Global ETD Search

1	Intrinsic and synaptic properties of membrane channels in mediating thalamocortical network neuronal activities: A computational analysis January 2021 (has links) archives@tulane.edu / The thalamocortical network generates rhythmic oscillations of various frequencies that underlie different brain states. Importantly, the transition from a faster frequency of firing, spindle, to slower oscillations, spike and wave discharges, is indicative of the pathological epileptic seizure development. Previous investigations have shown that the complex interactions between neurons in the thalamocortical network based on intrinsic and synaptic properties give rise to the observed frequency changes. However, the exact mechanism of how perturbations in this circuit disrupt the oscillations is not known. In this project, we used a well-established thalamocortical network computational model to perform receptor conductance changes to see how the oscillatory activity in the thalamocortical network changes. Computational methods can be used to provide some mathematical explanations regarding the mechanism of oscillations. Therefore, we generated several phase resetting curves by perturbing neurons during its oscillating period. Our results showed that the frequency reduction under the pathological state in the thalamocortical network might be caused by hyper-synchronization of neuronal activities in this circuit mediated by glutamatergic AMPA receptors. Notably, thalamic reticular neurons are capable of firing at a faster or slower frequency depending on the timing of the input that they receive from other neurons. Overall, our results provided evidence to support the hypothesis that thalamic reticular neurons might be the ultimate pacemakers in the thalamocortical network. / 1 / Hanyun Wang thalamocortical network Computational Model seizure
2	Role of transcription factor Pax6 in the development of the thalamocortical tract Clegg, James Matthew January 2013 (has links) During development the nuclei of the thalamus form reciprocal connections with specific regions within the cortex. These connections give rise to the thalamocortical tract. The processes by which axons of the thalamocortical tract are guided to their target regions are poorly understood. It has been shown that diffusible or membrane bound factors can have a chemoattractive or chemorepulsive effect on the tip or growth cone of the axon. Thalamocortical axons may also be guided along ‘pioneer’ axon populations that form a scaffold along which axons may grow. The transcription factor Pax6 has been shown to have a role in a variety of developmental processes such as neuronal patterning, proliferation, migration and axon guidance. It is known that Pax6 is involved in the development of the thalamocortical tract but its exact role is unknown. To explore the role that Pax6 plays in the development of the thalamocortical tract I have used two different mouse models, the small eye (Pax6Sey/Sey) mouse which lacks functional Pax6, and a conditional Pax6 knock-out (Pax6cKO) mouse made using a Gsh2 Cre line that specifically reduces Pax6 expression in the ventral telencephalon and prethalamus. Using the Pax6Sey/Sey mouse I show that thalamocortical axons do not enter the ventral telencephalon in the absence of Pax6 and that a small number of axons incorrectly enter the hypothalamus. In addition axons found within the ventral telencephalon of the mutant do not originate from the thalamus but instead originate from cells within the ventral telencephalon itself. I have found that the expression of guidance molecule Robo2 is reduced in the Pax6Sey/Sey mouse, which may explain why thalamocortical axons enter the hypothalamus. When Pax6 expression is reduced at the prethalamus and ventral telencephalon using the Pax6cKO mouse I show that the majority of thalamocortical axons reach the cortex normally but some axons become disorganized within the thalamus. Pioneer axons which emanate from the prethalamus normally guide thalamocortical axons through the diencephalon but in the Pax6cKO I report that these axons are reduced which may explain the disorganization of thalamocortical axons within the thalamus. Taken together the data from these two models demonstrate that for the thalamocortical tract to form normally Pax6 expression is required in both the cells of the thalamus and in cells that lie along the route of the tract. In addition I provide evidence that Pax6 may influence axon guidance by controlling the expression of guidance molecules and the development of pioneer axon tracts. 612.8
