Global ETD Search

141	Efeitos do envelhecimento sobre o sistema nitrérgico dos núcleos da base em humanos / Effects of aging over nitrergic system in human basal nuclei Santos, Bruno Lopes dos 22 April 2014 (has links) O óxido nítrico (NO) é uma molécula gasosa descrita recentemente, com implicações sobre uma vasta quantidade de processos fisiológicos, incluindo transmissão de sinais no sistema nervoso central (SNC). A sinalização nervosa mediada pelo NO ocorre por meios extrassinápticos, na chamada neurotransmissão por volume. Há evidências de que o NO seja um importante fator de modulação no controle da motricidade. A presença de neurônios que produzem NO já foi descrita em várias espécies, e estruturas ligadas ao controle do movimento como os núcleos da base (NNBB) contêm células nitrérgicas em quantidades variadas. Não se conhece os efeitos do processo de envelhecimento sobre a estrutura e função destes neurônios produtores de NO. O objetivo geral deste estudo foi investigar se o envelhecimento provoca alterações nos neurônios nitrérgicos presentes nos NNBB do encéfalo humano. Além disso, busca agregar mais conhecimento a aspectos morfológicos e de distribuição das células que compõem o sistema nitrérgico nos NNBB em humanos. As amostras de estriado (caudado e putâmen), globos pálidos (GP), núcleo subtalâmico (NST), substância negra (SN) e núcleo pedunculopontino (NPP) de 20 indivíduos sem doenças neurológicas e psiquiátricas foram submetidas à avaliação histológica em secções, coradas por técnicas que localizam neurônios que expressam NO, como a histoquímica para NADPH-diaforase (NADPHd) e à imunohistoquímica para sintase do NO neuronal (nNOS), e parâmetros de densidade neuronal e morfometria foram comparados entre indivíduos adultos jovens e idosos. Análises de densidade neuronal e morfometria entre subdivisões topográficas e funcionais também foram realizadas. Foi visto que o envelhecimento não provoca modificações na densidade neuronal e morfometria nitrérgica nos NNBB em humanos. Adicionalmente, o trabalho mostrou que: (I) as regiões mais posteriores do estriado se destacaram por apresentarem uma elevada densidade neuronal, associada a neurônios menores, em comparação com as regiões mais anteriores; (II) as porções do estriado ligadas ao córtex límbico apresentam maiores densidades neuronais; (III) o NST é uma região em que cerca de 90% de seus neurônios expressam NO, e suas características morfológicas sugerem que estas células coexpressem glutamato; (IV) o NPP é extensamente povoado por neurônios nitrérgicos, principalmente no nível do colículo inferior; (V) a presença de células NO-positivas é preponderante nas lâminas medulares de ambos GP, porém notamos maior concentração de células nitrérgicas no GPi; (VI) não foi detectada presença de neurônios quem contém NO na SN. Nossos resultados mostram que há uma presença maciça de neurônios que expressam NO em núcleos-chaves envolvidos com processamento motor corticobasal, como o NST, o estriado e o NPP, sugerindo que a neurotransmissão nitrérgica seja peça fundamental da fisiologia dos NNBB, portanto, com considerável potencial terapêutico nas doenças que afetam estas estruturas. / The nitric oxide (NO) is a gaseous molecule recently described, with a role on several physiologic processes, including signal transmission in central nervous system (CNS). The NO-mediated brain signaling occurs by extrasynaptic mode, called volume transmission. There are evidences supporting the NO as a major neurotransmitter involved on motor control modulation. The presence of NO neurons was described in many species, and movement-related structures, as the basal nuclei (BN), also contains variable densities of nitrergic cells. It is unknown the effect of aging over the structure and function of these NO neurons. The objective of the study is to investigate if the aging causes abnormalities on human BN nitrergic neurons. Furthermore, we aimed to explore distribution and morphologic features of these cells in BN. The samples of striatum (caudate and putamen), globus pallidum (GP), subthalamic nucleus (STN), substantia nigra (SN) and pedunculopontine nucleus (PPN) of 20 human brains from subjects without neurologic or psychiatric disases were processed for histologic analysis, stained by 2 techniques which localizes NO neurons: histochemistry for NADPH-diaphorase (NADPHd) and immunohistochemistry for neuronal NO synthase (nNOS); the neuronal density and morphometric parameters were compared between young adults and aged subjects. The neuronal density and morphometric analysis between striatal and