Global ETD Search

1	Computational studies of the human cardiac sodium channel Beard, Torien M. 08 December 2023 (has links) (PDF) Computational methods such as Molecular Dynamics (MD) simulations and Molecular Mechanics generalized Born surface area solvation (MM-GBSA) binding affinity calculations have been utilized to determine the binding modes and final binding affinities of small molecules that are known to interact with the heart sodium channel NaV1.5. Lidocaine, ranolazine, and flecainide are FDA approved arrhythmia drugs that are prescribed to patients in the event of heart disease. Here, we demonstrate the likely binding preferences and modes of action of all molecules with NaV1.5, the stability of the systems, and overall final binding affinities of the small molecules with the protein. To gain insights into the mechanisms of heart disease treatments, the MM-GBSA method was utilized to estimate the binding free energies of each molecule and pose to NaV1.5. The evaluation of the binding of small molecules to NaV1.5 contributes to enhancing our understanding of the underlying processes involved in heart disease treatments. The MM-GBSA approach provides a valuable tool for predicting and analyzing binding affinities, which can aid in the design and optimization of potential therapeutic compounds targeting NaV1.5. Sodium channel Lidocaine Ranolazine Flecainide
2	Einfluss von Ranolazin und Flunarizin in Kombination mit d-Sotalol auf getriggerte Arrhythmien im isolierten Kaninchenherzen / Effects of ranolazine and flunarizine on torsades de pointes tachycardias in a healthy isolated rabbit heart model Wallisch, Nora 20 September 2017 (has links) No description available. 610 ranolazine flunarizine torsade de pointes Medizin (PPN619874732)
3	Ranolazine: a Potential Anti-diabetic Drug Li, Xiaoxiao 12 December 2012 (has links) Diabetes is a life-long chronic disease that affects more than 24 million Americans. Loss of pancreatic beta-cell mass and function is central to the development of both type 1 (T1D) and type 2 diabetes (T2D). Therefore, preservation or regeneration of functional beta-cell mass is one of the essential strategies to treat diabetes [1]. In my study, I tested if ranolazine, a synthetic compound, has potential to prevent or treat diabetes. Diabetes were induced in mice by giving multiple low-doses of streptozotocin (STZ). Ranolazine was given twice daily via an oral gavage (20 mg/kg) for 5 weeks. blood levels of glucose, insulin, and glycosylated hemoglobin (HbA1c) were measured. Glucose tolerance test was performed in control and treated mice. pancreatic tissues were stained with hematoxylin and eosin or stained with insulin antibody for islet mass evaluation. INS1-832/13 cells and human islets were further used to evaluate the effect of ranalozine on beta-cell survival and related signaling pathway. Fasting blood glucose levels after the fourth week of STZ injections were lower in ranolazine treated group (199.1 mg/dl) compared to the vehicle group (252.1 mg/dl) (p<0.01). HbA1c levels were reduced by ranolozine treatment (5.33%) as compared to the control group (7.23%) (p<0.05%). Glucose tolerance was improved in ranolazine treated mice (p<0.05). Mice treated with ranolazine had higher beta-cell mass (0.25%) than the vehicle group (0.07%)(p<0.01). In addition, ranolazine improved survival of human islets exposed to high levels of glucose and palmitate, whereas cell proliferation was not altered. In addition, ranolazine slightly increased the cAMP in MIN-6 cell and human islets. In conclusion, ranolazine may have therapeutic potential for diabetes by preserving beta-cell mass. / Master of Science Ranolazine Beta-cell Apoptosis Proliferation Diabetes
4	Sodium dysregulation coupled with calcium entry leads to muscular dystrophy in mice Burr, Adam R. January 2014 (has links) No description available. Molecular Biology duchenne sodium ranolazine muscular dystrophy calcium ncx1
5	Etude cellulaire et moléculaire de l'insuffisance cardiaque à fonction systolique préservée / Heart failure with preserved systolic function : Cellular and molecular pathophysiological pathways Rouhana, Sarah 30 November 2018 (has links) L'insuffisance cardiaque à fraction d’éjection préservée (IC/FEp) constitue un problème de santé croissant. Elle pourrait devenir la principale cause d'IC d'ici une décennie. C’est une pathologie associée à un taux élevé de morbidité et de mortalité. La prise en charge thérapeutique de l’IC/FEp reste limitée en raison de sa physiopathologie encore mal élucidée. Dans le présent travail, après avoir mis au point un modèle d’IC/FEp sur le rat adulte mâle et l’avoir caractérisé, nous avons évalué le phénotype