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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
81

Microglial alterations in valproic acid models of autism

Awale, Prabha Sumant 23 July 2012 (has links)
No description available.
82

Intracortical Brain-Computer Interfaces: Modeling the Feedback Control Loop, Improving Decoder Performance, and Restoring Upper Limb Function with Muscle Stimulation

Willett, Francis R. 06 June 2017 (has links)
No description available.
83

Investigating the Effects of Glucose and Sweet Taste on Corticospinal and Intracortical Excitability

Toepp, Stephen 08 1900 (has links)
Transcranial magnetic stimulation (TMS) is commonly used to measure corticospinal and intracortical excitability in basic and clinical neuroscience. However, the effect of glucose on TMS-based measures is not well defined, despite a potentially impactful influence on precision and reliability. Here, a double-blinded placebo-controlled study was used to test the effects of glucose on two commonly used TMS measures: short-interval intracortical inhibition (SICI), and the area under the motor evoked potential recruitment curves (AURC). SICI and AURC are thought to reflect inhibitory (GABAergic) and excitatory (glutamatergic) neurotransmission respectively. Healthy males (N=18) each participated in four sessions. Session 1 involved TMS familiarization and acquisition of an individualized blood glucose response curve. During sessions 2, 3 and 4, dependent measures were taken before (T0) and twice after (T1 & T2) drinking 300 mL of solution containing glucose (75 g), sucralose-sweetened placebo (control for sweetness) or plain water (control for time). The T1 and T2 measurements were started 5 minutes prior to the blood glucose peak observed during Session 1. Blood glucose and mean arterial pressure (MAP) were also monitored. Sucralose, but not water or glucose increased AURC and none of the treatments altered SICI. There was no association between blood glucose level and TMS measures, but in all three conditions MAP rose after consumption of the drink. There was a positive correlation between the rise in blood pressure and the relative increase in AURC at the higher stimulus intensities. Eleven participants returned for a fifth session to quantify the smallest detectible change in the AURC measurements and it was confirmed that significant changes were real while non-significant differences in measurement means fell within the range of expected measurement error. This study also suggests a relationship between corticospinal excitability and autonomic tone. Additional investigation is required to understand the mediating factors of this association. / Thesis / Master of Science (MSc)
84

Effets électrophysiologiques de la stimulation du cortex moteur sur les noyaux somatosensorielslatéraux du thalamus : étude expérimentale sur un modèle de stimulation du cortex moteur chez le chat / Electrophysiological effects of Motor Cortex stimulation on the ventro-postero-lateral nucleus of the somatosensory thalamus : an experimental study on a cat model of motor cortex stimulation

Kobaïter Maarawi, Sandra 02 July 2013 (has links)
La stimulation du cortex moteur (SCM) est une technique neurochirurgicale utilisée chez l'Homme comme traitement de dernier recours pour les douleurs neuropathiques rebelles. Elle a été développée sur des bases empiriques. Ce travail vise à une meilleure compréhension des mécanismes d'action de la SCM qui restent incomplètement élucidés à ce jour. L'objectif de cette thèse est d'étudier les effets électrophysiologiques de la SCM au niveau thalamique, chez un modèle de chat. La première partie de cette étude a consisté à établir une cartographie stéréotaxique du cortex moteur (CM) de cet animal, inexistante dans la littérature. À partir de cette cartographie, nous avons pu établir et valider un modèle de SCM chez cet animal, implanté de façon mini-invasive. La deuxième partie de ce travail a consisté à recueillir et analyser les changements électrophysiologiques de l'activité extracellulaire unitaire des cellules du noyau ventro-postéro-latéral (VPL) du thalamus, induits par différents protocoles de SCM. Nos résultats montrent une modulation de l'activité des cellules du VPL par la SCM, qui varie en fonction de la nature nociceptive ou non de la cellule thalamique. La SCM augmente l'activité des cellules non nociceptives et diminue celle des cellules nociceptives. Pour une cellule donnée, l'effet observé est indépendant de la correspondance somatotopique entre la région du CM stimulée et la localisation sur le corps du champ récepteur de la cellule enregistrée. Ce travail a ainsi permis de montrer l'existence d'une neuro-modulation différentielle du VPL par la SCM en fonction de la nature de la cellule thalamique / Motor cortex stimulation (MCS) is a neurosurgical technique developed on empirical basis and currently used as last solution for patients suffering from refractory neuropathic pain. The present work is a new attempt among other contemporary studies aiming to understand the mechanisms of action of MCS, which remain incompletely elucidated at that time. The main objective of this thesis is to study the electrophysiological effect of MCS at the thalamic level, in a cat model. The first part of this work aims to establish the stereotactic somatotopic map of the cat motor cortex (MC), not available so far in the literature. Based on this mapping, we created and validated a cat model of MCS, using a mini-invasive electrode implantation. The second part of this study included a recording and analysis of the potential changes of the unitary extracellular activity of cells located in the thalamic ventro-postero-lateral (VPL) nucleus, induced by different MCS protocols. Our results indicate a modulation of the VPL cells activity after MCS, depending on the nociceptive or non-nociceptive nature of the recorded thalamic cell. MCS increases the activity of non-nociceptive cells and decreases that of nociceptive cells. For a given cell the matching between the somatotopy of the MC stimulated region and the receptive field localization of the recorded thalamic cell is not a prerequisite for obtaining such a modulation. In conclusion, the present work has proven a neuro-modulatory differential effect of MCS on nociceptive and non-nociceptive cells in the thalamic VPL nucleus
85

