Global ETD Search

11	Effects of Calcium Depletion and Loading on Injury During Metabolic Inhibition of Isolated Adult Rat Myocytes Rim, Dianne S., Altschuld, Ruth A., Ganote, Charles E. 01 January 1990 (has links) The hypothesis that calcium influxes from the extracellular space play an important role in the pathogenesis of irreversible anoxic injury was tested using isolated adult rat myocytes. Myocytes treated with 6 mm amytal and 3 mm iodoacetate and subsequently incubated in either calcium-containing (1.12 mm) or calcium-free media (with or without 1 mm EGTA) developed rigor contracture (cell squaring) and cell death (trypan blue permeability) at the same rate. The rates of cell death in both calcium-containing and calcium-free media were increased by incubation in hypotonic media even though the rates of contracture development remained unaltered. Cells developed osmotic fragility prior to membrane permeability increases. The calcium ionophore, A23187 (10 μm), induced rapid rounding of rod-shaped cells subjected only to mitochondrial inhibition in calcium containing media, confirming its ability to cause an increase in cellular permeability to calcium. However, A23187 did not alter the rates of cell death of totally metabolically inhibited myocytes in either calcium-containing or calcium-free media with EGTA. The results indicate that influxes of calcium are not necessary for the development of irreversible injury in metabolically inhibited, isolated myocytes. anoxic injury calcium isolated myocyte membrane injury osmotic fragility
12	Évaluation du rôle de nouvelles isoformes de PDE dans la compartimentation des nucléotides cycliques dans les cellules musculaires lisses vasculaires et les cardiomyocytes / Evaluation of the role of new PDE isoforms in cyclic nucleotide compartmentation in vascular smooth muscle cells and cardiomyocytes Zhang, Liang 28 September 2017 (has links) Les deux nucléotides cycliques, AMPc et GMPc, sont des seconds messagers importants qui régulent une grande variété de fonctions cellulaires, en particulier la fonction contractile cardiovasculaire, la croissance des cardiomyocytaires et la prolifération des cellules musculaires lisses vasculaires. Les phosphodiestérases (PDE) dégradent les nucléotides cycliques et exercent un contrôle local de leur concentration intracellulaire. Une altération de la voie de signalisation des nucléotides cycliques est impliquée dans plusieurs situations pathologiques telles que l’hypertension artérielle systémique ou pulmonaire, l’athérosclérose et l'hypertrophie cardiaque. Ainsi, les PDE constituent de puissantes cibles thérapeutiques pour restaurer un contrôle correct des nucléotides cycliques. Onze familles de PDEs sont actuellement décrites, les PDE1-6 étant les plus étudiées et les PDE 7-11 représentant de nouvelles familles.L'objectif de cette thèse était d'étudier le rôle respectif de 4 familles de PDEs, la PDE1, famille stimulée par le complexe Ca2+/calmoduline, les PDE5 et PDE9 spécifiques du GMPc, et la PDE8 spécifique de l'AMPc, dans le contrôle des concentrations intracellulaires d'AMPc ([AMPc]i) et de GMPc ([GMPc]i) dans les cellules musculaires lisses aortiques de rat (CMLARs) et les myocytes cardiaques de rat en utilisant une approche pharmacologique facilitée par le développement de nouveaux inhibiteurs sélectifs de PDEs. Les activités d'hydrolyse d’AMPc et de GMPc ont été mesurées par dosage enzymatique, tandis que les [AMPc]i et [GMPc]i ont été suivies sur cellules isolées, in situ, en temps réel, grâce à l'utilisation de l'imagerie FRET (Fluorescence Resonance Energy Transfer). Dans les CMLARs en culture, une activité d'hydrolyse des nucléotides cycliques via les PDE1, PDE5 et PDE9 a été observée. Nous avons montré un rôle fonctionnel de la PDE1 non stimulée dans le contrôle de l’augmentation de la [GMPc]i induite par le peptide natriurétique de type C (CNP). Il est intéressant de noter que, lors de l’élévation de la concentration intracellulaire en Ca2+, la PDE1 exerce également un contrôle de la réponse GMPci induite par le monoxyde d’azote (NO) et de la réponse AMPc médiée par la stimulation des récepteurs β-adrénergiques (β-AR). La PDE5 exerce un rôle majeur dans la réponse GMPc provoquée par l'activation de la guanylyl cyclase (GC) soluble par le NO ou des GC membranaires par les peptides natriurétiques, CNP et ANP. En revanche, la PDE9 ne régule que la réponse GMPc induite par le NO dans les RASMC