subthalamic topographic / functional subdivisions were also performed. Our data showed that aging does not change the neuronal density or morphometric parameters of nitrergic neurons in human BN. Additionally, other results were found: (I) the most posterior regions of striatum have a higher neuronal density and smaller neurons than the most anterior regions of this nucleus; (II) the limbic cortex-associated areas of striatum have higher neuronal density than others functional subdivisions; (III) the STN is a region in which about 90% of its neurons expresses NO, and its morphologic features suggest these neurons coexpress glutamate; (IV) the PPN has a massive nitrergic neuronal density, mostly in the inferior colliculus level; (V) in GP, there is a marked presence of NO neurons in laminae medullaris, and the internal GP has more NO-positive cells than the external GP; (VI) nitrergic neurons were not detected in SN. Our results showed a remarkable presence of neurons expressing NO in nuclei essential for motor corticobasal processing (striatum, STN, PPN), suggesting that the nitrergic neurotransmission has a fundamental role in BN physiology, therefore, with great therapeutic potential in diseases involving these structures. Aging Basal nuclei Envelhecimento Estriado Nitric oxide Núcleo subtalâmico Núcleos da base Óxido nítrico Striatum Subthalamic nucleus
142	A Study of Striatal Markers as Disease Modifiers in Huntington's Disease / Etude de marqueurs du striatum comme modificateurs d’atteinte pathologique dans la maladie de Huntington Francelle, Laetitia 26 November 2014 (has links) La maladie de Huntington (MH) est une affection neurodégénérative héréditaire dont la mutation conduit à une expansion anormale d’un segment polyglutamine dans la protéine Huntingtine (Htt). La Htt mutée, bien qu’ubiquitaire dans le cerveau, conduit à une neurodégénérescence préférentielle du striatum. Cette atteinte pourrait en partie s’expliquer par la présence de produits de gènes sélectivement exprimés dans le striatum. Le laboratoire étudie depuis plusieurs années l’implication potentielle de marqueurs moléculaires du striatum dans la vulnérabilité des neurones de cette structure cérébrale vis-à-vis de la Htt mutée. Durant ma thèse, j’ai étudié plus spécifiquement trois de ces marqueurs du striatum: l’ARN long intergénique non-codant Abhd11os et les protéines µ-crystalline (CRYM) et doublecortin-like kinase 3 (DCLK3). Une étude préliminaire avait montré l’effet neuroprotecteur de ces marqueurs du striatum contre la toxicité induite par un fragment court de la Htt mutée dans un modèle murin aigu de la MH. J’ai donc étudié plus en détails les caractéristiques de ces "modificateurs" de la MH, ainsi que les mécanismes moléculaires potentiels permettant d’expliquer leur effet neuroprotecteur dans un contexte de la MH. J’ai également mené une expérience de thérapie génique en surexprimant le marqueur striatal DCLK3 dans un modèle transgénique de la MH. Cette étude nous a permis de valider le haut potentiel thérapeutique de cette protéine.L’élucidation précise des mécanismes d’action de ces modificateurs de la MH reste encore à résoudre, mais plusieurs pistes sont maintenant possiblement envisagées par rapport à leurs caractéristiques moléculaires. Outre la découverte de candidats neuroprotecteurs qui pourrait permettre de développer de nouvelles cibles thérapeutiques, cette étude a permis d’envisager de nouvelles hypothèses permettant d’expliquer la vulnérabilité striatale dans la MH et de donner une vue d’ensemble des voies sur lesquelles il serait possible d’agir pour induire des effets neuroprotecteurs dans ce contexte. / Huntington’s disease (HD) is a neurodegenerative disorder caused by the mutation of huntingtin (Htt) gene, which leads to an abnormal polyglutamine expansion in the Htt protein.Whereas mutant Htt (mHtt) is ubiquitously expressed in the brain, it preferentially affects the striatum. Our hypothesis is that genes products selectively expressed in the striatum could be involved in the high vulnerability of the striatum. From this hypothesis, numerous teams studied “markers of the striatum”, that are genes product enriched in the striatum whose expression are up- or down-regulated in HD compared to healthy condition.During my thesis, I studied three of these striatal markers: the long intergenic non-coding RNA Abhd11os, and the two proteins µ-crystallin (CRYM) and doublecortin-like kinase 3 (DCLK3). A preliminary study from the laboratory has shown that these three markers have neuroprotective effects against a toxic fragment of mHtt in vivo. So, the