Mechano-sensitivity of cardiac pacemaker function: Pathophysiological relevance, experimental implications, and conceptual integration with other mechanisms of rhythmicity

Quinn, T. Alexander; Kohl, Peter

doi:10.1016/j.pbiomolbio.2012.08.008

Cited by 50 publications

(45 citation statements)

References 146 publications

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“…Computational simulations have suggested a role for nsMSCs in heart rate acceleration and deceleration due to stretch described above, and experimental evidence in SAN tissue using GsMTx-4 is in agreement [2,72]. Computational models and experiments studies suggest a role for nsMSCs in stretch-induced ectopic ventricular contractions, repolarization shortening, and rate-dependent restitution of action potential duration [44,[73][74][75].…”

Section: Cell Scale: Myocyte Electromechanical Couplingmentioning

confidence: 67%

Biomechanics of Cardiac Electromechanical Coupling and Mechanoelectric Feedback

Pfeiffer

Tangney

Omens

et al. 2014

Journal of Biomechanical Engineering

100

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Cardiac mechanical contraction is triggered by electrical activation via an intracellular calcium-dependent process known as excitation-contraction coupling. Dysregulation of cardiac myocyte intracellular calcium handling is a common feature of heart failure. At the organ scale, electrical dyssynchrony leads to mechanical alterations and exacerbates pump dysfunction in heart failure. A reverse coupling between cardiac mechanics and electrophysiology is also well established. It is commonly referred as cardiac mechanoelectric feedback and thought to be an important contributor to the increased risk of arrhythmia during pathological conditions that alter regional cardiac wall mechanics, including heart failure. At the cellular scale, most investigations of myocyte mechanoelectric feedback have focused on the roles of stretch-activated ion channels, though mechanisms that are independent of ionic currents have also been described. Here we review excitation-contraction coupling and mechanoelectric feedback at the cellular and organ scales, and we identify the need for new multicellular tissue-scale model systems and experiments that can help us to obtain a better understanding of how interactions between electrophysiological and mechanical processes at the cell scale affect ventricular electromechanical interactions at the organ scale in the normal and diseased heart.

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Section: Cell Scale: Myocyte Electromechanical Couplingmentioning

confidence: 67%

Biomechanics of Cardiac Electromechanical Coupling and Mechanoelectric Feedback

Pfeiffer

Tangney

Omens

et al. 2014

Journal of Biomechanical Engineering

100

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“…Proper SAN function is an essential component for normal pacemaking at baseline and heart rate variation in response to external regulators such as exercise or stress [3,4]. SAN dysfunction is common in a wide variety of cardiac diseases, and is characterized by sinus bradycardia, sinus pause, and/or inappropriate heart rate responses to exercise and stress [5].…”

Section: Introductionmentioning

confidence: 99%

Synchronization of Pacemaking in the Sinoatrial Node: A Mathematical Modeling Study

et al. 2018

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Computational studies using mathematical models of the sinoatrial node (SAN) cardiac action potential (AP) have provided important insight into the fundamental nature of cell excitability, cardiac arrhythmias, and potential therapies. While the impact of ion channel dynamics on SAN pacemaking has been studied, the governing dynamics responsible for regulating spatial and temporal control of SAN synchrony remain elusive. Here, we attempt to develop methods to explore cohesion in a network of coupled spontaneously active SAN cells. We present the updated version of a previously published graphical user interface LongQt: a cross-platform, threaded application for advanced cardiac electrophysiology studies that does not require advanced programming skills. We incorporated additional features to the existing LongQt platform that allows users to (1) specify heterogeneous gap junction conductivity across a multicellular grid, and (2) set heterogeneous ion channel conductance across a multicellular grid. We developed two methods of characterizing the synchrony of SAN tissue based on alignment of activation in time and similarity of voltage peaks among clusters of functionally related cells. In pairs and two-dimensional grids of coupled cells, we observed a range of conductivities (0.00014-0.00033 1/ -cm) in which the tissue was more susceptible to developing asynchronous spontaneous pro-arrhythmic behavior (e.g., spiral wave formation). We performed parameter sensitivity analysis to determine the relative impact of ion channel conductances on cycle length (CL), diastolic and peak voltage, and synchrony measurements in isolated and coupled cell pairs. We also defined measurements of evaluating synchrony based on peak AP voltage and the rate of wave propagation. Cell-to-cell coupling had a non-linear effect on the relationship between ion channel conductances, AP properties, and synchrony measurements. Our simulations demonstrate that conductivity plays an important role in regulating synchronous firing of heterogeneous SAN tissue, and demonstrate how to evaluate the role of coupling and ion channel conductance in pairs and grids of SAN cells. We anticipate that the approach outlined here will facilitate identification of key cell-and tissue-level factors responsible for cardiac disease.

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“…These chronic effects arise over time as the result of repeated bouts of acute intoxication and withdrawal, but each drinking episode is also acutely linked to its own complex time-and dose-dependent neural, muscular, and biochemical alterations within the cardiovascular system (Kahkonen et al, 2011; Kawano, 2010). Initially, these acute cardiovascular alterations are transient (Kawano, 2010), and system redundancies can effectively compensate for disruptions to any one given element (Joyner and Pedersen, 2011; Quinn and Kohl, 2012). Over time, however, these alterations can persist and become clinically evident as one of several diagnosable chronic cardiovascular diseases that are highly comorbid with alcohol dependence (Corrao et al, 2004; Rehm et al, 2010).…”

mentioning

confidence: 99%

Immediate and Complex Cardiovascular Adaptation to an Acute Alcohol Dose

Buckman

Eddie

Vaschillo

et al. 2015

Alcoholism Clin & Exp Res

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Background The detrimental effects of chronic heavy alcohol use on the cardiovascular system are well established and broadly appreciated. Integrated cardiovascular response to an acute dose of alcohol has been less studied. This study examined the early effects of an acute dose of alcohol on the cardiovascular system, with particular emphasis on system variability and sensitivity. The goal was to begin to understand how acute alcohol disrupts dynamic cardiovascular regulatory processes prior to the development of cardiovascular disease. Methods Healthy participants (N = 72, age 21 to 29) were randomly assigned to an alcohol, placebo, or no-alcohol control beverage condition. Beat-to-beat heart rate (HR) and blood pressure (BP) were assessed during a low-demand cognitive task prior to and following beverage consumption. Between-group differences in neurocardiac response to an alcohol challenge (blood alcohol concentration ~ 0.06 mg/dl) were tested. Results The alcohol beverage group showed higher average HR, lower average stroke volume, lower HR variability and BP variability, and increased vascular tone baroreflex sensitivity after alcohol consumption. No changes were observed in the placebo group, but the control group showed slightly elevated average HR and BP after beverage consumption, possibly due to juice content. At the level of the individual, an active alcohol dose appeared to disrupt the typically tight coupling between cardiovascular processes. Conclusions A dose of alcohol quickly invoked multiple cardiovascular responses, possibly as an adaptive reaction to the acute pharmacological challenge. Future studies should assess how exposure to alcohol acutely disrupts or dissociates typically integrated neurocardiac functions.

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Mechano-sensitivity of cardiac pacemaker function: Pathophysiological relevance, experimental implications, and conceptual integration with other mechanisms of rhythmicity

Cited by 50 publications

References 146 publications

Biomechanics of Cardiac Electromechanical Coupling and Mechanoelectric Feedback

Biomechanics of Cardiac Electromechanical Coupling and Mechanoelectric Feedback

Synchronization of Pacemaking in the Sinoatrial Node: A Mathematical Modeling Study

Immediate and Complex Cardiovascular Adaptation to an Acute Alcohol Dose

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