cultivées. Aucune activité ou fonction hydrolytique de l'AMPc n'a été révélée avec l'inhibiteur de la PDE8 dans les CMLARs ou les cardiomyocytes de rat. Dans ces cellules cardiaques, l'activité d'hydrolyse médiée par la PDE1 n'a été détectée que sur la réponse GMPc et uniquement en présence de Ca2 +/Calmoduline. L'inhibiteur de la PDE1 n'a que légèrement affecté la réponse AMPc médiée par les récepteurs β-AR, par augmentation du pic du signal FRET.En conclusion, notre travail démontre que dans les cellules musculaires lisses vasculaires, les PDE1, PDE5 et PDE9 exercent une régulation spécifique et locale des [AMPc]i et [GMPc]i, renforçant le rôle clé des PDEs dans la compartimentation subcellulaire de la signalisation des nucléotides cycliques. / The two cyclic nucleotides cAMP and cGMP are important second messengers that regulate a large variety of cellular functions, in particular cardiovascular contractile function, cardiomyocyte cell growth and vascular smooth muscle cell proliferation. Phosphodiesterases (PDEs) degrade cyclic nucleotides, and exert a fine local control of their intracellular concentration. Alteration of cyclic nucleotides signaling pathway is involved in several pathological situations such as systemic and pulmonary arterial hypertensions, atherosclerotic lesions and cardiac hypertrophy. Thus, PDEs constitute potent therapeutic targets to restore a right cyclic nucleotide function. Eleven families of PDEs are now described, PDE1-6 being the most studied and PDE 7-11 representing the new families.The aim of the present thesis was to investigate the respective role of 4 PDE families, the Ca2+/calmodulin-stimulated PDE1, the cGMP-specific PDE5 and PDE9, and the cAMP-specific PDE8, in controlling intracellular cAMP ([cAMP]i) and intracellular cGMP ([cGMP]i) concentrations in both rat aortic smooth muscle cells (RASMCs) and cardiac myocytes by using a pharmacological approach taken advantage of the development of new selective PDE inhibitors. Cyclic AMP- and cGMP-hydrolyzing activities were measured by enzymatic assay on cell lysate, whereas real-time [cAMP]i and [cGMP]i were followed in situ in isolated cells using Fluorescence Resonance Energy Transfer (FRET) imaging. In cultured RASMCs, PDE1, PDE5 and PDE9 hydrolyzing activities were observed. We showed a functional role of basal PDE1 in controlling [cGMP]i increased by the C-type Natriuretic Peptide (CNP). Interestingly, upon high intracellular Ca2+ concentration, PDE1 also regulated the Nitric Oxide (NO)-mediated [cGMP]i response and the β-adrenoceptor (β-AR)-mediated [cAMP]i response. PDE5 exerted a major role in degrading [cGMP]i produced by the activation of either the soluble guanylyl cyclase (GC) elicited by NO or the particulate GCs by the natriuretic peptides, CNP and ANP. By contrast, PDE9 only regulated NO-induced [cGMP]i increase in cultured RASMCs. No cAMP-hydrolyzing activity or function was revealed with the PDE8 inhibitor in RASMCs or cardiac myocytes. In rat cardiomyocytes, PDE1-mediated hydrolyzing activity was only detected on cGMP in the presence of Ca2+/calmodulin. Unexpectedly, PDE1 inhibition slightly affected the β-AR-mediated [cAMP]i response by increasing the peak of FRET signal.In conclusion, our work underscores the distinct role of PDE1, PDE5, and PDE9 in locally regulating the [cAMP]i and [cGMP]i, in vascular smooth muscle cells, strengthening the concept of PDEs as key actors of cyclic nucleotide subcellular compartmentation. AMPc GMPc Phosphodiestérase Cellule musculaire lisse vasculaire Myocyte cardiaque Camp Cgmp Phosphodiesterase Vascular smooth muscle cell Cardiac myocyte
13	The Origin and Stimuli Implicated in the Expression of Nestin(+) Cardiac Myocyte-like Cells in the Ischemic Heart Assimakopoulos, John 01 1900 (has links) Nos études ont démontrées que la formation de la cicatrice et la guérison sont associées avec l’apparition de cellules de type myocytes cardiaques nestine(+) dans la région péri-infarcie. Présentement, l’étude examine le mécanisme, tel que l’hypoxie ou les hormones neuronales, possiblement impliqué dans leur recrutement et de dévoiler leur origine cellulaire. La présence de ces cellules a été détectée dans les coeurs infarcies d’une semaine et maintenue après neuf mois suite à une sujétion coronaire complète. Aussi, ces cellules de type myocytes cardiaques nestine(+) ont été observées dans le coeur infarci humain. L’hypoxie représente un événement