aims of my thesis were to further characterize these three ill-defined disease modifiers and to better understand the putative molecular mechanisms underlying their neuroprotective effects against mHtt.I also conducted a translational study on DCLK3, whose results validate the high therapeutic potential of this protein.The elucidation of the mechanisms underlying the neuroprotective effects of these disease modifiers against mHtt toxicity will require further studies, but new trails can be envisioned, according to their characteristics. My study has enlightened new therapeutic targets and more globally gives an overview of molecular mechanisms to modulate to induce neuroprotective effects in this context, leading to new hypothesis explaining striatal vulnerability in HD. Maladie de Huntington Marqueurs du striatum Neuroprotection Huntington’s disease Striatal markers Neuroprotection Disease modifiers
143	Adolescent Development of Multiple Learning Systems Davidow, Juliet Y. January 2014 (has links) Adolescence is a time filled with opportunities for making choices that have not been encountered before. How do adolescents learn to make these decisions? Maturation of learning processes coupled with dynamic changes in brain systems for learning must be studied in order to determine the mechanisms that underlie adolescent decision making. Research in adults has found contributions from multiple learning systems for decision making. One such system learns incrementally from feedback and reinforcement, and depends in part on the striatum. Another system, in the hippocampus, encodes episodes and allows for flexible use of learned information when required by novel contexts. Recent research in adults explores how these systems can cooperate and compete to facilitate decision making. Ongoing research into learning and decision making processes over the course of adolescence has also implicated the striatum in learning and decision making, but how the hippocampus and striatum interact for decision making remains unknown. In this dissertation I investigate contributions of multiple learning systems for learning and decision making in adolescence. I leverage what is known about underlying brain systems for learning and decision making in adults, and consider how changes in these same systems over adolescence might contribute to behavioral shifts in adolescence. Specifically, in the studies included here, I show how developmental trajectories for learning can enhance performance in adolescents for some types of learning and not others. In the first study I ask how do the striatal and hippocampal systems contribute to feedback based learning in adolescence? I show that in adolescents, both the hippocampus and the striatum contribute to probabilistic feedback learning, and that this type of learning is better in adolescents than in adults. This response to feedback in the hippocampus was found to relate to memory accuracy for features of feedback events only in adolescents. Pushing the finding of hippocampal activation in adolescents, in the second study I ask how does learned value influence flexible decision making in adolescence? Adolescents did not show reliable transfer of value, but there were individual differences in this tendency. Thus, in the third study, I ask which brain regions account for individual differences in learning and value transfer? I show that variability in connectivity at rest between the hippocampus and the vmPFC related to the tendency to transfer value in adults. Taken together, these results contribute to a growing body of research in adolescent decision making, and extend upon our understanding of the mechanisms for learning and decision making systems, and how they change over development. Learning, Psychology of Decision making Hippocampus (Brain) Corpus striatum Adolescent psychology Psychology Cognitive psychology Developmental psychology
