Global ETD Search

21	Mechanisms of excitability in the central and peripheral nervous systems : Implications for epilepsy and chronic pain Tigerholm, Jenny January 2012 (has links) The work in this thesis concerns mechanisms of excitability of neurons. Specifically, it deals with how neurons respond to input, and how their response is controlled by ion channels and other active components of the neuron. I have studied excitability in two systems of the nervous system, the hippocampus which is responsible for memory and spatial navigation, and the peripheral C–fibre which is responsible for sensing and conducting sensory information to the spinal cord. Within the work, I have studied the role of excitability mechanisms in normal function and in pathological conditions. For hippocampus the normal function includes changes in excitability linked to learning and memory. However, it also is intimately linked to pathological increases in excitability observed in epilepsy. In C–fibres, excitability controls sensitivity to responses to stimuli. When this response becomes enhanced, this can lead to pain. I have used computational modelling as a tool for studying hyperexcitability in neurons in the central nervous system in order to address mechanisms of epileptogenesis. Epilepsy is a brain disorder in which a subject has repeated seizures (convulsions) over time. Seizures are characterized by increased and highly synchronized neural activity. Therefore, mechanisms that regulate synchronized neural activity are crucial for the understanding of epileptogenesis. Such mechanisms must differentiate between synchronized and semi synchronized synaptic input. The candidate I propose for such a mechanism is the fast outward current generated by the A-type potassium channel (KA). Additionally, I have studied the propagation of action potentials in peripheral axons, denoted C–fibres. These C–fibres mediate information about harmful peripheral stimuli from limbs and organs to the central nervous system and are thereby linked to pathological pain. If a C–fibre is activated repeatedly, the excitability is altered and the mechanisms for this alteration are unknown. By computational modelling, I have proposed mechanisms which can explain this alteration in excitability. In summary, in my work I have studied roles of particular ion channels in excitability related to functions in the nervous system. Using computational modelling, I have been able to relate specific properties of ion channels to functions of the nervous system such as sensing and learning, and in particular studied the implications of mechanisms of excitability changes in diseases. / <p>QC 20102423</p> Dendritic excitability synchronized synaptic input multicompartment model epilepsy axonal excitability silent C–fibres Hodgkin–Huxley dynamics conduction velocity KA
22	Preparation for Nerve Membrane Potential Readings of a Leech, Laboratory Setup and Dissection Process Caulfield, Jason Patrick 01 June 2009 (has links) (PDF) A well documented laboratory setup, leech preparation process, and bio-potential data recording process are needed. Repeatability and quality data recordings are essential and thus dictate the requirements of the laboratory setup and processes listed above. Advances in technology have both helped and hindered this development. While very precise equipment is required to record the low voltage bio-potentials, noisy electronic equipment and wires surrounding the work area provide high levels of interference. Proper laboratory setup and data recording processes, however, limit the unwanted interference. Quality data can only be recorded from a properly handled and prepared leech subject. Proper setup and procedures result in quality recordings which lend a clean signal for furthering the understanding of nerve functionality. The electrophysiology lab at California Polytechnic State University in San Luis Obispo is an example of a proven lab setup for high quality signal capture. leech action-potential laboratory bio-potential Hodgkin Huxley axon nerve ganglia neuron voltage-gated-ion-channels
