Global ETD Search

61	Neuronal development in the rat sensory ganglia Memberg, Stacey Piszczkiewicz January 1995 (has links) No description available. Biology, Neuroscience Ganglia, sensory Neurons, development Rats
62	Selective blockade by gallamine and pancuronium of muscarinic inhibitory activity in cervical sympathetic ganglia as determined by nictitating membrane contractions, surface potential recordings and histofluorescent experiments / Tsevdos, Estelle J. January 1978 (has links) No description available. Health Sciences Sympathetic nervous system Autonomic ganglia
63	Perceptual Organization in Parkinson’s Disease: A Behavioral Investigation of Basal Ganglia Dysfunction Muralidharan, Padmapriya 11 December 2018 (has links) The basal ganglia provide a major neural system through which the cortex affects behavior. Most notable among these effects are those related to the voluntary control of movement as seen in neurodegenerative disorders like Parkinson’s disease (PD). Well known tests of visual perception in PD “explicitly” measure object recognition (a high-level visual process) but “implicitly” rely on intact mid-level visual processes like grouping and figure-ground segmentation to structure the image. Hence, exploring the importance of the basal ganglia in perceptual organization (PO) abilities by examining the specific impairments incurred with the damage of such a vital structure is imperative. Therefore, this study attempted to investigate PD performance in tasks in computerized classic gestalt perception experiments with the aim of identifying any mid-level visuo-perceptual deficits. Differences were observed in the grouping by proximity dot counting task but not in other tasks that involved figure-ground segregation, part detection in embedded contexts or shape discrimination. / M.S. / Damage to the basal ganglia, a group of structures in the subcortical part of the brain (below the cerebral cortex), has long been associated primarily with Parkinson’s Disease (PD), a neurological disorder that manifests with symptoms like muscle rigidity and tremors. While several key visual and perceptual problems have also been connected to this area, very few studies have tried to describe the mechanisms by which PD functionally alters their ability to perceive the visual world. Hence, this study attempted to investigate PD performance in computerized classic perception experiments with the aim of exploring mechanisms that organize incoming visual information to structure the image called perceptual organization (PO). Differences were observed in tasks that tested their ability to group “dots” when they are varied by proximity to each other but not in other tasks that involved their ability to segregate figures from the ground, detect parts of shapes in embedded contexts or discriminate between shapes. Perceptual Organization Parkinson's Disease Basal Ganglia Grouping
64	Kognitivní funkce u pacientů intoxikovaných metanolem / Cognitive sequelae from methanol poisoning Bernášková, Lucie January 2014 (has links) This thesis focuses on cognitive functions in patients after methanol poisoning. The theoretical part consists of a description of methanol, characteristics of methanol poisoning and its neurological sequelae. Methanol poisoning affects the basal ganglia, therefore we describe them and their role in cognitive processes. The theoretical part also describes a case of mass methanol poisoning in the Czech Republic in 2012-2013. The practical part compares results of a control group and a group of patients poisoned with methanol in cognitive assessment. Results show that the patients after methanol poisoning have significantly lower scores in tasks testing memory and executive functions than the control group.
65	Characterization of toll-like receptor 4 in the neurons and glia of the dorsal root ganglion. January 2014 (has links) 背根神經節（DRG）上的初級感覺神經元通常負責感覺從環境中有害的刺激，但新出現的證據表明，它亦負責對危險的感覺。Toll-樣受體-4（TLR4）通常見於小膠質細胞，它是負責識別病原體相關分子模式（PAMPs）或損傷相關分子模式（DAMPs）並誘發炎症。奇怪的是，儘管TLR4在中樞神經系統通常見於神經膠質細胞，在DRG發現的TLR4僅見於初級感覺神經元，但從未見於周邊的衛星膠質細胞（SGC）。而重要的是，在感覺神經節中激活TLR4是會導致神經病理性疼痛的，但我們仍然未知道初級感覺神經元上的TLR4是否導致疼痛的唯一來源。本研究旨在探討在DRG細胞的TLR4信號傳導的分子和細胞機理，並探討在DRG的神經元和膠質細胞上TLR4活動的差異，在生物學上有甚麼意義。 / 為了研究在DRG神經元和膠質細胞的相互作用，我們首先在一個既定的混合DRG細胞培養模型上研究了谷氨酰胺合成酶（ GS ）的表達模式。GS是一種只會在SGC上表達的特異性酶，並於神經元和神經膠質細胞之間的谷氨酰胺 - 谷氨酸循環產生相互作用。在典型的DRG細胞培養，神經元通過擴散因子促進了GS在神經膠質細胞上的表達，然而，GS的表達亦受到TLR4激動劑，即脂多醣（LPS），的抑制。這表明DRG神經元和神經膠質細胞的關係受到TLR4介導的炎症之影響。