Motor Control and Perception during Haptic Sensing: Effects of Varying Attentional Demand, Stimuli and Age

Master, Sabah 28 November 2012 (has links)
This thesis describes a series of experiments in human observers using neurophysiological and behavioural approaches to investigate the effects of varying haptic stimuli, attentional demand and age on motor control and perception during haptic sensing (i.e., using the hand to seek sensory information by touch). In Experiments I-IV, transcranial magnetic stimulation (TMS) was used to explore changes in corticomotor excitability when participants were actively engaged in haptic sensing tasks. These studies showed that corticospinal excitability, as reflected in motor evoked potential (MEP) amplitude, was greatly enhanced when participants were engaged in different forms of haptic sensing. Interestingly, this extra corticomotor facilitation was absent when participants performed finger movements without haptic sensing or when attention was diverted away from haptic input by a concurrent cognitive task (Exp I). This provided strong evidence that the observed corticomotor facilitation was likely central in origin and related to haptic attention. Neuroimaging has shown activation of the parieto-frontal network likely subserves this aspect of haptic perception. Further, this haptic-specific corticomotor facilitation was finely modulated depending on whether participants focused attention on identifying material (texture) as opposed to geometric properties of scanned surfaces (Exp II). With regards to aging effects, haptic-related corticomotor facilitation was associated with higher recognition accuracy in seniors (Exp III). In line with this, seniors exhibited similar levels of haptic-related corticomotor facilitation to young adults when task demands were adjusted for age (Exp IV). Interestingly, both young and senior adults also showed substantial corticomotor facilitation in the ‘resting’ hand when the ipsilateral hand was engaged in haptic sensing (Exp IV). Simply touching the stimulus without being required to identify its properties (no attentional task demands) produced no extra corticomotor facilitation in either hand or age group, attesting again to the specificity of the effects with regards to haptic attention. In Experiments V-VI, the ability to recognise 2-D letters by touch was investigated using kinematic and psychophysical measures. In Experiment V, we characterized how age affected contact forces deployed at the fingertip. This investigation showed that older adults exhibited lower normal force and increased letter-to-letter variability in normal force when compared to young adults. This difference in contact force likely contributed to longer contact times and lower recognition accuracy in older adults, suggesting a central contribution to age-related declines in haptic perception. Consistent with this interpretation, Experiment VI showed that haptic letter recognition in older adults was characterized not only by lower recognition accuracy but also by substantial increases in response times and specific patterns of confusion between letters. All in all, these investigations highlight the critical interaction of central factors such as attentional demand with aging effects on motor and perceptual aspects of haptic sensing. Of particular significance is the clear demonstration that corticomotor excitability is greatly enhanced when a haptic sensing component (i.e., attending to specific haptic features) is added to simple finger movements performed at minimal voluntary effort levels (typically <15 % of the maximal effort). These observations underline the therapeutic potential of active sensory training strategies based on haptic sensing tasks for the re-education of motor and perceptual deficits in hand function (e.g., subsequent to a stroke). The importance of adjusting attentional demands and stimuli is highlighted, particularly with regards to special considerations in the aging population.
86

Ré-agir vite et bien à une perturbation de mouvement : étude des mécanismes corticaux par couplage EEG-TMS chez l'homme. / Re-acting well and fast to a motor perturbation : cortical mechanisms studied with combined EEG-TMS