144	Rôle de Narp dans le développement des dyskinésies induites par la L-DOPA / Role of Narp in L-DOPA-induced dyskinesia Malerbi, Marion 30 January 2015 (has links) Le traitement substitutif par la L-DOPA, indiqué dans la maladie de Parkinson, induit à terme des complications motrices appelées les dyskinésies induites par la L-DOPA. L'apparition des dyskinésies est due, au moins en partie, à la mise en place d'une plasticité aberrante dans le striatum, qui fait suite à des modifications transcriptionnelles induites par la L-DOPA. Une analyse du transcriptome nous a permis d'identifier le gène Nptx2, codant pour la neuropentraxine Narp, comme étant un candidat potentiellement impliqué dans l'apparition des dyskinésies. L'objectif de ce travail était d'étudier la régulation et le rôle de Narp dans l'apparition des dyskinésies, dans un modèle de souris lésée à la 6-hydroxydopamine. Nous avons montré que les dyskinésies induites par la L-DOPA sont diminuées chez des souris invalidées pour Nptx2 (Narp-KO). Par ailleurs, l'injection dans le striatum dorsal d'un adénovirus exprimant une forme dominante négative de Narp, induit une réduction importante des scores de dyskinésies. Dans le striatum, Narp est exprimé par les neurones épineux de taille moyenne et par les interneurones à parvalbumine. Après une stimulation dopaminergique, l'augmentation de l'expression de Nptx2 s'accompagne d'un enrichissement de Narp au niveau synaptique. Nos travaux montrent donc que Narp joue un rôle important dans le développement des dyskinésies et suggèrent qu'il pourrait être impliqué dans la plasticité synaptique des neurones du striatum, comme cela a été montré dans l'hippocampe. Ces résultats permettent d'ouvrir de nouvelles perspectives thérapeutiques pour retarder l'apparition de ces complications motrices chez les patients parkinsoniens. / Dopaminergic replacement therapy in Parkinson’s disease is hampered by the occurrence of L-DOPA-induced dyskinesia (LID). One major hypothesis is that LID result from L-DOPA-induced aberrant plasticity in the striatum due to modifications of the transcriptional program. Using a microarray-based approach, we identified Narp as a putative candidate implicated in LID induction. Thus, we investigated Narp involvement in LID by examining abnormal involuntary movements (AIM) development in Narp genetically-ablated mice or upon intrastriatal injection of a dominant negative form of Narp. Interestingly, the total AIM score was greatly reduced in these two models of impaired Narp expression. Hence, my results highlight Narp as an important actor in LID development. Then, I further examined Narp regulatory mechanisms in the striatum and I demonstrated that dopamine stimulation leads to increased Narp expression both at the transcriptional level and at the protein level through its accumulation within the synaptic compartment. These findings advance knowledge about mechanisms underlying dyskinesia with the hope of delaying their appearance in patients. Narp Dyskinésies Striatum Parkinson L-Dopa 6-Ohda Dyskinesia Parkinson 616.8
145	Collective dynamics of basal ganglia-thalamo-cortical loops and their roles in functions and dysfunctions / Interactions entre les boucles de rétroaction et inhibition feedforward striatale dans la dynamique normale et pathologique du réseau basalo-thalamo-corticale Arakaki, Takafumi 21 March 2016 (has links) Les ganglions de la base (GB) sont principalement connus pour leurs fonctions motrices, mais présentent également des fonctions non motrices. Sans surprise, il a été montré qu’ils sont impliqués dans des troubles moteurs tels que la maladie de Parkinson ou les dystonies. Des études récentes suggèrent que les GB jouent également un rôle prépondérant dans des maladies “non-motrices” telles que l’épilepsie d’absence , qui est une épilepsie généralisée non convulsive. Dans l’ensemble de ces dysfonctions des GB, les symptômes sont accompagnés de différents patrons oscillants d’activité neuronale souvent synchronisés entre les différents noyaux des GB, le cortex et d’autres aires cérébrales. Comment les GB peuvent-ils favoriser ou soutenir ces différentes activitées oscillantes?Des expériences récentes ont montré le rôle clé joué par les GB dans l’épilepsie d’absence et remettent en question le point de vue traditionnel selon lequel les circuits thalamo-corticaux sont responsables des crises d’absence. Nous proposons une nouvelle théorie selon laquelle les rétroactions opérées par les GB sur l’activité corticale rend le réseau bistable et entraîne les patrons d’activité oscillante qui apparaîssent pendant les crises. Notre théorie est compatible avec l’ensemble des résultats expérimentaux connus et elle prédit qu’un input excitateur transitoire sur le cortex peut terminer prématurément les crises d’absence. Nous présentons ici des résultats préliminaires en accord avec cette prédiction.De multiples fréquences des oscillations d’activité sont observées dans la maladie de Parkinson au sein des GB, telles que les fréquences correspondant aux tremblement des membres ou encore les oscillations béta. Nous montrons que notre model peut générer des oscillations à différentes échelles temporelles qui coïncident avec les fréquences des oscillations dans la maladie de Parkinson. Notre