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71	PIEZOELECTRIC POLYMER MICROSTRUCTURES FOR BIOMEDICAL APPLICATIONS Koucky, Michael Harten 26 June 2009 (has links) No description available. Biomedical Research Engineering Materials Science Polymers microfabrication polyvinylidene fluoride piezoelectric effect soft lithography cardiomyocyte
72	Non-invasive investigation of the response to oxidative stress in living cardiomyocytes by studying mitochondrial NAD(P)H Aneba, Swida January 2008 (has links) Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal. NAD(P)H Autofluorescence Mitochondrie Cardiomyocyte vivant État métabolique oxydatif NAD(P)H Autoflurorescence (AF) Spectrally-resolved fluorescence decays Mitochondria Living cardiomyocyte Oxidative metabolic state
73	Non-invasive investigation of the response to oxidative stress in living cardiomyocytes by studying mitochondrial NAD(P)H Aneba, Swida January 2008 (has links) Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal NAD(P)H Autofluorescence Mitochondrie Cardiomyocyte vivant État métabolique oxydatif NAD(P)H Autoflurorescence (AF) Spectrally-resolved fluorescence decays Mitochondria Living cardiomyocyte Oxidative metabolic state
74	THE CARDIAC L-TYPE CALCIUM CHANNEL DISTAL CARBOXYL- TERMINUS AUTO-INHIBITION IS REGULATED BY CALCIUM Crump, Shawn M 01 January 2012 (has links) The L-type calcium channel (LTCC) provides trigger Ca2+ for sarcoplasmic reticulum Ca2+-release and LTCC function is influenced by interacting proteins including the LTCC Distal Carboxyl-terminus (DCT) and calmodulin. DCT is proteolytically cleaved, and re-associates with the LTCC complex to regulate calcium channel function. DCT reduces LTCC barium current (IBa,L) in reconstituted channel complexes, yet the contribution of DCT to ICa,L in cardiomyocyte systems is unexplored. This study tests the hypothesis that DCT attenuates cardiomyocyte ICa,L. We measured LTCC current and Ca2+ transients with DCT co-expressed in murine cardiomyocytes. We also heterologously co-expressed DCT and CaV1.2 constructs with truncations corresponding to the predicted proteolytic cleavage site, CaV1.2Δ1801, and a shorter deletion corresponding to well-studied construct, CaV1.2Δ1733. DCT inhibited IBa,L in cardiomyocytes, and in HEK 293 cells expressing CaV1.2Δ1801 and CaV1.2Δ1733. Ca2+-CaM relieved DCT block in cardiomyocytes and HEK cells. The selective block of IBa,L combined with Ca2+-CaM effects suggested that DCT-mediated blockade may be relieved under conditions of elevated Ca2+. We therefore tested the hypothesis that DCT block is dynamic, increasing under relatively low Ca2+, and show that DCT reduced diastolic Ca2+ at low stimulation frequencies but spared high frequency Ca2+-entry. DCT reduction of diastolic Ca2+ and relief of block at high pacing frequencies, and under conditions of supraphysiological bath Ca2+ suggests that a physiological function of DCT is to increase the dynamic range of Ca2+ transients in response to elevated pacing frequencies. Our data motivates the new hypothesis that DCT is a native reverse use-dependent inhibitor of LTCC current. : L-type Calcium Channel Distal Carboxyl-Terminus Calcium Channel Auto-Inhibition Cardiomyocyte Reverse Use Dependent Inhibition Cellular and Molecular Physiology
75	La bioénergétique systémique moléculaire des cellules cardiaques : la relation structure-fonction dans la régulation du métabolisme énergétique compartmentalisé Gonzalez granillo, Marcela alejandra 28 September 2012 (has links) (PDF) An important element of metabolic regulation of cardiac and skeletal muscle energetics is the interaction of mitochondria with cytoskeleton. Mitochondria are in charge of supplying the cells with energy, adjusting its functional activity under conditions of stress or other aspects of life. Mitochondria display a tissue-specific distribution. In adult rat cardiomyocytes, mitochondria are arranged regularly in a longitudinal lattice at the level of A band between the myofibrils and located within the limits of the