fonctionnel et l’homéostasie calcique des cardiomyocytes. Les cœurs de ces animaux ont montré une fraction d’éjection supérieure à 50%, associée à une congestion pulmonaire, une hypertrophie concentrique avec une augmentation de la masse du ventricule gauche, une rigidité myocardique, une relaxation et un remplissage ventriculaire passif altérés et une dilatation auriculaire. Au niveau cellulaire, la contraction mesurée sur des cardiomyocytes isolés ainsi que le transitoire calcique sont augmentées. On note, de même, une surcharge en Ca2+ diastolique favorisée par une fuite à travers les canaux Ryanodine 2 et par un dysfonctionnement de l’échangeur Na+ /Ca2+ qui contribuent à générer des événements calciques spontanés. La phosphorylation du phospholamban, régulateur de l’activité de la SERCA2a, a également augmenté, laissant suggérer une compensation adaptative du cycle de Ca2+. Enfin, en présence de Ranolazine, inhibiteur du courant sodique soutenu, les évènements calciques spontanés ont été réprimés. En conclusion, le remodelage cardiaque dans l’IC/FEp semble être diffèrent de celui observé dans l’IC/FEr et ouvre la voie vers de nouveaux acteurs physiopathologiques et thérapeutiques. / Heart failure with preserved ejection fraction (HFpEF) is a growing health problem. It could become the leading cause of HF within a decade. It is a pathology associated with high morbidity and mortality. Therapeutic options are limited due to a lack of knowledge of the pathology and its evolution. In this work, we investigated the cellular phenotype and Ca2+ handling in hearts recapitulating HFpEF criteria. HFpEF was induced in a portion of male Wistar rats four weeks after abdominal aortic banding. These animals had nearly normal ejection fraction and presented elevated blood pressure, lung congestion, concentric hypertrophy, increased LV mass, wall stiffness, impaired active relaxation and passive filling of the left ventricle, enlarged left atrium, and cardiomyocyte hypertrophy. Left ventricular cell contraction was stronger and the Ca2+ transient larger. Ca2+ cycling was modified with a RyR2 mediated Ca2+ leak from the sarcoplasmic reticulum and impaired Ca2+ extrusion through the Na+ /Ca2+ (NCX), which promoted an increase in diastolic Ca2+ and spontaneous Ca2+ waves. PLN phosphorylation which promotes SERCA2a activity, was increased, suggesting an adaptive compensation of Ca2+ cycling. In the presence of Ranolazine, a sustained sodium current inhibitor, spontaneous Ca2+ events were suppressed. Cardiac remodeling in hearts with a HFpEF status differs from that known for HFrEF and opens the way to new pathophysiological and therapeutic actors. Insuffisance cardiaque diastolique Fraction d'ejection Calcium Hypertension Cardiomyocytes Ranolazine Diastolic heart failure Ejection fraction Calcium Hypertension Cardiomyocytes Ranolazine
6	Persistent and transient Na⁺ currents in hippocampal CA1 pyramidal neurons Park, Yul Young 13 October 2011 (has links) The biophysical properties and distribution of voltage gated ion channels shape the spatio-temporal pattern of synaptic inputs and determine the input-output properties of the neuron. Of the various voltage-gated ion channels, persistent Na⁺ current (INaP) is of interest because of its activation near rest, slow inactivation kinetics, and consequent effects on excitability. Overshadowed by transient Na⁺ current (INaT) of large amplitude and fast inactivation, various quantitative characterizations of INaP have yet to provide a clear understanding of their role in neuronal excitability. We addressed this question using quantitative electrophysiology to compare somatic INaP and INaT in 4–7 week old Sprague-Dawley rat hippocampal CA1 pyramidal neurons. INaP was evoked with 0.4 mV/ms ramp voltage commands and INaT with step commands in hippocampal neurons from in vitro brain slices utilizing nucleated patch-clamp recording. INaP was found to have a density of 1.4 ± 0.7 pA/pF in the soma. Compared to INaT, it has a much smaller amplitude (2.38% of INaT) and distinct voltage dependence of activation (16.7 mV lower half maximal activation voltage and 41.3% smaller slope factor than those of INaT). The quantitative measurement of INaT gave the activation time constant ([tau]m) of 22.2 ± 2.3 [mu]s at 40 mV. Hexanol, which has anesthetic effects, was shown to preferentially block INaP compared to INaT with a significant voltage threshold elevation (4.6 ± 0.7 mV) and delayed 1st spike latency (221 ± 54.6 ms) suggesting reduced neuronal excitability. The number of spikes evoked by either given step current injections or [alpha]-EPSP integration was also significantly decreased. The differential blocking of INaP by halothane, a popularly used volatile anesthetic, further supports the critical role of INaP in setting voltage threshold. Taken together, the presence of INaP in the soma demonstrates an intrinsic mechanism utilized by hippocampal CA1 pyramidal neurons to regulate axonal spike initiation through different biophysical properties of the Na⁺ channel. Furthermore, INaP becomes an interesting target of intrinsic plasticity because of its profound effect on the input-output function of the neuron. / text Persistent sodium current Transient sodium current Hippocampus Neuronal excitability Hexanol Riluzole Ranolazine