théorie peut rendre compte des oscillations observées dans la maladie de Parkinson et dans l’epilépsie d’absence dans un cadre théorique unifié et suggère deux scénarios pour expliquer les multiples fréquences des oscillations d’activité, à la fois pathologiques et fonctionnelles. / The Basal Ganglia (BG) are thought to be involved primarily in motor but also in non-motor functions. Unsurprisingly, the BG are shown to be involved in motor dysfunctions such as Parkinson's disease or dystonia. More recent studies suggest the key role of the BG in "non-motor" diseases such as absence epilepsy which is a generalized non-convulsive epilepsy. In these diseases, symptoms accompany various oscillatory patterns of neural activity often synchronized across the BG, cortex and other brain areas. How can the BG support these different kinds of oscillatory patterns?Recent experiments have highlighted the key role of the BG in absence seizures and question the traditional view in which thalamocortical circuits underlie absence seizures. We propose a novel theory according to which the feedbacks of cortical activity through BG make this network bistable and drive the oscillatory patterns of activity occurring during the seizures. Our theory is compatible with virtually all known experimental results and it predicts that well-timed transient excitatory inputs to the cortex advance the termination of absence seizures. We report preliminary experimental results consistent with this prediction.Multiple oscillatory frequencies are observed in Parkinsonian BG such as the frequencies of the limb tremor and the beta oscillations. We show that our model can generate oscillations with multiple timescales which resemble Parkinsonian oscillations. Our theory can model the oscillations in Parkinson's disease and absence epilepsy in a unified framework and points to two scenarios to explain multiple frequencies of pathological and functional oscillations. Striatum Petit mal Maladie de Parkinson Oscillation Neurosciences des systèmes Système dynamique Absence seizures Parkinson's disease Oscillations 616.8
146	Altered function of ventral striatum during reward-based decision making in old age Mell, Thomas, Wartenburger, Isabell, Marschner, Alexander, Villringer, Arno, Reischies, Friedel M., Heekeren, Hauke R. January 2009 (has links) Normal aging is associated with a decline in different cognitive domains and local structural atrophy as well as decreases in dopamine concentration and receptor density. To date, it is largely unknown how these reductions in dopaminergic neurotransmission affect human brain regions responsible for reward-based decision making in older adults. Using a learning criterion in a probabilistic object reversal task, we found a learning stage by age interaction in the dorsolateral prefrontal cortex (dIPFC) during decision making. While young adults recruited the dlPFC in an early stage of learning reward associations, older adults recruited the dlPFC when reward associations had already been learned. Furthermore, we found a reduced change in ventral striatal BOLD signal in older as compared to younger adults in response to high probability rewards. Our data are in line with behavioral evidence that older adults show altered stimulus-reward learning and support the view of an altered fronto-striatal interaction during reward-based decision making in old age, which contributes to prolonged learning of reward associations. aging fMRI reward association learning ventral striatum decision making dorsolateral prefrontal cortex Language, Linguistics
147	Computer Modelling of Neuronal Interactions in the Striatum Hjorth, Johannes January 2009 (has links) Large parts of the cortex and the thalamus project into the striatum,which serves as the input stage of the basal ganglia. Information isintegrated in the striatal neural network and then passed on, via themedium spiny (MS) projection neurons, to the output stages of thebasal ganglia. In addition to the MS neurons there are also severaltypes of interneurons in the striatum, such as the fast spiking (FS)interneurons. I focused my research on the FS neurons, which formstrong inhibitory synapses onto the MS neurons. These striatal FSneurons are sparsely connected by electrical synapses (gap junctions),which are commonly presumed to synchronise their activity.Computational modelling with the GENESIS simulator was used toinvestigate the effect of gap junctions on a network of synapticallydriven striatal FS neurons. The simulations predicted a reduction infiring frequency dependent on the correlation between