prédominant suite à un infarctus de myocarde, mais l’exposition des rats normaux à un environnement hypoxique n’a pas pu promouvoir l’apparition de ces cellules. Autrement, l’infusion de l’agoniste -adrénergique non-sélectif isoprotérénol (ISO) dans les rats adultes Sprague-Dawley a augmenté la protéine nestine dans le ventricule gauche et a été associé avec la réapparition de cellules de type myocytes cardiaques nestine(+). Cela représente possiblement un effet secondaire suite à la nécrose des myocytes cardiaques par l’administration d’isoprotérénol. Dernièrement, on a identifié une sous-population de cellules nestine(+) dans le coeur normal du rat qui co-exprime les marqueurs de cellules cardiaques progénitrices Nkx-2.5 et GATA-4. Cette sous-population de cellules nestine/Nkx-2.5/GATA-4 pourrait représenter des substrats cellulaires qui puissent se différentier en cellules de type myocytes cardiaques nestine(+) suite à une ischémie. Mots clés: nestine, isoprotérénol, nécrose, cellule souche, cellule progénitrice, myocyte cardiaque / Studies from our lab demonstrated that scar formation and healing was associated with the appearance of nestin(+) cardiac myocyte-like cells predominantly at the peri-infarct region. The focus of the present study was to identify the underlying mechanism(s) (e.g. hypoxia, neurohormones) implicated in their recruitment and their cellular origin. The presence of these cells was detected as early as 1-week post-myocardial infarction (MI) and persisted 9 months after complete coronary artery ligation. Furthermore, nestin(+) cardiac myocyte-like cells were also detected in the infarcted human heart. Hypoxia represents a predominant stimulus following MI, however the exposure of normal rats to a hypoxic environment failed to promote the re-appearance of nestin(+) cardiac myocyte-like cells. By contrast, the infusion of the non-selective -adrenergic agonist isoproterenol (ISO) in the normal adult Sprague-Dawley rat increased nestin expression in the left ventricle and was associated with the reappearance of nestin(+) cardiac myocyte-like cells. However, the reappearance of nestin(+) cardiac myocyte-like cells may not represent a direct effect but was apparently secondary to cardiac myocyte necrosis mediated by isoproterenol. Lastly, we identified a subpopulation of nestin-immunoreactive cells in the normal rat heart that coexpressed cardiac progenitor cell markers Nkx-2.5 and GATA-4. This subpopulation of nestin/Nkx-2.5/GATA-4 cells may represent the progenitor pool that differentiates to a nestin(+) cardiac myocyte-like cell following an ischemic insult. Key words: nestin, isoproterenol, cardiac myocyte, cardiac progenitor, necrosis Nestine Isoproterenol Cellule Progenitrice Cellule Souche Myocyte Cardiaque Necrose Nestin Isoproterenol Cardiac Myocyte Cardiac Progenitor Necrosis
14	Dynamics and synchronization in biological excitable media / Dynamique et synchronisation dans les milieux excitables biologiques Xu, Jinshan 03 December 2012 (has links) Cette thèse étudie l'origine de l'activité spontanée dans l'utérus. Cet organe n'a aucune activité jusqu'à la délivrance, où les contractions rapides et efficaces sont générés. Le but de ce travail est de fournir un aperçu de l'origine des oscillations spontanées et de la transition de l'activité asynchrone à synchronisé dans l'utérus gravide. Un aspect intéressant de l'utérus est l'absence de pacemaker. L'organe est composé de cellules musculaires, qui sont excitables, et conjonctives, dont le comportement est purement passif, aucune de ces cellules, pris isolément, oscillent spontanément. Nous développons une hypothèse basée sur l'augmentation grande du couplage électrique entre les cellules observée pendant la grossesse. L'étude est basée sur deux modèles des cellules excitables, couplé à l'autre sur un réseau régulier, et un nombre variable de cellules passives, en accord avec la structure connue de l'utérus. Les deux paramètres du modèle, le couplage entre les cellules excitables, et entre les cellules excitables et passive, croissent pendant la grossesse. En utilisant les deux modèles, nous démontrons que les oscillations peuvent apparaître spontanément lorsque l'on augmente les coefficients de couplage, conduisant finalement à des oscillations cohérentes sur l'ensemble du tissu. Nous étudions la transition vers un régime cohérent, à la fois numériquement et semi-analytique, en utilisant le modèle simple des