在混合DRG細胞中，我們對TLR4-免疫反應（IR）進行了鑑定，發現TLR4最主要的是表達在神經元細胞的表面。另外，LPS（ 1微克/毫升，2小時）會刺激混合DRG細胞，通過在DRG細胞中MyD88依賴性信令，誘導環加氧酶-2（COX -2），白細胞介素-1β（ IL-1β）和腫瘤壞死因子-α（TNFα）的轉錄。此外，在DRG細胞， LPS（ 1微克/毫升， 24小時）亦會觸發依賴COX-2 的前列腺素E2（PGE₂）和的前列環素（PGI₂）的產生。但在LPS刺激後，我們發現DRG神經元和神經膠質細胞都對 COX-2-IR呈陽性反應。這證明DRG神經膠質細胞對TLR4誘發的神經炎症也擔任一定的角色。 / 為了純粹研究神經膠質細胞有沒有任何TLR4活性，我們把神經元從混合DRG細胞中除去，從而把神經膠質細胞純化。出乎意料的是，在純化後，大約80的神經膠質細胞對TLR4 -IR呈陽性反應。而且，時間和濃度依賴性的研究表明，純化後的神經膠質細胞對LPS刺激的COX-2表達反應在有效性和效率上比混合DRG細胞的顯著更高。明顯地，神經元對神經膠質細胞的TLR4活性有抑制作用。我們並且發現，神經元的抑制作用是透過由細胞與細胞之間的接觸介導，而不是由擴散因子介導。 / 重要的是， LPS也能誘導純化後的神經膠質細胞去產生依賴COX-2活性的前列腺素E2（PGE₂）。反過來， PGE₂能區別地調節依賴TLR4的炎症基因轉錄，說明在DRG 由TLR4介導的神經炎症是受多重複雜的機理控制。然而有趣的是，從受熱休克性損害的感覺神經元所收集的培養基可以激活純化膠質細胞，並通過對TLR4局部依賴性的方式，誘導COX-2的轉錄。此外，我們利用斑馬魚作為疼痛行為反應的模型，發現COXs的活性與瞬時受體電位通道亞家族V1（ TRPV1）有密切關係。斑馬魚幼蟲的疼痛行為反應是一個適合於篩選新型鎮痛化合物的體內模型。 / 總括來說，透過細胞與細胞之間的接觸和擴散因子，感覺神經元可以控制神經膠質細胞的表型。我們的研究確定感覺神經元是在DRG中表達TLR4的主要細胞類型，但當神經元施加的抑制被削弱，SGC可以成為完全勝任TLR4信息傳遞的細胞。因此我們推測TLR4的活性在DRG中被嚴格調控，以防止不必要的神經炎症發生。至於未來，我們認為在DRG中的TLR4/COX-2/PGE₂信號通路可以成為研究方的新型鎮痛化合物的方向。而轉基因斑馬魚則可用作篩選新型鎮痛化合物的工具。 / Primary sensory neurons of the dorsal root ganglia (DRG) are classically responsible for the detection of physiological stimuli from the environment, but emerging evidences suggests that they are also involved in the sensation of danger. Toll-like receptor 4 (TLR4) is commonly found on microglia for the recognition of pathogen- or damage- associated molecular patterns (PAMPs or DAMPs) and to the activation of TLR4 leads to inflammation. Curiously, while commonly found in glial cells in central nervous system, TLR4 expression was only found in primary sensory neurons but not the satellite glial cells (SGCs) in the DRG. Importantly, activation of TLR4 in sensory ganglia mediates neuropathic pain, but it remains unknown whether neurons are the only source of TLR4 activity. The present study aims to study the cellular and molecular mechanism(s) of TLR4 signalings and explore the biological significance of differential cellular TLR4 activity in the DRG. / To investigate neuron-glia interactions in the DRG, the expression of glutamine synthetase (GS), a SGC-specific enzyme in the glutamine-glutamate shuttle between neuron and glia, was studied in an established model of mixed DRG cells culture. In typical mixed DRG cell cultures, neurons promoted the GS expression in glial cells through diffusible factors. However, GS expression was negatively regulated by theTLR4 agonist, lipopolysaccharide (LPS), indicative of a change in neuron-glia relationships by TLR4 mediated inflammation. In mixed DRG cells, cell surface TLR4-immunoreactivity (-ir) was predominantly identified on the neurons. LPS (1 μg/mL, 2 h) stimulation induced cyclooxygenases-2 (COX-2), interleukin-1β (IL-1β) and tumor necrosis factor-α (TNFα) transcription through MyD88-dependent signalings in DRG cells. Furthermore, LPS (1 μg/mL, 24 h) triggered COX-2-dependent production of prostaglandin E₂ (PGE₂) and prostacyclin (PGI₂) in mixed DRG cells. / To study the TLR4 activity of glial cells, glial cell cultures were purified by removing neurons from mixed DRG cell culture. Unexpectedly, approximately 80% of purified glial cells become TLR4-ir positive. Moreover, a time- and concentration-dependent study showed that the efficacy and efficiency of purified glial cells to express COX-2 in response to LPS was significantly higher than that of mixed DRG cells. We found that neuron inhibited glial cells through cell-cell contact, but not by diffusible factors. Importantly, LPS also induced COX-2 dependent PGE₂ production in purified glial cells. In turn, PGE₂ can differentially modulate TLR4-dependent gene transcription, suggestive of a complex regulation of TLR4-mediated inflammation in the DRG. Intriguingly, conditioned media from heat-shocked damaged sensory neurons activated purified glial cells to induce COX-2-transcription through a partially TLR4-dependent mechanism. Using zebrafish as a model of nocifensive behavior, we found that the activity of COXs was closely associated with the transient receptor potential channel subfamily V1 (TRPV1), and the nocifensive behavior of zebrafish larvae is suitable for in vivo screening of novel analgesic compounds. / To conclude, sensory neurons regulate the phenotypes of DRG glial cells through cell-cell contact and diffusible factors. Here, sensory neurons are confirmed to be the predominant cell type expressing TLR4 in the DRG, but SGCs become fully competent for TLR4 signalings when the neuronal inhibitions are diminished. We therefore hypothesize that TLR4 activity is tightly regulated in the DRG to prevent unwanted neuroinflammation. Future studies with genetically modified zebrafish can be used for the screening of novel analgesic compound targeting the TLR4/COX-2/PGE₂ signaling pathway. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Tse, Kai Hei. / Thesis (Ph.D.) Chinese University of Hong Kong, 2014. / Includes bibliographical references (leaves 190-222). / Abstracts also in Chinese. Spinal ganglia Cell receptors Ganglia, Spinal Toll-Like Receptor 4--chemistry
