Global ETD Search

51	Gap Junction Formation in Heart Valves in Response to Mechanical Loading O'Malley, Karen L. 28 June 2013 (has links) Valvular interstitial cells (VICs) are responsible for the maintenance of heart valve leaflet structure, however their responses to mechanical loading are not fully understood. Further characterization of VIC responses with regards to phenotype (quiescent or activated via ?-smooth muscle actin [?-SMA]) and communication (through gap junction proteins connexins 43 and 26) were studied. Tissue strips from porcine aortic, pulmonary, and mitral valves were cyclically stretched in the circumferential direction at normal and above normal membrane tensions for 48 hours at 1 Hz, 37°C, and 5% CO2. Unloaded tissues were statically incubated concurrently with loaded tissues, and fresh tissue controls were collected immediately. VIC phenotype was identified by ?- SMA via immunohistochemical staining and cell enumeration, as well as by gene expression via RT-PCR. Gap junction protein Cx43 was also evaluated via immunohistochemical staining and cell enumeration and by gene expression via RT-PCR, whereas Cx26 was evaluated using immunohistochemical staining and cell enumeration only. Within the range tested, it was found that mechanical loading did not affect ?-SMA or gap junction protein levels, nor were any differences in responses noted between valve types. However, the ?-SMA gene expression level was significantly lower in the mitral valve compared to the aortic and pulmonary valves. This may indicate a difference in the genetic response pathways among the valves, but not in the functional outcomes. This difference may be explained by embryological origins, since the mitral valve, unlike the aortic and pulmonary valves, contains only VICs and no neural crest cells. Connexins Gap junctions Stretch Mechanical loading A-SMA Heart valves VICs Cx43 Cx26
52	Influence of environmental and chemical factors on cellular signaling in lens epithelial cells Long, Amy Carise, January 2007 (has links) Thesis (Ph. D.)--Ohio State University, 2007. / Title from first page of PDF file. Includes bibliographical references (p. 120-147).
53	Evidence for neuron-glia signaling in trigeminal ganglia : implication in temporomandibular joint pathology / Thalakoti, Srikanth, January 1900 (has links) Thesis (M.S.)--Missouri State University, 2008. / "May 2008." Includes bibliographical references (leaves 56-63). Also available online.
54	TNF-a regulation of cell signaling in trigeminal ganglion in an in vivo model of TMJ inflammation / Damodaram, Srikanth, January 1900 (has links) Thesis (M.S.)--Missouri State University, 2008. / "August 2008." Includes bibliographical references (leaves 101-112). Also available online.
55	Endothelial cell function using a tissue engineered blood vessel model a case study of cell-cell communication / Johnson, Tiffany Lynn. January 2006 (has links) Thesis (Ph. D.)--Biomedical Engineering, Georgia Institute of Technology, 2006. / Pollman, Matthew, Committee Member ; Galis, Zorina, Committee Member ; McIntire, Larry, Committee Member ; Taylor, W Robert, Committee Member ; Jo, Hanjoong, Committee Member ; Nerem, Robert, Committee Chair.
56	Influence des ratios de co-expression précis Cx43 : Cx45 sur la formation des canaux de jonction et leurs propriétés électriques / Influence of Cx43 : Cx45 accurate co-expressed ratios on gap junction channels formation and their electricals properties Dupuis, Sebastien 16 December 2016 (has links) Les canaux de jonctions (CJ) composés des connexines (Cxs) assurent la communication intercellulaire directe qui par leur propriétés électriques régulent la propagation du potentiel d’action (PA) cardiaque. Dans les myocytes ventriculaires Cx43 et Cx45 exprimées à des niveaux et ratios physiopathologiques variables assurent cette fonction. Cette étude détermine la contribution de Cx43 et Cx45 dans la formation des CJ et leurs propriétés électriques. La lignée cellulaire épithéliale de foie de rat exprimant la Cx43 endogène et transfectée de manière stable pour exprimer des ratios Cx43:Cx45 précis a été utilisée. Les propriétés électriques des CJ ont été obtenues par double voltage clamp sur paires de cellules. L’expression de la Cx45 diminue le couplage électrique et augmente la dépendance au potentiel de jonction indépendamment du ratio. Les cinétiques de désactivation sont ralenties avec l’augmentation du niveau d’expression de Cx45 et les cinétiques de restitution sont modifiées en fonction du ratio. Les conductances unitaires suggèrent la formation de CJ composés de Cx43 et Cx45. La diminution du niveau d’expression de Cx43 par ARNi anti-Cx43 entraine une diminution du couplage électrique tandis que les autres propriétés électriques restent inchangées. Ces résultats montrent une contribution spécifique de Cx43 et Cx45 dans la régulation de la formation et des propriétés électriques des CJ caractérisées. Ces propriétés seront corrélées à la participation des CJ dans la régulation de la propagation du PA en fonction des profils d’expression des Cxs en conditions physiologiques et pathologiques. / Gap junction channels (GJCs), composed of connexins (Cxs) allow a direct intercellular communication that ensures the cardiac action potential (AP) propagation. Cx43 and Cx45 co-expressed in ventricular myocytes with changing expression levels and ratios in the healthy and the diseased heart ensure this function. The purpose of this study is to determine the contribution of Cx43 and Cx45 on the formation of GJCs and their electrical properties. Rat Liver Epithelial cells that endogenously express Cx43 and stably transfected to co-express accurate Cx43:Cx45 ratios have been used. The electrical properties of GJCs at each ratios were obtained by performing dual voltage clamp recordings on cell pairs. Expression of Cx45 decreases the