3	Investigating the mechanism by which thalamocortical projections reach the cerebral cortex Chen, Yijing January 2012 (has links) This thesis provides insights into the mechanism by which thalamocortical axons (TCAs) approach the cortex from their origin in the thalamus. Previous studies suggested that the reciprocal projections from the prethalamus and the ventral telencephalon guide TCAs to descend through the prethalamus and cross the diencephalic-telencephalic boundary (DTB), after which TCAs navigate through permissive corridor cells in the ventral telencephalon and cross the pallial-subpallial boundary (PSPB) before reaching their final targets in the cortex. The ‘Handshake Hypothesis’ proposed that pioneer axons from cortical preplate neurons guide TCAs into corresponding cortical areas. However, there is a lack of convincing evidence on whether TCAs need any guidance to cross the PSPB. In the current study, Adenomatous polyposis (Apc) gene is conditionally deleted from the cortex, by using Emx1Cre-APCloxP recombination technology. Apc is widely expressed in the nervous system including the cortical plate of the cortex and regulates axonal growth and neuronal differentiation. Deleting Apc may block neurite extension and/or affect the formation of attractive or repulsive cues in the cortex. By using DiI tracing as well as L1 immunohistochemistry techniques, I showed that in the Apc mutants cortical axons are absent and that TCAs initially navigate into the ventral telencephalon normally but fail to complete their journey into the cortex. They stop as they approach the PSPB, although the PSPB doesn’t seem to be directly affected by the mutation of Apc in the cortex. Additionally, Ig-Nrg1 (Neuregulin-1), the secreted protein that was suggested to play long-range roles in attracting TCAs towards the cortex, is present in the Apc mutant. This implies that Ig-Nrg1 is not sufficient for guiding TCAs into the cortex, and that additional guidance factors are needed. Moreover, my in vitro explant culture experiments show that the mutant cortex neither repel nor inhibit thalamic axonal outgrowth, indicating that the failure of TCAs in reaching the cortex is not due to the change of repulsive cues secreted by the mutant cortex. It rather indicates that the guidance factors for TCAs are likely to function through cell-cell contact mediated mechanisms. The Apc mutant cortex lacks these guidance factors, which might be the cortical axons. In conclusion, my data reveal a choice point for TCAs at the PSPB. Guidance factors from the cortex are needed for TCAs to cross the PSPB, which are absent in the Apc mutant. TCAs may need the direct contact with cortical axons and use them as an axonal scaffold to navigate into the cerebral cortex. 612.825
4	Functional Development and Plasticity of Parvalbumin Cells in Visual Cortex: Role of Thalamocortical Input Quast, Kathleen Beth 06 August 2013 (has links) Unlike principal excitatory neurons, cortical interneurons comprise a diverse group of distinct subtypes. They can be classified by their morphology, molecular content, developmental origins, electrophysiological properties and specific connectivity patterns. The parvalbumin-positive \((PV^+)\), large basket interneuron has been implicated in two cortical functions: 1) the control and shaping of the excitatory response, and 2) the initiation of critical periods for plasticity. Disruptions in both phenomena have been implicated in the etiology of cognitive developmental disorders. Careful characterization of \(PV^+\) cell function and plasticity in response to their primary afferent, the thalamocortical synapse, is needed to directly relate their vital contribution at a synapse-specific or network level to whole animal behavior. Here, I used electrophysiological, anatomical and molecular genetic techniques in a novel slice preparation to elucidate \(PV^+\) circuit development and plasticity in mouse visual cortex. I found that GFP-positive \(PV^+\) cells in layer 4 undergo a rapid maturation after eye opening just prior to onset of the critical period. This development occurs across a number of intrinsic physiological properties that shape their precise, fast spiking. I further optimized and characterized a visual thalamocortical slice to examine the primary afferent input onto both pyramidal and \(PV^+\) cells. Thalamic input onto \(PV^+\) cells is larger, faster and again matures ahead of the critical period. Both the intrinsic and synaptic properties of \(PV^+\) cells are then maintained by a secreted homeoprotein, Otx2 (Sugiyama et al, 2008), which is mediated by an extracellular glycosaminoglycan recognition. Since the plasticity of fast-spiking, inhibitory neurons is