66	Rôle du striatum dans la physiopathologie des épilepsies focales : un modèle translationnel de l’Homme au primate non-humain / Role of the striatum in the pathophysiology of focal epilepsies : a translational approach from non-human primate to human. Aupy, Jérôme 21 December 2018 (has links) Contexte : […], le mode d'interaction entre les signaux corticaux et striataux reste flou. Dans la présente thèse, nous avons d’abord saisi l’opportunité d’enregistrements stéréoélectroencéphalographiques chez des patients atteints d’épilepsie pharamcorésistante pour analyser qualitativement et quantitativement l’activité ictale du striatum. Deuxièmement, nous avons créé un modèle primate de crises motrices focales sous-corticales induites par des injections striatales antagonistes GABAergiques. Première étude : Patients et méthode : onze patients ayant subi une évaluation SEEG ont été inclus prospectivement s'ils remplissaient deux critères d'inclusion: i) au moins un contact explorait le striatum, ii) au moins deux crises avaient été enregistrées. Les régions d'intérêt corticales et sous-corticales ont été définies et différentes périodes d'intérêt ont été analysées. Les signaux SEEG ont été inspectés visuellement et une analyse de corrélation non linéaire h2 a été réalisée pour étudier la connectivité fonctionnelle entre les régions corticales d’intérêt et le striatum. Résultats : Deux patterns principaux d'activation striatale ont été enregistrés : le plus fréquent était caractérisé par une activité alpha / bêta précoce débutant dans les cinq premières secondes suivant le début de la crise. Le second était caractérisé par une activité thêta / delta tardive plus lente. Une différence significative des indices de corrélation h2 a été observée au cours de la période préictale et début de crise par rapport au tracé de fond pour l'indice striatal global, l'indice mésio-temporal / striatal, l'index latérotemporal / striatal, l'index insulaire / striatal, l'index préfrontal / striatal. En outre, une différence significative des indices de corrélation h2 a été observée pendant la période de fin de crise par rapport à toutes les autres périodes d’intérêt. Deuxième étude : Matériel et méthode : Des injections antagonistes aiguës de GABAergic (bicuculline) ont été réalisées sur trois Macaca fascicularis dans la partie sensorimotrice du striatum. Les modifications comportementales ont été enregistrées et scorées selon une échelle de Racine modifiée. L'électromyographie, l'électroencéphalographie, les potentiels de champ locaux des noyaux gris centraux ont été enregistrés au cours de chaque expérience. Une analyse de retromoyenage a été effectuée pour chaque session enregistrée. Résultats: sur les 39 injections de bicuculline, 29 (74,3%) ont produit des changements comportementaux reproductibles caractérisés par des secousses myocloniques répétitives et pseudopériodiques avec des crises tonico-cloniques généralisées. Les injections de NaCl n'ont jamais entraîné de changement de comportement. Les secousses myocloniques étaient clairement détectables sur le signal EMG sous la forme d'une courte bouffée stéréotypée concomitante de pointes épileptiques anormales enregistrées sur l'EEG. Une analyse de rétromoyennage à partir des myoclonies EMG a montré que l'activité électrophysiologique commençait significativement plus tôt dans le striatum (p <0,0001), le GPe (p <0,0003) et le GPi (p <0,0086) que dans le cortex. Conclusion : Ces modifications du niveau de synchronisation entre les activités corticales et striatales pourraient s’inscrire dans un mécanisme endogène contrôlant la durée des oscillations anormales au sein de la boucle striato-thalamo-corticale et, de fait leur terminaison. Les interneurones GABAergic de type fast-spiking pourraient jouer un rôle crucial dans la synchronisation du réseau cortico-striato-thalamique