The effects of increasing cell length on auxotonic contractions; membrane potential and intracellular calcium transients in single guinea‐pig ventricular myocytes

White, Edward; Guennec, Jean‐Yves Le; Nigretto, Jean-Maxime; Gannier, François; Argibay, JA; Garnier, D

doi:10.1113/expphysiol.1993.sp003671

Cited by 117 publications

(68 citation statements)

References 27 publications

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“…It has been shown that in ferret, cat and rat myocardium [18,22] and isolated Guinea-pig and rat myocytes [12,26,27] the Ca 2+ transient declines faster at high preload. Superimposing of Ca 2+ transients obtained in rat cardiac muscle at low and high preload revealed their crossing on approximately half of the transient amplitude [16,17,23].…”

Section: Introductionmentioning

confidence: 99%

“…Preload-dependent changes in calcium handling in cardiomyocytes are more complex and controversial. No preload-dependence of resting [Ca 2+ ] i level has been shown in ferret papillary muscle [8], mouse right ventricular trabeculae [9], and stimulated or quiescent Guinea-pig, rat and mouse cardiomyocytes [10][11][12][13][14]. On the other hand, preload caused a rise in resting calcium level in stimulated Guinea-pig right ventricular trabeculae [15] or a small significant decrease of that level in rat ventricular trabeculae [16,17].…”

Section: Introductionmentioning

confidence: 99%

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Preload-induced changes in isometric tension and [Ca2+]i in rat myocardium

Lookin

Protsenko

2011

Open Life Sciences

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Preload-induced changes of active tension and [Ca2+]i are “dissociated” in mammalian myocardium. This study aimed to describe the distinct effects of preload at low and physiological [Ca2+]o. Rat RV papillary muscles were studied in isometric conditions at 25‡C and 0.33 Hz at 1 mM (hypo-Ca group) and 2.5 mM [Ca2+]o (normal-Ca group). [Ca2+]i was monitored with fura-2/AM. Increase of preload caused a rise of active tension in hypo-Ca and normal-Ca groups whereas peak fluorescence rose significantly only at low [Ca2+]o. End-diastolic tension, end-diastolic level of fluorescence, time-to-peak tension, but not time-to-peak of Ca2+ transient, progressively increased with preload. Mechanical relaxation decelerated with preload while Ca2+ transient decay time decreased in the initial phase and increased in the late phase, resulting in a prominent “bump” configuration. The “bump” was assessed as a ratio of its area to the fluorescence trace area. It was a new finding that the preload-induced rise of this ratio was twice as large in hypo-Ca. Our results indicate that preload-induced changes in active tension and [Ca2+]i are “dissociated” in rat myocardium, with relatively higher expression at low [Ca2+]o. Ca-dependence of Ca-TnC association/dissociation kinetics is thought to be a main contributor to these preload-induced effects.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Preload-induced changes in isometric tension and [Ca2+]i in rat myocardium

Lookin

Protsenko

2011

Open Life Sciences

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“…Previous work in the literatures on single cardiac cells and whole hearts has shown that mechanical stretch can alter action potential duration (Zeng et al, 2000), and generate extrasystoles in isolated frog (Lab, 1978), pig (Dean and Lab, 1989) and dog (Hansen et al, 1990;Stacy et al, 1992) hearts. It has been speculated that this process of "mechanoelectric feedback" could alter the normal distribution of repolarization and excitability (Tung and Zou, 1995;White et al, 1993), and potentiate the likelihood for reentrant arrhythmia in failing hearts (Dean and Lab, 1989;Reiter, 1996). We are testing MEF effect experimentally using 2D cardiac cell monolayers, characterizing electrophysiological properties, such as excitability, refractoriness (action potential duration) and electrical conduction (conduction velocity) of the monolayer under different mechanical conditions.…”

Section: Discussionmentioning

confidence: 99%

Cell cultures as models of cardiac mechanoelectric feedback

Zhang

Sekar

McCulloch

et al. 2008

Progress in Biophysics and Molecular Biology

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Although stretch-activated currents have been extensively studied in isolated cells and intact hearts in the context of mechanoelectric feedback (MEF) in the heart, quantitative data regarding other mechanical parameters such as pressure, shear, bending, etc, are still lacking at the multicellular level. Cultured cardiac cell monolayers have been used increasingly in the past decade as an in vitro model for the studies of fundamental mechanisms that underlie normal and pathological electrophysiology at the tissue level. Optical mapping makes possible multisite recording and analysis of action potentials and wavefront propagation, suitable for monitoring the electrophysiological activity of the cardiac cell monolayer under a wide variety of controlled mechanical conditions. In this paper, we review methodologies that have been developed or could be used to mechanically perturb cell monolayers, and present some new results on the acute effects of pressure, shear stress and anisotropic strain on cultured neonatal rat ventricular myocyte (NRVM) monolayers.