dramatically distinct from their neighboring pyramidal neurons in vivo (Yazaki-Sugiyama et al. 2009), I directly examined the plasticity of thalamocortical synapses in vitro. After brief monocular deprivation, thalamic input specifically onto \(PV^+\) cells is reduced while remaining unaltered in pyramidal cells. Deprivations prior to critical period onset or in GAD65 knockout mice neither produce a shift of visual responsiveness in vivo (Hensch et al, 1998) nor reduce thalamocortical input onto \(PV^+\) cells. These results directly confirm that \(PV^+\) cells are uniquely sensitive to visual experience, which may drive further rewiring of the surrounding excitatory cortical network. Neurosciences critical period inhibition otx2 plasticity thalamocortical vision
5	A thalamocortical theory of propofol phase-amplitude coupling Soplata, Austin Edward 07 October 2019 (has links) Propofol is one of the most commonly used general anesthetics in the world, and yet precisely how it enables loss of consciousness still eludes us. It exhibits rich spectral characteristics on electroencephalogram (EEG) recordings from human patients, including alpha oscillations (8-14 Hz) and Slow Wave Oscillations (SWO, 0.5-2.0 Hz). Additionally, these two oscillations are phase-amplitude coupled (PAC) in a dose-dependent manner: low doses cause “trough-max” coupling where alpha power is maximal during the trough of the SWO cycle, while high doses cause “peak-max” coupling where alpha power is maximal during the peak of the SWO cycle. These propofol rhythms occur at the same frequencies as sleep spindles and sleep SWO, and likely use the same well-studied thalamocortical circuitry. The study of anesthesia therefore represents a safe method for investigating both how our brains sleep and the much-debated components of consciousness. In this dissertation, I use Hodgkin-Huxley-style computational models of both the thalamus and cortex to explain how the direct and indirect effects of propofol can generate such spectral phenomena. In the first part of this dissertation, I discuss results from a thalamic model. I illustrate how GABAA potentiation by propofol can create sustained alpha oscillations in the hyperpolarized thalamus by utilizing the same mechanisms used by sleep spindles. I then show how the thalamus, under artificial SWO conditions, can output trough-max or peak-max PAC depending on background excitation, GABAA potentiation, and H-current conductance. In the second part of this dissertation, I discuss results from a thalamocortical model. My analysis reveals how, in a simulated EEG signal, trough-max PAC can arise from competition between thalamocortical and intracortical synaptic currents, while peak-max PAC can arise from their cooperation. Furthermore, the coherence of cortical SWO rhythms can directly control whether the system expresses trough-max or peak-max PAC, while the indirect effects of propofol on acetylcholine are required for both PAC states. This culmination of years of work reveals just how complex the inner workings of anesthesia can be in enabling its profound effects. Neurosciences Anesthesia Computational neuroscience Neural oscillations Propofol Thalamocortical Thalamus
6	Role for Gli3 in the formation of the major axonal tracts in the telencephalon Magnani, Dario January 2011 (has links) In the adult brain, the thalamocortical tract conveys sensory information from the external environment to the cortex. The cortex analyzes and integrates this information and sends neural responses back to the thalamus through the corticothalamic tract. To reach their final target both thalamocortical and corticothalamic axons have to cover long distances during embryogenesis, changing direction several times and passing through different brain territories. The ventral telencephalon plays a major role in the early development of these tracts. At least three main axon guidance mechanisms act in the ventral telencephalon. First, two different populations of pioneer neurons in the lateral ganglionic eminence (LGE) (LGE pioneer neurons) and medial ganglionic eminence (MGE) (MGE pioneer neurons) provide scaffolds which allow growing corticothalamic and thalamocortical axons to cross the pallium sub pallium boundary (PSPB) and the diencephalic telencephalic boundary (DTB), respectively. Second, the ventral telencephalon forms a permissive corridor for thalamic axons by tangential migration of Isl1 and Ebf1 expressing cells from the LGE into the MGE. Finally, thalamortical and corticothalamic axons guide each other once they have met in the ventral telencephalon (“handshake hypothesis”). The Gli3 transcription factor