et une modification GABAergique brutale du striatum peut provoquer une crise focale. Le rôle joué par les noyaux gris centraux dans le renforcement des mécanismes sous-jacents à la cessation de la propagation ictale devrait inspirer de nouveaux schémas de stimulation cérébrale profonde chez les patients atteints d'épilepsies focales pharmacorésistantes non chirurgicales. / Background: Although a number of experimental and clinical studies have pointed out participation or an even more prominent role of basal ganglia in focal seizures, the mode of interaction between cortical and striatal signals remains unclear. In the present thesis, we first we took the opportunity of stereoelectroencephalographic recordings in drug-resistant epilepsy patients, to qualitatively and quantitatively analyse the ictal striatum activity. Secondly, we created a primate model of subcortical focal motor seizures induced by GABAergic antagonist striatal injections First study: Patients and method: eleven patients who underwent SEEG evaluation were prospectively included if they fulfilled two inclusion criteria: i) at least one orthogonal intracerebral electrode contact explored the basal ganglia, in their either putaminal or caudate part, ii) at least two SEEG seizures were recorded. Cortical and subcortical regions of interest were defined and different periods of interest were analysed. SEEG was visually inspected and h2 non-linear correlation analysis performed to study functional connectivity between cortical region of interest and striatum. Results: Two main patterns of striatal activation were recorded: the most frequent was characterised by an early alpha/beta activity that started within the first five second after seizure onset. The second one was characterised by a late slower, theta/delta activity. A significant difference in h2 correlation indexes was observed during the preictal and seizure onset period compared to background for global striatal index, mesio-temporal/striatal index, latero-temporal/striatal index, insular/striatal index, prefrontal/striatal index. In addition, a significant difference in h2 correlation indexes was observed during the seizure termination period compared to all the other periods of interest. Second study: Material and method: Experiments were performed on three fascicularis monkeys. Acute GABAergic antagonist (bicuculine) injections were performed within the sensorimotor part of the striatum. Behavioural modifications were recorded and scored according to a modified Racine’s scale. Electromyography, electroencephalography, basal ganglia local field potentials were recorded during each experiment. A backaveraging analysis was performed for each recorded session. Results: over the 39 Bicuculline injections, 29 (74.3%) produced dramatic reproducible behavioural changes characterised by repetitive and pseudo-periodic myoclonic jerks with generalised tonic-clonic seizures. NaCl injections never produced any behavioural changes. Myoclonic jerks were clearly detectable on the EMG signal as short stereotypical EMG burst concomitant from abnormal epileptic spikes recorded on EEG. Back averaging analysis from EMG myoclonia showed that electrophysiological activity started significantly earlier in the striatum (p < 0.0001), the GPe (p < 0.0003) and the GPi (p < 0.0086) than in the cortex. Conclusion: These changes in synchronisation level between cortical and striatal activity might be part of an endogenous mechanism controlling the duration of abnormal oscillations within the striato-thalamo-cortical loop and thereby their termination. GABAergic fast-spiking interneurones might play a crucial role synchronising the cortico-striato-thalamic network and a drastic GABAergic modification of the striatum can induce focal seizures. The role of the basal ganglia role in strengthening mechanisms underlying cessation of ictal propagation should inspire new rationales for deep brain stimulation in patients with intractable focal epilepsy. Epilepsie Basal ganglia Striatum Synchronisation Connectivité Réseaux Epilepsy Basal ganglia Striatum Connectivity Synchronization Networks
67	Modulation of T-type Ca²⁺ channels in nociceptive neurons by reducing agents : cellular and molecular mechanisms / Nelson, Michael Todd. January 2007 (has links) Thesis (Ph. D.)--University of Virginia, 2007. / Includes bibliographical references. Also available online through Digital Dissertations.