23	Duty Cycle Maintenance in an Artificial Neuron Barnett, William Halbert 01 October 2009 (has links) Neuroprosthetics is at the intersection of neuroscience, biomedical engineering, and physics. A biocompatible neuroprosthesis contains artificial neurons exhibiting biophysically plausible dynamics. Hybrid systems analysis could be used to prototype such artificial neurons. Biohybrid systems are composed of artificial and living neurons coupled via real-time computing and dynamic clamp. Model neurons must be thoroughly tested before coupled with a living cell. We use bifurcation theory to identify hazardous regimes of activity that may compromise biocompatibility and to identify control strategies for regimes of activity desirable for functional behavior. We construct real-time artificial neurons for the analysis of hybrid systems and demonstrate a mechanism through which an artificial neuron could maintain duty cycle independent of variations in period. Hybrid systems Real time systems Hodgkin huxley Neuronal dynamics Electrophysiology Dynamic clamp Medicinal leech Central pattern generator Half center oscillator Heartbeat Bifurcation theory Astrophysics and Astronomy Physics
24	Réseaux de neurones sur silicium : une approche mixte, analogique / numérique, pour l'étude des phénomènes d'adaptation, d'apprentissage et de plasticité Bornat, Yannick 01 December 2006 (has links) (PDF) Dans un contexte où l'usage de circuits neuromimétiques se généralise au sein des neurosciences, nous étudions ici leur intégration au sein de réseaux adaptatifs. Les circuits mis en oeuvre se basent sur un modèle proche de la biologie résolu en continu et en temps réel. Les calculs relatifs à l'adaptation du réseau sont réalisés en numérique temps réel, logiciel et/ou matériel. La partie logicielle est assurée par un ordinateur interfacé à travers le bus PCI, tandis que la partie matérielle utilise des EPGAS. Trois générations sont présentés avec une analyse critique sur leur utilisation comme système de simulation de réseau neuronal. Réseaux de neurones plasticité synaptique neurones artificiels modèle Hodgkin-Huxley
25	Silicon neural networks : implementation of cortical cells to improve the artificial-biological hybrid technique / Réseau de neurones in silico : contribution au développement de la technique hybride pour les réseaux corticaux Grassia, Filippo Giovanni 07 January 2013 (has links) Ces travaux ont été menés dans le cadre du projet européen FACETS-ITN. Nous avons contribué à la simulation de cellules corticales grâce à des données expérimentales d'électrophysiologie comme référence et d'un circuit intégré neuromorphique comme simulateur. Les propriétés intrinsèques temps réel de nos circuits neuromorphiques à base de modèles à conductance, autorisent une exploration détaillée des différents types de neurones. L'aspect analogique des circuits intégrés permet le développement d'un simulateur matériel temps réel à l'échelle du réseau. Le deuxième objectif de cette thèse est donc de contribuer au développement d'une plate-forme mixte - matérielle et logicielle - dédiée à la simulation de réseaux de neurones impulsionnels. / This work has been supported by the European FACETS-ITN project. Within the frameworkof this project, we contribute to the simulation of cortical cell types (employingexperimental electrophysiological data of these cells as references), using a specific VLSIneural circuit to simulate, at the single cell level, the models studied as references in theFACETS project. The real-time intrinsic properties of the neuromorphic circuits, whichprecisely compute neuron conductance-based models, will allow a systematic and detailedexploration of the models, while the physical and analog aspect of the simulations, as opposedthe software simulation aspect, will provide inputs for the development of the neuralhardware at the network level. The second goal of this thesis is to contribute to the designof a mixed hardware-software platform (PAX), specifically designed to simulate spikingneural networks. The tasks performed during this thesis project included: 1) the methodsused to obtain the appropriate parameter sets of the cortical neuron models that can beimplemented in our analog neuromimetic chip (the parameter extraction steps was validatedusing a bifurcation analysis that shows that the simplified HH model implementedin our silicon neuron shares the dynamics of the HH model); 2) the fully customizablefitting method, in voltage-clamp mode, to tune our neuromimetic integrated circuits usinga metaheuristic algorithm; 3) the contribution to the development of the PAX systemin terms of software tools and a VHDL driver interface for neuron configuration in theplatform. Finally, it also addresses the issue of synaptic tuning for future SNN simulation. Neurosciences computationnelles Modèle de Hodgkin Huxley Analyse de bifurcation Algorithmes métaheuristiques Systèmes neuromorphiques Réseaux de neurones Computational Neurosciences Hodgkin and Huxley model Bifurcation Analysis Metaheuristic Algorithms Neuromorphic Systems Spiking Neural Networks