electrical coupling and increases the voltage dependence independently of the ratio. The kinetics of deactivation are slowed with the increases of Cx45 level of expression and the kinetics of recovery are modified in a Cx43:Cx45 ratio dependent manner. Unitary conductances suggest a formation of GJCs composed by Cx43 and Cx45. The decreases of Cx43 level of by a SiRNA treatment induces a decrease of the electrical coupling, while other electrical properties are not affected. Our data show a specific contribution of Cx43 and Cx45 in regulation of the GJCs characterized by specific electrical properties. Such properties will be correlated to the function of GJCs in regulating the AP propagation in the specific patterns of expression of Cxs in the healthy and diseased heart. Jonctions communicantes Connexines Double voltage clamp Propriétés électriques Gap junctions Connexins Dual voltage clamp Electrical properties
57	Information processing in the Striatum : a computational study Hjorth, Johannes January 2006 (has links) The basal ganglia form an important structure centrally placed in the brain. They receive input from motor, associative and limbic areas, and produce output mainly to the thalamus and the brain stem. The basal ganglia have been implied in cognitive and motor functions. One way to understand the basal ganglia is to take a look at the diseases that affect them. Both Parkinson's disease and Huntington's disease with their motor problems are results of malfunctioning basal ganglia. There are also indications that these diseases affect cognitive functions. Drug addiction is another example that involves this structure, which is also important for motivation and selection of behaviour. In this licentiate thesis I am laying the groundwork for a detailed model of the striatum, which is the input stage of the basal ganglia. The striatum receives glutamatergic input from the cortex and thalamus, as well as dopaminergic input from substantia nigra. The majority of the neurons in the striatum are medium spiny (MS) projection neurons that project mainly to globus pallidus but also to other neurons in the striatum and to both dopamine producing and GABAergic neurons in substantia nigra. In addition to the MS neurons there are fast spiking (FS) interneurons that are in a position to regulate the firing of the MS neurons. These FS neurons are few, but connected into large networks through electrical synapses that could synchronise their effect. By forming strong inhibitory synapses on the MS neurons the FS neurons have a powerful influence on the striatal output. The inhibitory output of the basal ganglia on the thalamus is believed to keep prepared motor commands on hold, but once one of them is disinhibited, then the selected motor command is executed. This disinhibition is initiated in the striatum by the MS neurons. Both MS and FS neurons are active during so called up-states, which are periods of elevated cortical input to striatum. Here I have studied the FS neurons and their ability to detect such up-states. This is important because FS neurons can delay spikes in MS neurons and the time between up-state onset and the first spike in the MS neurons is correlated with the amount of calcium entering the MS neuron, which in turn might have implications for plasticity and learning of new behaviours. The effect of different combinations of electrical couplings between two FS neurons has been tested, where the location, number and strength of these gap junctions have been varied. I studied both the ability of the FS neurons to fire action potentials during the up-state, and the synchronisation between neighbouring FS neurons due to electrical coupling. I found that both proximal and distal gap junctions synchronised the firing, but the distal gap junctions did not have the same temporal precision. The ability of the FS neurons to detect an up-state was affected by whether the neighbouring FS neuron also received up-state input or not. This effect was more pronounced for distal gap junctions than proximal ones, due to a stronger shunting effect of distal gap junctions when the dendrites were synaptically activated. We have also performed initial stochastic simulations of the Ca2+-calmodulin-dependent protein kinase II (CaMKII). The purpose here is to build the knowledge as well as the tools necessary for biochemical simulations of intracellular processes that are important for plasticity in the MS neurons. The simulated biochemical pathways will then be integrated into an existing model of a full MS neuron. Another venue to explore is to build striatal network models consisting of MS and FS neurons and using experimental data of the striatal microcircuitry. With these different approaches we will improve our understanding of striatal information processing. / QC 20101116 striatum fast spiking interneuron gap junctions synchronisation up-state detection CaMKII mathematical modelling Neurosciences Neurovetenskaper
58	Characterization of Conduction Abnormalities in Canine Models of Atrial Arrhythmias Ryu, Kyungmoo 07 April 2005 (has links) No description available. Engineering, Biomedical Atrial arrhythmias Atrial Fibrillation Atrial Flutter Cardiac mapping Conduction abnormalities Atrial pacing Gap junctions
59	"Mechanisms of Adrenal Medullary Excitation Under the Acute Sympathetic Stress Response" Hill, Jacqueline Suzanne 27 August 2012 (has links) No description available. Neurosciences Physiology Acute stress voltage-gated calcium channels PACAP gap junctions patch clamp electrophysiology
60	The Implications Of Gap Junction Inhibition In Jurkat Cell-CellCommunication And Proliferation Shaw, Jeremy Joseph Porter 16 May 2014 (has links) No description available. Biomedical Research Acute Myeloid Leukemia Jurkat Cells Gap Junctions 1-Octanol Carbenoxolone Calcein AM DiI

Search results