sarcomeres. In interaction with cytoskeleton, sarcomeres and sarcoplasmic reticulum they form the functional complexes, the intracellular energetic units (ICEUs). The ICEUs have specialized pathways of energy transfer and metabolic feedback regulation between mitochondria and ATPases, mediated by CK and AK. The central structure of ICEUs is the mitochondrial interactosome (MI) containing ATP Synthasome, respiratory chain, mitochondrial creatine kinase and VDAC, regulated by tubulins. The main role of MI is the regulation of respiration and the intracellular energy fluxes via phosophotransfer networks. The regulation of ICEUs is associated with structural proteins. The association of mitochondria with several cytoskeletal proteins described by several groups has brought to light the importance of structure-function relationship in the metabolic regulation of adult rat cardiomyocytes. To purvey a better understanding of these findings, the present work investigated the mechanism of energy fluxes control and the role of structure-function relationship in the metabolic regulation of adult rat cardiomyocytes. To show these complex associations in adult cardiac cells several proteins were visualized by confocal microscopy: α-actinin and β-tubulin isotypes. For the first time, it was showed the existence of the specific distribution of β-tubulin isotypes in adult cardiac cells. Respiratory measurements were performed to study the role of tubulins in the regulation of oxygen consumption. These results together confirmed the crucial role of cytoskeletal proteins -i.e. tubulins, α-actinin, plectin, desmin, and others- for the normal shape of cardiac cells as well as mitochondrial arrangement and regulation. In addition, in vivo - in situ mitochondrial dynamics were studied by the transfection of GFP-α-actinin, finding that fusion phenomenon does not occur as often as it is believed in healthy adult cardiac cells. Couplage fonctionnel Compartimentation ATP Metabolisme énergétique Cardiomyocyte Cancer
76	Effects of hydrodynamic culture on embryonic stem cell differentiation: cardiogenic modulation Sargent, Carolyn Yeago 07 July 2010 (has links) Stem and progenitor cells are an attractive cell source for the treatment of degenerative diseases due to their potential to differentiate into multiple cell types and provide large cell yields. Thus far, however, clinical applications have been limited due to inefficient differentiation into desired cell types with sufficient yields for adequate tissue repair and regeneration. The ability to spontaneously aggregate in suspension makes embryonic stem cells (ESCs) amenable to large-scale culture techniques for the production of large yields of differentiating cell spheroids (termed embryoid bodies or EBs); however, the introduction of hydrodynamic conditions may alter differentiation profiles within EBs and should be methodically examined. The work presented here employs a novel, laboratory-scale hydrodynamic culture model to systematically interrogate the effects of ESC culture hydrodynamics on cardiomyocyte differentiation through the modulation of a developmentally-relevant signaling pathway. The fluidic environment was defined using computational fluid dynamic modeling, and the effects of hydrodynamic conditions on EB formation, morphology and structure were assessed. Additionally, EB differentiation was examined through gene and protein expression, and indicated that hydrodynamic conditions modulate differentiation patterns, particularly cardiogenic lineage development. This work illustrates that mixing conditions can modulate common signaling pathways active in ESC differentiation and suggests that differentiation may be regulated via bioprocessing parameters and bioreactor design. Embryonic stem cells Embryoid body Hydrodynamic Bioprocessing Differentiation Cardiomyocyte Heart cells Degeneration (Pathology) Hydrodynamics Embryonic stem cells Research