cellules excitables. Enfin, nous montrons que le modèle réaliste reproduit irréguliers modes de la propagation d'action potentiels ainsi que le comportement de bursting, observé dans les expériences in vitro. / This thesis investigates the origin of spontaneous activity in the uterus. This organ does not show any activity until shortly before delivery, where fast and efficient contractions are generated. The aim of this work is to provide insight into the origin of spontaneous oscillations and into the transition from asynchronous to synchronized activity in the pregnant uterus. One intriguing aspect in the uterus is the absence of any pacemaker cell. The organ is composed of muscular cells, which are excitable, and connective cells, whose behavior is purely passive; None of these cells, taken in isolation, spontaneously oscillates. We develop an hypothesis based on the observed strong increase in the electrical coupling between cells in the last days of pregnancy. The study is based on a mathematical model of excitable cells, coupled to each other on a regular lattice, and to a fluctuating number of passive cells, consistent with the known structure of the uterus. The two parameters of the model, the coupling between excitable cells, and between excitable and passive cells, grow during pregnancy.Using both a model based on measured electrophysiological properties, and a generic model of excitable cell, we demonstrate that spontaneous oscillations can appear when increasing the coupling coefficients, ultimately leading to coherent oscillations over the entire tissue. We study the transition towards a coherent regime, both numerically and semi-analytically, using the simple model of excitable cells. Last, we demonstrate that, the realistic model reproduces irregular action potential propagation patterns as well as the bursting behavior, observed in the in-vitro experiments. Modèle myocyte utérin Milieux excitables Couplage du jonction gap Synchronisation Contraction utérine Uterine myocyte model Excitable media Gap junction coupling Synchronization Uterine contraction
15	The Origin and Stimuli Implicated in the Expression of Nestin(+) Cardiac Myocyte-like Cells in the Ischemic Heart Assimakopoulos, John 01 1900 (has links) Nos études ont démontrées que la formation de la cicatrice et la guérison sont associées avec l’apparition de cellules de type myocytes cardiaques nestine(+) dans la région péri-infarcie. Présentement, l’étude examine le mécanisme, tel que l’hypoxie ou les hormones neuronales, possiblement impliqué dans leur recrutement et de dévoiler leur origine cellulaire. La présence de ces cellules a été détectée dans les coeurs infarcies d’une semaine et maintenue après neuf mois suite à une sujétion coronaire complète. Aussi, ces cellules de type myocytes cardiaques nestine(+) ont été observées dans le coeur infarci humain. L’hypoxie représente un événement prédominant suite à un infarctus de myocarde, mais l’exposition des rats normaux à un environnement hypoxique n’a pas pu promouvoir l’apparition de ces cellules. Autrement, l’infusion de l’agoniste -adrénergique non-sélectif isoprotérénol (ISO) dans les rats adultes Sprague-Dawley a augmenté la protéine nestine dans le ventricule gauche et a été associé avec la réapparition de cellules de type myocytes cardiaques nestine(+). Cela représente possiblement un effet secondaire suite à la nécrose des myocytes cardiaques par l’administration d’isoprotérénol. Dernièrement, on a identifié une sous-population de cellules nestine(+) dans le coeur normal du rat qui co-exprime les marqueurs de cellules cardiaques progénitrices Nkx-2.5 et GATA-4. Cette sous-population de cellules nestine/Nkx-2.5/GATA-4 pourrait représenter des substrats cellulaires qui puissent se différentier en cellules de type myocytes cardiaques nestine(+) suite à une ischémie. Mots clés: nestine, isoprotérénol, nécrose, cellule souche, cellule progénitrice, myocyte cardiaque / Studies from our lab demonstrated that scar formation and healing was associated with the appearance of nestin(+) cardiac myocyte-like cells predominantly at the peri-infarct region. The focus of the present study was to identify the underlying mechanism(s) (e.g. hypoxia, neurohormones) implicated in their recruitment and their cellular origin. The presence of these cells was detected as early as 1-week post-myocardial infarction (MI) and persisted 9 months after complete coronary artery