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“…As myocardiocytes were mechanically stretched, an outwardly rectifying K + current component with a conductance of approximately 100-130 pS was detected in whole-cell recordings in rat ventricular myocytes, and underlay the drop in refractoriness. The reduction in plateau and repolarization duration was induced by stretch, reported by Franz et al [31,33,34,38,39,47]. The shortening of plateau phase results from either of the two factors: the acceleration of K + outflow or the acceleration of Ca 2+ inflow.…”

Section: Tachyarrhythmogenesis In Stretchmentioning

confidence: 99%

“…Song et al [86] detailed the features: "In cornea and skin, a laterally oriented, wound-induced d.c. (direct current) electric field is generated instantaneously when the epithelium is damaged, and it persists until re-epithelialization restores the electrical resistance barrier function of the epithelium". These electric fields were estimated to be [40][41][42][43][44][45][46][47][48][49][50] , and spatial variations in the electrical resistance of epithelial sheets [86].…”

Section: The Identity Of Electric Field Lateralization Induced By Dismentioning

confidence: 99%

Spontaneous high-frequency action potential

Shen

Choe

2011

Sci. China Life Sci.

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Action potential, which is the foundation of physiology and electrophysiology, is most vital in physiological research. This work starts by detecting cardiac electrophysiology (tachyarrhythmias), combined with all spontaneous discharge phenomena in vivo such as wound currents and spontaneous neuropathic pain, elaborates from generation, induction, initiation, to all of the features of spontaneous high-frequency action potential--SSL action potential mechanism, i.e., connecting-end hyperpolarization initiates spontaneous depolarization and action potential in somatic membrane. This work resolves the conundrums of in vivo spontaneous discharge in tachyarrhythmias, wounds, denervation supersensitivity, neurogenic pain (hyperalgesia and allodynia), epileptic discharge and diabetic pain in pathophysiological and clinical researches that have puzzled people for a hundred years. action potential, spontaneous high-frequency action potential, tachyarrhythmias, atrial fibrillation, wound, denervation supersensitivity, neurogenic pain, hyperalgesia and allodynia, epileptic discharge, diabetic pain, regeneration and development Citation:Shen H Y, Choe W C. Spontaneous high-frequency action potential. Sci China Life Sci, 2011Sci, , 54: 311 -335, doi: 10.1007 Wound, nerve disconnection, and atrial fibrillation (AF) induced by the excessive atrial dilation, are commonly characterized by the spontaneous repetitive discharge. Their common induction is the disconnection of intercellular connection, and their common result is the initiation of spontaneous high-frequency discharge, which discloses the existence of the special action of intercellular connection.The Hodgkin-Huxley model has predicted, and the computer models in applied mathematics have well demonstrated, that potassium leakage causes persistent spontaneous electrifying state with spontaneous oscillation of high-frequency action potential. The sustained disconnection of connecting-end space induces potassium leakage in the connecting-end and consequently the sustained reduction of [K + ] i , which induces in vivo spontaneous high-frequency action potential in plasmalemma.To form an intercellular conduction, connecting-end space exerts action on ion diffusions, the alteration of the space alters ion diffusions (i.e., ionic permeability) in the connecting-end. The abolishment of connecting-end space action causes K + leakage and consequently the reduction of intracellular positive electropotential (IPE) (i.e., the increase of intracellular negative potential), which elevates resting somatic membrane potential and initiates action potential in somatic membrane. SSL action potential is named to the course from the initiation (i.e., connecting-end hyperpolarization) to the termination of somatic membrane action potential.Tachyarrhythmias that are characterized by spontaneous discharge have been most deeply studied. Their inductions contain both mechanical actions and chemical actions, and their courses contain the transformation from traditional action potential to SSL-ty...

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The effects of increasing cell length on auxotonic contractions; membrane potential and intracellular calcium transients in single guinea‐pig ventricular myocytes

Cited by 117 publications

References 27 publications

Preload-induced changes in isometric tension and [Ca2+]i in rat myocardium

Preload-induced changes in isometric tension and [Ca2+]i in rat myocardium

Cell cultures as models of cardiac mechanoelectric feedback

Spontaneous high-frequency action potential

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