77	Mechanismen der sensiblen Mechanotransduktion in Kardiomyozyten Schreiber, Anna 18 October 2016 (has links) Die vorgelegte Dissertationsschrift dient der Identifizierung des Mechanismus, über welchen neonatale Kardiomyozyten der Ratte biaxialen zyklischen Stretch wahrnehmen. Angriffspunkt dafür bildeten sowohl Stretch Activated Ion Channels (SAIC) als auch die mit Integrinen assoziierte Focal Adhesion Kinase (FAK). Die Inhibition der SAIC erfolgte mit Gadolinium und eine Blockade der FAK konnte durch den FAK-Inhibitor II erreicht werden. Eigens angelegte Zellkulturen wurden unter definierten Parametern für 24 Stunden unter Einwirkung genannter Stoffe gestretcht und anschließend einer Analyse mittels Immunfluoreszenz und Western Blot unterzogen. Gestretchte Kardiomyozyten richteten sich schräg zur Achse der einwirkenden Kraft aus und wiesen eine Polarisierung von Connexin 43 auf, außerdem zeigte sich dessen gesteigerte Expression. Durch die Blockade der FAK konnte lediglich eine aufgehobene Polarisierung von Connexin 43 bei unveränderter Expression und Ausrichtung der Kardiomyozyten festgestellt werden. Auch die Mikrotubuli veränderten nach Stretch ihre Orientierung bezogen auf die Zellachse. Die zunächst annähernde Parallelität der Fasern zeigte sich nach Inhibition der FAK deutlich aufgelockert. Für die Aktinfilamente konnte dies nicht nachgewiesen werden. Die Integrine dienen demnach der Wahrnehmung von Stretch und vermitteln die Polarisierung von Connexin 43 sowie die Orientierung der Mikrotubuli über die FAK. Für die anderen genannten Prozesse ist die Aktivierung eines FAK-unabhängigen Integrin-Signalweges denkbar. Gadolinium hatte insgesamt keinen Effekt auf beschriebene Veränderungen, sodass ein Einfluss der SAIC auf Stretch-induzierte Veränderungen in Kardiomyozyten ausgeschlossen werden konnte. Gleichzeitig konnte durch die Beobachtung der Polarisierung von Microtubule Organizing Center, Kinesin und Golgi-Apparat die Hypothese der sich durch Stretch orientierenden neonatalen Kardiomyozyte unterstützt werden, welche die Voraussetzung für die Anordnung von Connexin 43 an den Zellpolen darstellen könnte. Sowohl die Selbstorganisation des Myokards im Rahmen der Embryogenese als auch die Pathophysiologie verschiedener kardialer Erkrankungen könnte dadurch womöglich besser verstanden werden. info:eu-repo/classification/ddc/610 ddc:610
78	Mechanisms of cardiomyocyte cell cycle arrest and maturation in postnatal rodents and swine Velayutham, Nivedhitha 23 August 2022 (has links) No description available. Developmental Biology cardiomyocyte proliferation cardiac development postnatal heart maturation large mammal studies heart regeneration cell cycle regulation
79	Effects of medicinal herbs on contraction rate of cultured cardiomyocyte. Possible mechanisms involved in the chronotropic effects of hawthorn and berberine in neonatal murine cardiomyocyte / Possible mechanisms involved in the chronotropic effects of hawthorn and berberine in neonatal murine cardiomyocyte Salehi, Satin 29 September 2009 (has links) Herbs have been used for many centuries in diverse civilizations for the treatment of heart disease. Only a few natural supplements claim to have direct cardiovascular actions including hawthorn (Crataegus spp.) and berberine derived from the Berberidaceae family. Several different studies indicate important cardiovascular effects of hawthorn and berberine. For example, both exert positive inotropic effects and have been used in the treatment of congestive heart failure. Recently, it was shown that hawthorn extract preparations cause negative chronotropic effects in a cultured neonatal murine cardiomyocyte assay independent of beta-adrenergic receptor blockade. The aim of this study was to further characterize the effect of hawthorn extract to decrease the contraction rate of cultured cardiomyocytes. We hypothesized that hawthorn extract may be acting through muscarinic receptors to decrease contraction rate of cardiomyocytes. Atrial and ventricular cardiomyocytes were treated with hawthorn extract in the presence of atropine or himbacine. Changes in the contraction rate