demonstrate that the interbeat interval of VF scales as VFcycle length ‫؍‬ 53 ؋ BM 1/4 , spanning more than four orders of magnitude in BM from mouse to horse.allometry ͉ spiral waves ͉ ventricular fibrillation

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Section: Resultssupporting

confidence: 63%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Universal scaling law of electrical turbulence in the mammalian heart

Noujaim

Berenfeld

Kalifa

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

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“…by one stable high frequency source mother rotor and complex VF patterns are the result of multiple breaks of the waves from this source at heterogeneities of the heart [3]. The multiple wavelet hypothesis explains VF by breakup of spiral waves due to dynamical or anatomical heterogeneity [4,5].…”

mentioning

confidence: 99%

Negative filament tension in the Luo-Rudy model of cardiac tissue

Alonso

Panfilov

2007

Chaos: An Interdisciplinary Journal of Nonlinear Science

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Scroll waves are vortices which occur in three dimensional excitable media. Scroll waves have been observed in a variety of systems including cardiac tissue, where they are associated with cardiac arrhythmias. The disorganization of scroll waves into chaotic behavior is thought to be the mechanism of ventricular fibrillation, which lethality is widely known. One of the possible mechanisms of scroll wave instability is negative filament tension, which was studied theoretically using low dimensional models of excitable medium. In this article we perform a numerical study of negative filament tension using the Luo-Rudy phase 1 model, which is widely used in cardiac electrophysiology. We show that this instability exists in this model, study its manifestation and discuss its relation to cardiac arrhythmogenesis.

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“…13 The reasons for the modification of the ionic model from its original version are the following. A singlecell electrophysiological study by Samie et al 14 have shown that LV myocardial cells have larger background potassium current as compared to RV cells. The study by Samie et al incorporated spline functions in the LR1 model (available at the journal website) to represent the experimental current-voltage relationship the authors obtained for isolated LV and RV cells.…”

Section: Representation Of Ionic Currents and Membrane Electroporamentioning

confidence: 99%

Arrhythmogenesis in the heart: Multiscale modeling of the effects of defibrillation shocks and the role of electrophysiological heterogeneity

Arevalo

Rodriguez

Trayanova

2007

Chaos: An Interdisciplinary Journal of Nonlinear Science

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The mechanisms of initiation of ventricular arrhythmias as well as those behind the complex spatiotemporal wave dynamics and its filament organization during ventricular fibrillation (VF) are the topic of intense research and debate. Mechanistic inquiry into the various mechanisms that lead to arrhythmia initiation and VF maintenance is hampered by the inability of current experimental techniques to resolve, with sufficient accuracy, electrical behavior confined to the depth of the ventricles. The objective of this article is to demonstrate that realistic 3D simulations of electrical activity in the heart are capable of bringing a new level of understanding of the mechanisms that underlie arrhythmia initiation and subsequent organization. The article does this by presenting the results of two multiscale simulation studies of ventricular electrical behavior. The first study aims to uncover the mechanisms responsible for rendering the ventricles vulnerable to electric shocks during a specific interval of time, the vulnerable window. The second study focuses on elucidating the role of electrophysiological heterogeneity, and specifically, differences in action potential duration in various ventricular structures, in VF organization. Both studies share common multiscale modeling approaches and analysis, including characterization of scroll-wave filament dynamics.Sudden cardiac death, due primarily to ventricular arrhythmias, is a major public health issue in the industrialized world. In the United States only, it results in over 350 000 deaths each year. Delivery to the heart of a strong electrical shock is currently the only effective means for prevention of sudden cardiac death, a procedure that is painful and could result in myocardial dysfunction and damage. A significant obstacle to improving treatment of ventricular arrhythmia is our limited understanding of both the mechanisms by which the arrhythmia is maintained in the heart and the mechanisms by which an electric shock interacts with the fibrillating heart. Experimental investigation of the electrical behavior in the heart has a limited scope because current experimental techniques cannot document with certainty electrical events in the depth of the cardiac wall. This article offers an alternative approach to the study of arrhythmia generation and termination in the heart: realistic three-dimensional multiscale modeling of electrical activity in the heart. It demonstrates that such modeling is a powerful

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Rectification of the Background Potassium Current

Cited by 248 publications

References 36 publications

Universal scaling law of electrical turbulence in the mammalian heart

Universal scaling law of electrical turbulence in the mammalian heart

Negative filament tension in the Luo-Rudy model of cardiac tissue

Arrhythmogenesis in the heart: Multiscale modeling of the effects of defibrillation shocks and the role of electrophysiological heterogeneity

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