7	Ion transport pharmacology in heart disease and type-2 diabetes. Soliman, Daniel 06 1900 (has links) The cardiac sodium-calcium exchanger (NCX) is an important membrane protein which regulates cellular calcium necessary for the optimal contractile function of the heart. NCX has become a focal point in ischemic heart disease (IHD) research as evidence suggests that reactive oxygen species (ROS) produced during IHD can cause NCX to malfunction resulting in an intracellular calcium overload leading to cardiac contractile abnormalities. Therefore, I hypothesized that NCX function is mediated by ROS increasing NCX1 activity during cardiac ischemia-reperfusion. To research this hypothesis, I investigated cellular mechanisms which may play a role in NCX dysfunction and also examined methods to correct NCX function. I found that reactive oxygen species directly and irreversibly modify NCX protein, increasing its activity, thereby worsening the calcium overload which is deleterious to cardiac function. I also elucidated the molecular means by which NCX protein modification occurs. Exploring pharmacological means by which to decrease NCX function to relieve the calcium overload and reduce the damage to the heart, I discovered that ranolazine (Ranexa), indicated for the treatment of angina pectoris inhibits NCX activity directly, thereby further reducing the calcium overload-induced injury to the heart. Furthermore, many IHD patients are also co-morbid for type-2 diabetes. These patients are prescribed sulfonylurea (SU) agents which act at the ATP sensitive K+ channel (KATP). One agent such as glibenclamide is known to have cardiotoxic side effects. Therefore, SUs devoid of any cardiac side effects would beneficial. Interestingly, patients possessing the genetic variant E23K-S1369A KATP channel have improved blood glucose levels with the use of the SU gliclazide. Therefore, I determined the functional mechanism by which gliclazide has increased inhibition at the KATP channel. These findings have implications for type-2 diabetes therapy, in which 20% of the type-2 diabetic population carries the KATP channel variant. In summary, the findings presented in this thesis have implications on treatment strategies in the clinical setting, as a NCX inhibitor can be beneficial in IHD and possibly type-2 diabetes. Moreover, a pharmacogenomic approach in treating type-2 diabetes may also provide a positive outcome when considering co-morbid cardiac complications such as atrial fibrillation and heart failure. heart disease type-2 diabetes pharmacology reactive oxygen species sulfonylureas ranolazine sodium-calcium exchanger ATP-sensitive potassium channel patch clamping
8	Ion transport pharmacology in heart disease and type-2 diabetes. Soliman, Daniel Unknown Date No description available. heart disease type-2 diabetes pharmacology reactive oxygen species sulfonylureas ranolazine sodium-calcium exchanger ATP-sensitive potassium channel patch clamping
9	Die Rolle des späten Natriumstroms (late INa) bei Druck-induzierter Hypertrophie und bei Herzinsuffizienz / Role of late sodium current in pressure overload-induced hypertrophy and heart failure Hartmann, Nico Horst 31 March 2015 (has links) No description available. 610 Hypertrophie Arrhythmien später Natriumstrom (lateINa) CaMKII Ranolazin Hypertrophy Arrhythmias late INa CaMKII Ranolazine
10	Die Rolle des späten Natrium-Stroms bei der Kalzium-Calmodulin-abhängigen ProteinkinaseIIδC (CaMKIIδC)-induzierten Herzinsuffizienz und beim chronischen Vorhofflimmern / The role of the late sodium current in calcium-calmodulin-dependent protein kinase II δC (CaMKIIδC)-induced heart failure and chronic atrial fibrillation Maurer, Ulrike Kerstin 02 July 2012 (has links) No description available. 610 Medizin, Gesundheit MED 411 Medicine Ranolazin später Natrium-Strom CaMKII SERCA NCX Herzinsuffizienz Vorhofflimmern diastolische Dysfunktion Ranolazine late sodium current CaMKII SERCA NCX heart failure atrial fibrillation diastolic dysfunction 44.85

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