26	Action Potential Simulation of the Hirudo Medicinalis's Retzius Cell in MATLAB Tempesta, Zechari Ryan 01 December 2013 (has links) Modification of Hodgkin and Huxley’s experimentally derived set of nonlinear differential equations was implemented to accurately simulate the action potential of the Hirudo Medicinalis’s Retzius cell in MATLAB under analogous conditions to those found in the Retzius cell environment. The voltage-gated sodium and potassium channel responses to changes in membrane potential, as experimentally determined by Hodgkin and Huxley, were manipulated to suit simulation parameters established by electrophysiological Retzius cell recordings. Application of this methodology permitted additional accurate simulation of the Hirudo Medicinalis’s P cell under analogous conditions to those found in the P cell environment. Further refinement of this technique should allow for the voltage-gated behavioral based simulation of action potential waveforms found in variety of neurons under simulation conditions analogous to the nerve cell environment. Retzius cell Hirudo medicinalis action potential electrophysiology computational simulation Hodgkin-Huxley Model Voltage-gated ion channels Computational Engineering
27	Collective Dynamics of Excitable Tree Networks Khaledi Nasab, Ali 23 September 2019 (has links) No description available. Biophysics Nanoscience Physics Excitable tree networks Random trees Hodgkin-Huxley Collective dynamics Diffusively coupled excitable elements Frankenhaeuser-Huxley Stochastic dynamics Deterministic dynamics
28	Noise Decomposition for Stochastic Hodgkin-Huxley Models Pu, Shusen 26 January 2021 (has links) No description available. Mathematics Neurosciences Cognitive Psychology Hodgkin-Huxley Models Langevin Models Efficient Stochastic Simulations Stochastic Shielding Variance of Interspike Interval Phase Response Curve Model Comparison Noise Decomposition Theorem
29	Neural membrane mutual coupling characterisation using entropy-based iterative learning identification Tang, X., Zhang, Qichun, Dai, X., Zou, Y. 17 November 2020 (has links) Yes / This paper investigates the interaction phenomena of the coupled axons while the mutual coupling factor is presented as a pairwise description. Based on the Hodgkin-Huxley model and the coupling factor matrix, the membrane potentials of the coupled myelinated/unmyelinated axons are quantified which implies that the neural coupling can be characterised by the presented coupling factor. Meanwhile the equivalent electric circuit is supplied to illustrate the physical meaning of this extended model. In order to estimate the coupling factor, a data-based iterative learning identification algorithm is presented where the Rényi entropy of the estimation error has been minimised. The convergence of the presented algorithm is analysed and the learning rate is designed. To verified the presented model and the algorithm, the numerical simulation results indicate the correctness and the effectiveness. Furthermore, the statistical description of the neural coupling, the approximation using ordinary differential equation, the measurement and the conduction of the nerve signals are discussed respectively as advanced topics. The novelties can be summarised as follows: 1) the Hodgkin-Huxley model has been extended considering the mutual interaction between the neural axon membranes, 2) the iterative learning approach has been developed for factor identification using entropy criterion, and 3) the theoretical framework has been established for this class of system identification problems with convergence analysis. / This work was supported in part by the National Natural Science Foundation of China (NSFC) under Grant 51807010, and in part by the Natural Science Foundation of Hunan under Grant 1541 and Grant 1734. / Research Development Fund Publication Prize Award winner, Nov 2020. Neural coupling analysis Extended Hodgkin-Huxley model Equivalent electric circuit Information entropy Iterative learning Convergence analysis Statistical description Kernel density estimation
30	A Fast Numerical Method for Large-Scale Modeling of Cardiac Tissue and Linear Perturbation Theory for the Study and Control of Cardiac Spiral Wave Breakup Allexandre, Didier 01 September 2004 (has links) No description available. Cardiac Arrhythmia Spiral Wave Reentry Fibrillation Modeling Computer model Control Electrode Action Potential Algorithm Numerical method Simulation Finite Difference Eigenmode Linear Perturbation Hodgkin-Huxley Heart

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