synaptic inputsto the neighbouring neurons, but only a slight synchronisation. Thegap junction effects on modelled FS neurons showing sub-thresholdoscillations and stuttering behaviour confirm these results andfurther indicate that hyperpolarising inputs might regulate the onsetof stuttering.The interactions between MS and FS neurons were investigated byincluding a computer model of the MS neuron. The hypothesis was thatdistal GABAergic input would lower the amplitude of back propagatingaction potentials, thereby reducing the calcium influx in thedendrites. The model verified this and further predicted that proximalGABAergic input controls spike timing, but not the amplitude ofdendritic calcium influx after initiation.Connecting models of neurons written in different simulators intonetworks raised technical problems which were resolved by integratingthe simulators within the MUSIC framework. This thesis discusses theissues encountered by using this implementation and gives instructionsfor modifying MOOSE scripts to use MUSIC and provides guidelines forachieving compatibility between MUSIC and other simulators.This work sheds light on the interactions between striatal FS and MSneurons. The quantitative results presented could be used to developa large scale striatal network model in the future, which would beapplicable to both the healthy and pathological striatum. / QC 20100720 striatum fast spiking interneurons medium spiny projection neurons gap junctions interoperability MUSIC Computer science Datavetenskap
148	Histone post-translational modifications in the nuclei of striatal D1 and D2 neurons : development of a novel method of study and effects of cocaine Jordi, Emmanuelle 21 September 2012 (has links) (PDF) L'exposition répétée à la cocaine induit une plasticité cérébrale responsable de changements comportementaux de longue durée, dont les mécanismes de signalisation intracellulaire sont mal connus. Les neurones du striatum exprimant le recepteur à la dopamine D1 et ceux exprimant le recepteur à la dopamine D2 jouent un rôle important dans l'intégration de ces signaux. L'activation de ces récepteurs induit des cascades de signalisations opposées, il est donc primordial de pouvoir les étudier séparément. Afin d'analyser spécifiquement ces familles de neurones, nous avons adapté une méthode de tri et d'analyse des noyaux des neurones basée sur la cytométrie en flux. Notre étude a permis de quantifier les changements post-traductionels des histones, ainsi que les enzymes les controlant, specificiquement dans les noyaux des neurones D1 ou D2, suite à un traitement aigu ou chronique de cocaine. Avec cette approche, nous avons trouvé que les neurones D1 et D2 comportent des profils épigénétiques spécifiques, dynamiquement régulés par la cocaine. Plus particulièrement, nous avons trouvé que l'acétylation des histones H3K14, H4K5, H4K12 et la méthylation de H3K9 étaient régulées de manière opposée entre les deux types cellulaires, sous-tendant la disparité de leur réponse transcriptionelle à la drogue. Enfin, nous avons observé qu'il y avait une corrélation complexe entre les modifications post-traductionelles d'histones, spécifiques des neurones D1 ou D2, et qui est sensiblement altérée par la cocaine. Nous proposons une approche originale dans le domaine des neurosciences permettant l'étude des protéines nucléaires applicable potentiellement à tous les types neuronaux du cerveau epigénétique histones striatum cocaine neurones épineux de taille moyenne cytométrie en flux
149	Information processing in the Striatum : a computational study Hjorth, Johannes January 2006 (has links) <p>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.</p><p>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.</p><p>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.</p><p>We have also performed initial stochastic simulations of the Ca<sup>2+</sup>-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.</p> striatum fast spiking interneuron gap junctions synchronisation up-state detection CaMKII mathematical modelling Neuroscience Neurovetenskap
150	Inhibitory synpatic transmission in striatal neurons after transient cerebral ischemia Li, Yan. January 2009 (has links) Thesis (Ph.D.)--Indiana University, 2009. / Title from screen (viewed on December 1, 2009). Department of Anatomy and Cell Biology, Indiana University-Purdue University Indianapolis (IUPUI). Advisor(s): Zao C. Xu, Feng C. Zhou, Charles R. Yang, Theodore R. Cummins. Includes vitae. Includes bibliographical references (leaves 115-135).

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