has been shown to be essential for normal early embryonic regionalization of the mammalian forebrain, although roles of Gli3 in later aspects of forebrain development, like the formation of axonal connections, have not been investigated previously. Here, I present the analysis of axonal tract development in the forebrain of the Gli3 hypomorphic mutant mouse Polydactyly Nagoja (Pdn). These animals lack the major axonal commissures of the forebrain: the corpus callosum, the hippocampal commissure, the anterior commissure and the fimbria. In addition, DiI injections and neurofilament (NF) staining showed defects in the formation of the corticothalamic and thalamocortical tracts. Although the Pdn/Pdn cortex forms early coticofugal neurons and their axons, these axons do not penetrate the LGE and instead run along the PSPB. Later in development, although a thick bundle of Pdn/Pdn cortical axons is still observed to project along the PSPB, some Pdn/Pdn cortical axons eventually enter the ventral telencephalon navigating along several abnormal routes until they reach thalamic regions. In contrast, Pdn/Pdn thalamic axons penetrate into the ventral telencephalon at early stages of thalamic tract development. However, rostrally they deviate from their normal trajectory, leaving the internal capsule prematurely and only few of them reach the developing cortex. Caudally, an ectopic Pdn/Pdn dorsal thalamic axon tract projects ventrally in the ventral telencephalon not entering the internal capsule at all. These defects are still observed in newborn Pdn/Pdn mutant mice. Next, I investigated the developmental mechanisms causing these pathfindings defects. No obvious defects are present in Pdn/Pdn cortical laminae formation and in the patterning of the Pdn/Pdn dorsal thalamus. In addition, Pdn/Pdn thalamocortical axons are able to respond to ventral telencephalic guidance cues when transplanted into wild type brain sections. However, these axonal pathfinding defects correlate with patterning defects of the Pdn/Pdn LGE. This region is partially ventralized and displays a reduction in the number of postmitotic neurons in the mantle zone due to an elongated cell cycle length of LGE progenitor cells. Finally, Pdn/Pdn mutant display an upregulation of Shh expression and Shh signalling in the ventral telencephalon. Interestingly, these patterning defects lead to the absence of DiI back-labelled LGE pioneer neurons, which correlates with the failure of corticothalamic axons to penetrate the ventral telencephalon. In addition, ventral telencephalic thalamocortical guidance mistakes happen at the same time of abnormal formation of the corridor cells. Taken together these data reveal a novel role for Gli3 in the formation of ventral telencephalic intermediate cues important for the development of the thalamocortical and corticothalamic connections. Indeed, Pdn animals are the first known mutants with defective development of the LGE pioneer neurons, and their study provides a link between early patterning defects and axon pathfinding in the developing telencephalon. 612.8
7	A quantitative analysis of thalamocortical white matter development in benign childhood epilepsy with centro-temporal spikes (BECTS) Thorn, Emily 25 October 2018 (has links) BACKGROUND: A number of epilepsy syndromes are characterized by sleep-activated epileptiform discharges, however drivers of this process are not well understood. Previous research has found that thalamic injury in early life may increase the odds of sleep-activated spikes. Benign childhood epilepsy with centrotemporal spikes (BECTS) is among the most common pediatric-onset epilepsy syndromes, characterized by sleep-potentiated spike activity, a focal sensorimotor seizure semiology, and deficits in language, attention, and behavioral functioning. Though ictal and interictal electro-clinical activity resolves during mid-adolescence, adverse psychosocial outcomes may persist. Previous findings from monozygotic twin and neuroimaging studies suggest a multifactorial pattern of disease and raise suspicion for structural changes in thalamocortical connectivity focal to the seizure onset zone, though this has not been explored. OBJECTIVE: This research aims to (1) assess white matter differences in focal thalamocortical connectivity between BECTS cases and healthy controls using validated probabilistic tractography methods, (2) assess the association between spike burden and white matter connectivity focal to the seizure onset zone, and (3) evaluate longitudinal changes in thalamocortical connectivity across four cases. METHODS: 42 subjects ages 6-15 years were recruited between November 