68	Cocaine- and Amphetamine-Regulated Transcript-Immunoreactivity in the Rat Sympatho-Adrenal Axis Dun, N. J., Dun, S. L., Kwok, E. H., Yang, J., Chang, J. K. 07 April 2000 (has links) Distribution of cocaine- and amphetamine-regulated transcript-like immunoreactivity (CART-LI) was studied in the rat spinal cord, sympathetic ganglia and adrenal glands by immunohistochemical methods, utilizing a polyclonal antiserum raised against the CART peptide fragment 55-102. CART-LI was detected in nerve fibers and in basket-like terminals surrounding many postganglionic neurons of the superior cervical ganglion (SCG), stellate, paravertebral and prevertebral ganglia. Postganglionic neurons exhibited low or non-detectable levels of CART-LI. Surgical sectioning of the cervical sympathetic trunk for 6-7 days resulted in a nearly complete loss of CART-LI fibers and terminals in the SCG. In the adrenal gland, CART-LI nerve fibers formed a plexus underneath the capsule, some of which bifurcated and made a sharp turn toward the adrenal medulla, where clusters of chromaffin cells were intensely labeled. The detection of CART-LI in sympathetic ganglia and adrenal glands extends the previous observation of the presence of CART-LI in sympathetic preganglionic neurons and further supports the notion that CART peptide(s) may function as a signaling molecule in the sympatho-adrenal axis. chromaffin cells paravertebral ganglia prevertebral ganglia superior cervical ganglion
69	Linking actions to outcomes : the role of the posterior pedunculopontine tegmental nucleus in instrumental learning MacLaren, Duncan A. A. January 2012 (has links) Located in the mesopontine tegmentum, the pedunculopontine tegmental nucleus (PPTg) is comprised principally of glutamatergic, cholinergic and GABAergic neurons. In addition to being fully integrated into basal ganglia, PPTg projects to thalamus and motor output sites in the brainstem. Previous studies have shown a range of behavioural changes after PPTg manipulation. Prominent amongst these is an apparent deficit in the ability to learn the consequences of actions. PPTg is divisible into a posterior component (pPPTg) in receipt of rapid polymodal sensory input and projecting into VTA/SNc dopamine neurons and an anterior component (aPPTg) in receipt of basal ganglia outflow and projecting into SNc and lower brainstem structures. The research described here assesses the role of the pPPTg in instrumental learning. Using a contingency degradation paradigm, it was shown that inactivation of the pPPTg (by muscimol microinfusion) specifically blocked the updating of associations between actions and outcomes, without the affecting the ability to re-execute previously learned instrumental actions. Selective bilateral destruction of pPPTg cholinergic neurons (with the fusion toxin diphtheria toxin – urotensin II [Dtx-UII]) resulted in >90% loss of pPPTg cholinergic neurons. These lesions produced no detectable changes on any measured aspect of an instrumental learning task consisting of various fixed and variable ratio schedules of reinforcement and extinction. Subsequent experiments found that the same selective cholinergic pPPTg lesions also produced no changes in the locomotor response to nicotine or rate of nicotine sensitisation. These results are the first to demonstrate a brainstem role in action-outcome learning. Results support the view that PPTg performs a ‘first pass' analysis on incoming sensory data and interfaces salient aspects of this with appropriate basal ganglia and brainstem circuitry, with glutamatergic pPPTg projections sending an essential signal and cholinergic projections performing as part of a wider modulatory system. 612.8
70	THE EFFECTS OF ADRENOCEPTOR AGONISTS ON SLOW AND FAST SYNAPTIC TRANSMISSION IN THE INFERIOR MESENTERIC GANGLION (IMG) OF THE GUINEA PIG. Dryer, Stuart Evan. January 1982 (has links) No description available. Sympatholytic agents. Adrenaline -- Receptors. Autonomic ganglia. Neural transmission.

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