ligation. Furthermore, nestin(+) cardiac myocyte-like cells were also detected in the infarcted human heart. Hypoxia represents a predominant stimulus following MI, however the exposure of normal rats to a hypoxic environment failed to promote the re-appearance of nestin(+) cardiac myocyte-like cells. By contrast, the infusion of the non-selective -adrenergic agonist isoproterenol (ISO) in the normal adult Sprague-Dawley rat increased nestin expression in the left ventricle and was associated with the reappearance of nestin(+) cardiac myocyte-like cells. However, the reappearance of nestin(+) cardiac myocyte-like cells may not represent a direct effect but was apparently secondary to cardiac myocyte necrosis mediated by isoproterenol. Lastly, we identified a subpopulation of nestin-immunoreactive cells in the normal rat heart that coexpressed cardiac progenitor cell markers Nkx-2.5 and GATA-4. This subpopulation of nestin/Nkx-2.5/GATA-4 cells may represent the progenitor pool that differentiates to a nestin(+) cardiac myocyte-like cell following an ischemic insult. Key words: nestin, isoproterenol, cardiac myocyte, cardiac progenitor, necrosis Nestine Isoproterenol Cellule Progenitrice Cellule Souche Myocyte Cardiaque Necrose Nestin Isoproterenol Cardiac Myocyte Cardiac Progenitor Necrosis
16	ALTERATIONS IN MYOSIN AND MYOCYTE STRUCTURE IN AN EXTREMLY LONG TERM PACING MODEL OF CANINE DILATED CARDIOMYOPATHY Fuller, Geraldine Anne 20 December 2002 (has links) No description available. dilated cardiomyopathy
17	Sphingosine-1-Phosphate and Fingolimod (FTY720) Regulate ICl,swell In HL-1 Cardiac Myocytes via Intracellular Binding And Mitochondrial ROS Production Desai, Pooja 01 January 2013 (has links) Swelling-activated Cl− current (ICl,swell) is an outwardly-rectifying current that plays an important role in cardiac electrical activity, cellular volume regulation, apoptosis, and acts as a potential effector of mechanoelectrical feedback. Persistent activation of ICl,swell has been observed in models of cardiovascular disease. We previously suggested sphingosine-1-phosphate (S1P) activates volume-sensitive Cl- current (ICl,swell) by ROS-dependent signaling. S1P and its analog, FTY720 (fingolimod), primarily act via G-protein coupled receptors (S1PR; S1PR1-3 in heart), but several intracellular S1P ligands are known. We investigated how these agents regulate ICl,swell. ICl,swell was elicited by bath S1P (500 nM), FTY720 (S1PR1,3 agonist; 10 μM), and SEW2871 (S1PR1 agonist; 10 μM) and was fully inhibited by DCPIB, a specific blocker. These data suggested role of S1PR in activation of ICl,swell. Surprisingly, neither CAY10444 (S1PR3 antagonist; 10 μM) nor VPC23019 (S1PR1,3 antagonist; 13 μM) blocked FTY720-induced ICl,swell. Also, gallein a pan Gbeta-gamma inhibitor, failed to block the S1P-induced current. Moreover, 100 nM FTY720 applied via the pipette evoked a larger, faster activating current than 10 μM bath FTY720. Similarly, 500 nM S1P gave larger, faster activating ICl,swell when added to the pipette than when added in the bath. In contrast to FTY720, bath S1P-induced ICl,swell was blocked by CAY10444, but a 3-fold higher concentration failed to eliminate the response to pipette S1P, and VPC23019 failed to suppress bath and pipette S1P-induced currents. Taken together, inconsistencies in the responses to S1PR agents and the greater sensitivity to pipette than bath S1P and FTY720 support the notion that intracellular ligands rather than sarcolemmal S1PR activated ICl,swell. Next we tested if S1P and FTY720, like osmotic swelling, require both NADPH oxidase and mitochondrial ROS production to evoke ICl,swell. S1P- and FTY720-induced ICl,swell were blocked by rotenone but were insensitive to gp91ds-tat, suggesting only mitochondrial ROS production was needed. One possibility is that S1P and FTY720 elicit ICl,swell by binding to mitochondrial prohibitin-2, an S1P ligand whose knockdown augments mitochondrial ROS productions. These data suggest ICl,swell may be activated by S1P accumulation in ischemia-reperfusion and CHF. Understanding S1P-signaling that elicits ICl,swell may provide insight into electrophysiological mechanisms of cardiac pathology and help identify novel targets for therapy. ICl swell S1P FTY720 electrophysiology ROS HL-1 Cardiac myocyte Life Sciences Physiology