2015 and February 2018, including 23 BECTS cases and 19 healthy controls. Subjects underwent 3 Tesla structural and diffusion-weighted magnetic resonance imaging (2mm x 2mm x 2mm) with 64 gradient directions (b-value=2000) and 72 electrode sleep-deprived electroencephalographic (EEG) recordings. Seed and target regions of interest (ROIs) were created within each hemisphere using the Desikan-Killiany atlas, with the thalamus set as a seed ROI, and SOZ cortex and non-SOZ (NSOZ) cortex as target ROIs. Probabilistic tractography was executed using PROBTRACKX2 with 500 streamlines per seed voxel, 0.5 millimeter steps, and a curvature threshold of 0.2. All streamlines reaching the target ROI were summed and normalized by seed voxel count. Results for BECTS and healthy controls were plotted by age. The slope of thalamocortical connectivity versus age was computed for each group and compared between groups using nonparametric bootstrap analysis. Additionally, the association between SOZ connectivity and spike burden was assessed in a subgroup analysis using a linear regression model, controlling for age. RESULTS: A significant difference in the developmental trajectory of thalamocortical connectivity to the SOZ in BECTS cases compared to healthy controls was found (p=0.014), where the increase in connectivity with age observed in healthy controls was not present in BECTS children. These results did not extend to NSOZ thalamocortical connections (p=0.192). Longitudinal results support these observations, where all BECTS cases who underwent repeat imaging (N=4) showed a decrease in thalamocortical connectivity to the SOZ over the follow-up period. No relationship was found between thalamocortical connectivity and spike burden (p=0.840). CONCLUSIONS: These findings suggest that children with BECTS show subtle alterations in thalamocortical white matter development focal to the seizure onset zone. Thalamocortical connectivity to the SOZ does not appear to directly mediate non-REM sleep spike potentiation in BECTS. Limitations of this study include the potential for selection bias and limited power to detect sample differences. Additional research is needed to further characterize thalamocortical network changes and electrographic and neuropsychological correlates. Neurosciences BECTS EEG Thalamocortical connectivity Diffusion MRI Probabilistic tractography Rolandic epilepsy
8	The development of corticothalamic and corticotectal connections in the murine visual system Grant, Eleanor January 2014 (has links) All peripheral sensory information is represented in the thalamus before being transmitted to the cortex, with the exception of olfaction. The thalamus projects to all areas of the neocortex and all neocortical areas project to the thalamus. I am interested in the development of three corticothalamic populations which are anatomically and functionally distinct; they project to different thalamic nuclei and generate different post-synaptic responses. Layer V fibres project exclusively to higher order thalamic nuclei. These projections drive thalamic neuron activity and mediate a trans-thalamic cortico-cortical relay. Layer VI and VIb fibres project to both first order and higher order thalamic nuclei. These projections modulate thalamic neuron activity and mediate feedback to the thalamus. Using three transgenic mouse lines I demonstrate that developing corticothalamic fibres target the specific groups of thalamic nuclei to which they project in adulthood. Rbp4-Cre::tdTomato labels layer V; Ntsr1-Cre::tdTomato labels layer VI; Golli-τ-eGFP labels layer VI and VIb. By P4 layer V fibres arborise densely in higher order nuclei but do not innervate the first order nuclei at any age. In contrast, at this age VI and VIb fibres densely innervate the first order ventral posterior-medial nucleus (VPM), as well as higher order nuclei. Layer VI and VIb fibres accumulate outside the dorsal Lateral Geniculate Nucleus (dLGN) from P2 before entering at P6. During this waiting period, retinal fibres transmit spontaneous waves of activity to the dLGN. To assess whether retinal input regulates corticothalamic circuit development I performed monocular enucleation. I demonstrate that after loss of retinal input, layer VI and VIb fibres enter the dLGN prematurely, by P2. Furthermore layer V fibres which target the retino-recipient superior colliculus also enter prematurely following enucleation. These results suggest there may be a retinal mechanism which regulates the timing of corticofugal ingrowth to joint retinal/cortical targets. The loss of retinal driver input to the dLGN also induces layer V driver fibres to aberrantly