of cultured cardiomyocytes revealed that both muscarinic antagonists significantly attenuated the negative chronotropic activity of hawthorn extract. Using quinuclidinyl benzilate, L-[benzylic-4,4'-3H] ([³H]-QNB) as a radioligand antagonist, the effect of a partially purified hawthorn extract fraction to inhibit muscarinic receptor binding was quantified. Hawthorn extract fraction 3 dose-dependently inhibited [³H]-QNB binding to mouse heart membranes. These findings suggest that muscarinic receptors may be involved in the negative chronotropic effect of hawthorn extracts in neonatal murine cardiomyocytes. Berberine exhibits variable positive and negative chronotropic effects in different species. Our first aim was to examine the effect of berberine in a cultured neonatal murine cardiomyocyte assay. Our study demonstrates that berberine has significant negative chronotropic actions on cardiomyocytes which is not an effect of beta-adrenergic receptor blockade. Pertussis toxin (PTX), a Gi/o protein inhibitor, blocked the negative chronotropic activity of berberine. Muscarinic, adenosine, opioid, and α₂ receptors are coupled through a G-protein (Gi/o) to adenylyl cyclase in an inhibitory fashion. Activation of these receptors are primarily responsible for PTX-sensitive negative chronotropic effects in heart. We hypothesized that berberine may be acting through one of these receptor type to decrease contraction rate of cardiomyocytes. For this purpose, we studied the effects of the muscarinic-receptor antagonists, atropine, himbacine, or AF- DX 116 on the negative chronotropic activity of berberine. Muscarinic antagonists completely blocked the effect of berberine on contraction rate of cardiomyocytes, whereas the bradycardic effect of berberine was not inhibited by the opioid, adenosine, or α2 receptor antagonists naloxone, CGS 15943, or phentolamine, respectively. Using [³H]QNB as a radioligand, we demonstrated that berberine bound to muscarinic receptors of adult mouse heart membranes with relatively high affinity. Furthermore, berberine dose-dependently inhibited [³H]QNB binding to muscarinic M2 receptors exogenously expressed in HEK 293 cells. Therefore, the findings of the present study suggest that berberine has muscarinic agonist effects in cultured neonatal murine cardiomyocytes, potentially explaining reported physiological effects of berberine. Cardiac hypertrophy represents the most important factor in the development of congestive heart failure. We investigated the inhibitory effect of berberine on hypertrophy of H9c2 cells. In rat heart-derived H9c2 myoblast cells treated with different hypertrophic agonists such as insulin growth factor II (IGF-II), arginine vasopressin (AVP), phenylephrine, and isoproterenol, protein content and size of cells were significantly increased compared to control group. However, the number of H9c2 cells after treatment with hypertrophic agonists did not differ significantly compared to control. The increases in area of cells and protein content induced by the hypertrophic agonists were inhibited by treatment with berberine in a concentration-dependent manner. Our findings have provided the first scientific evidence that berberine may have an inhibitory effect on hypertrophy of heart-derived cells, and provide a rationale for further studies to evaluate berberine's cardiac activity. / Graduation date: 2010 Hawthorn Cardiomyocyte Berberine Muscarinic receptors Hypertrophy H9c2 cell line Heart cells Heart -- Hypertrophy Muscarinic receptors Berberidaceae Cardiovascular agents Hawthorns Plant extracts Materia medica, Vegetable
80	Study of NAD(P)H fluorescence in living cardiomyocytes by spectrally resolved time-correlated single photon counting Ying, Cheng January 2007 (has links) Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal. NAD(P)H Autofluorescence (AF) Mitochondrie Mitocondria Myocytes cardiatques Living cardiomyocyte Rejet des coeurs transplantés Rejection of heart transplantation

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