18	L'effet pathologique du monoxyde d'azote est diminué dans les myocytes cardiaques hypertrophiés El-Helou, Viviane January 2004 (has links) Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal. Myocyte cardiaque Monoxyde d'azote Oxyde nitrique synthase Hypertrophie Synthèse d'ADN Superoxide dismutase Peroxynitrite
19	A Singular Perturbation Approach to the Fitzhugh-Nagumo PDE for Modeling Cardiac Action Potentials. Brooks, Jeremy 01 May 2011 (has links) The study of cardiac action potentials has many medical applications. Dr. Dennis Noble first used mathematical models to study cardiac action potentials in the 1960s. We begin our study of cardiac action potentials with one form of the Fitzhugh-Nagumo partial differential equation. We use the non-classical method to produce a closed form solution for the decoupled Fitzhugh Nagumo equation. Using voltage recording data of action potentials in a cardiac myocyte and in purkinje fibers, we estimate parameter values for the closed form solution with standard linear and non-linear regression methods. Results are limited, thus leading us to perturb the solution to obtain a better fit. We turn to singular perturbation theory to justify our pole-based approach. Finally, we test our model on independent action potential data sets to evaluate our model and to draw conclusions on how our model can be applied. Singular Perturbation Theory Physical Sciences and Mathematics Statistical Models Statistics and Probability
20	From Womb to Doom: Mechanical Regulation of Cardiac Tissue Assembly in Morphogenesis and Pathogenesis McCain, Megan Laura January 2012 (has links) The assembly, form, and function of the heart is regulated by complex mechanical signals originating from intrinsic and extrinsic sources, such as the cytoskeleton and the extracellular matrix. During development, mechanical forces influence the self-assembly of highly organized ventricular myocardium. However, mechanical overload induces maladaptive remodeling of tissue structure and eventual failure. Thus, mechanical forces potentiate physiological or pathological remodeling, depending on factors such as frequency and magnitude. We hypothesized that mechanical stimuli in the form of microenvironmental stiffness, cytoskeletal architecture, or cyclic stretch regulate cell-cell junction formation and cytoskeletal remodeling during development and disease. To test this, we engineered cardiac tissues in vitro and quantified structural and functional remodeling over multiple spatial scales in response to diverse mechanical perturbations mimicking development and disease. We first asked if the mechanical microenvironment impacts tissue assembly. To investigate this, we cultured two-cell cardiac µtissues on flexible substrates with tunable stiffness and monitored cell-cell junction formation over time. As myocytes transitioned from isolated cells to interconnected µtissues, focal adhesions disassembled near cell-cell interfaces and mechanical forces were transmitted almost completely through cell-cell junctions. However, µtissues cultured on stiff substrates mimicking fibrotic microenvironments retained focal adhesions near the cell-cell interface, potentially to reinforce the cell-cell junction in response to excessive forces generated by myofibrils in stiff microenvironments. Intercellular electrical conductance between myocytes was measured as a function of connexin 43 immunosignal and the length-to-width ratio of cell pairs. We observed that conductance was correlated to connexin 43 immunosignal and cell pair length-to-width ratio, indicating that tissue architecture can affect electrical coupling. The impact of mechanical overload was also determined by applying chronic cyclic stretch to engineered cardiac tissues. Stretch activated gene expression patterns characteristic of pathological remodeling, including up-regulation of focal adhesion genes, and impacted sarcomere alignment and myocyte shape. Furthermore, chronic cyclic stretch altered intracellular calcium cycling in a manner similar to heart failure and decreased contractile stress generation, suggestive of maladaptive remodeling. In summary, we show that the assembly, form, and function of cardiac tissue is sensitive to a wide range of mechanical cues that emerge during physiological and pathological growth. / Engineering and Applied Sciences adherens junction cardiac myocyte focal adhesion intercalated disc mechanotransduction sarcomere biomedical engineering cellular biology biophysics

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