enter the first order dLGN. These results are the first to show cross-hierarchical rewiring after losing peripheral sensory input. The role of peripheral activity in the developing nervous system is underscored by activity dependent molecular mechanisms. I therefore performed a microarray gene expression experiment to systematically analyse molecular changes in the dLGN following enucleation. The expression of numerous genes is altered following enucleation including potassium channels Kcnk9 and Kcnn3, kinase pathway mediators, Shc3 and Dgkk, and immediate early genes BDNF, Egr1 and Egr2. The majority of genes regulated by enucleation are regulated in the opposite direction over development indicating that the loss of the retinal input delays maturation of the dLGN transcriptome. In this thesis I demonstrate that early corticothalamic development targets specific thalamic nuclei. Using the visual system as a model I demonstrate that retinal input regulates corticothalamic development and contributes to the transcriptome of thalamic nuclei. 612.8
9	Thalamocortical Innervation of GABAergic Interneurons in Mouse Primary Vibrissal Somatosensory Cortex Feyerabend, Michael 03 December 2019 (has links) No description available. 570 GABAergic Interneurons thalamocortical circuits ChR2-assisted circuit mapping primary somatosensory cortex Biologie (PPN619462639)
10	Em direcão a um modelo fenomenológico de coluna tálamo-cortical com uma abordagem orientada a objetos Souza, Vitor de January 2017 (has links) Orientador: Prof. Dr. Francisco Javier Ropero Peláez / Dissertação (mestrado) - Universidade Federal do ABC, Programa de Pós-Graduação em Ciência da Computação, 2017. / Esta pesquisa tem como objetivo principal criar um modelo fenomenologico de colunas talamo-corticais, por meio do uso de orientação a objetos. Este modelo sera organizado num arcabouço em que sera possível a criação de diferentes redes neurais artificiais nao supervisionadas que se espelham no comportamento e organização do cerebro biologico. Nesta pesquisa, a rede neural que sera modelada e a do koniocortex (camada IV do cortex cerebral), que contem os distintos tipos de neuronios encontrados no talamo e no cortex. O uso da orientação a objetos juntamente com a organização dos neuronios em estruturas colunares tem o intuito de facilitar a inserção de novos componentes futuramente, como neuronios de outras camadas do cortex cerebral. Para tal, foi construido um neuronio artificial usando orientação a objetos e adicionado caracteristicas biologicas como plasticidade sinaptica e plasticidade intrinseca; e um sistema de estruturas colunares que se assemelha ao constatado em colunas talamo-corticais biologicas (com o talamo servindo de porta de entrada das informações sensoriais). Dos resultados obtidos, observou-se classi ficação de padrões e competição emergindo naturalmente da rede, dada a organização dos neuronios inibitorios e as propriedades homeostaticas modeladas, tendo como exemplo o reconhecimento de caracteres alfanumericos e imagens simples em preto e branco (e.g. uma arvore, um sapato, uma casa etc.). / This research aims to create a phenomenological model of thalamocortical columns, through the use of object-oriented programming. This model is going to be organized in a framework in which it will be possible to create many diferent artifcial non supervised neural networks that resemble behavior and organization of the biological brain. In this research, the neural network that is going to be modeled is the koniocortex (layer IV of the cerebral cortex), which contains the distinct types of neurons found in the thalamus and cortex. This object-oriented approach together with the organization of these objects in columnar structures intends to facilitate the insertion of new components hereafter, as neurons from other layers from the cerebral cortex. To this end, it was built an artificial neuron using object-oriented programming with biological characteristics such as synaptic plasticity and intrinsic plasticity; and a columnar structure system that resembles biological thalamocortical columns (with the thalamus as a gateway for sensorial information). From the results obtained, we observed pattern classification and competition naturally emerging from the network, given the organization of inhibitory neurons and the homeostatic properties modeled, taking as an example the recognition of alphanumeric characters and simple black and white images, such as a tree, a shoe, a house, etc. KONIOCORTEX COLUNA TÁLAMO-CORTICAL PLASTICIDADE SINÁPTICA THALAMOCORTICAL COLUMN SYNAPTIC PLASTICITY

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