Spieser, Laure 26 October 2010 (has links)
Dans la vie de tous les jours, il arrive que nos actions soient perturbées par desvariations rapides des forces externes de notre environnement. Afin d'atteindre notre but, nousdevons alors réagir “vite et bien” à ces perturbations de mouvement, ce qui implique la mise enjeu à la fois de processus cognitifs et de processus sensori-moteurs. Nous nous sommesintéressés aux mécanismes corticaux (engagés notamment au niveau du cortex sensorimoteurprimaire) sous-tendant les interactions entre fonctions cognitive et sensorimotrice permettantd'adapter la réaction à la perturbation en fonction de notre intention, en nous efforçant de fairele lien entre les mécanismes impliqués au cours de la préparation et de la réalisation de laréaction. En utilisant le couplage EEG-TMS (avec enregistrement de l'EMG), nous avons menéune approche par stimulation-enregistrement, permettant d'observer simultanément lesmécanismes corticaux et corticospinaux précédant et suivant la stimulation, et ainsi de mieuxcomprendre le lien reliant l'activité cérébrale et le comportement.Dans l’étude 1, nous avons utilisé une perturbation motrice centrale, c'est-à-dire quenous avons demandé au sujet soit de résister soit d'assister un mouvement évoqué directementau niveau cortical par TMS. Ceci nous a permis de montrer que les processus cognitifs peuventinfluencer directement l'excitabilité corticale et corticospinale, avant la mise en jeu deprocessus sensorimoteurs impliqués dans l’exécution du mouvement. Lorsque le sujet s’estpréparé à résister au mouvement évoqué par TMS, l'augmentation anticipée de l'activité desréseaux intracorticaux inhibiteurs de M1 diminue l'excitabilité corticale, menant à une diminutionde l’excitabilité corticospinale, réduisant ainsi l’amplitude du mouvement évoqué par TMS.Dans les études suivantes (2, 3 et 4), nous nous sommes intéressés aux mécanismescorticaux et corticospinaux impliqués dans la préparation et la réaction rapide à uneperturbation périphérique du mouvement. Nous avons demandé au sujet soit de résister soitde se laisser-faire par une extension passive du poignet, et avons étudié les mécanismesimpliqués dans la modulation de la composante à longue latence du réflexe d'étirement (LLSR,qui débute environ 50 ms après la perturbation), en fonction de l'intention. Concernantl’excitabilité corticospinale, les résultats montrent que, lors de la préparation à uneperturbation périphérique, les phénomènes d'intégration sensori-motrice engendrés par lesafférences sensorielles dues à la perturbation sont pris en compte dans le réglage anticipé del'excitabilité corticospinale, afin que la réaction, déclenchée par les afférences sensorielles, soitadaptée à l'intention du sujet (étude 2). Au niveau cortical, une modification de l'activité desréseaux intracorticaux de M1 en fonction de l'intention précède la modulation de l'activitécorticale du cortex sensorimoteur primaire, liée à la genèse du LLSR, suggérant que desprocessus anticipateurs influencent l’activité du cortex sensorimoteur primaire afin que saréponse précoce à la perturbation soit adaptée à l'intention du sujet (étude 3). Enfin, dansl’étude 4, nous avons mis en évidence le rôle d'une aire motrice non primaire, la SMA proper,dans la modulation du réflexe d'étirement en fonction de l'intention.Ainsi, lorsque nous anticipons une perturbation motrice, des processus préparatoiresspécifiques (dépendants de notre intention), et différents de ceux impliqués avant la réalisationd’un mouvement sans variation des forces externes, sont mis en jeu dans la SMA proper et lecortex sensorimoteur primaire de manière à ce que la réaction rapide, déclenchée au niveau ducortex sensorimoteur par les afférences sensorielles induites par la perturbation, soit adaptée àl’intention du sujet. / In everyday life, our actions can be perturbed by rapid variations of environmentalexternal forces. In order to achieve our goals, we have to react “well and fast” to thesemovement perturbations. This reaction implies both cognitive and sensorimotor processes. Wewere interested in the cortical mechanisms (mainly involving the primary motor cortex, M1)underlying the interaction between cognitive and sensorimotor functions that allows theadaptation of the reaction to the perturbation according to the intention. We tried to relate themechanisms implicated during the preparation with those implicated during the realization ofthe reaction. With combined EEG-TMS (with EMG recording), we used a stimulation-recordingapproach, allowing simultaneous observation of cortical and corticospinal mechanisms, bothbefore and after the stimulation. This approach helps to obtain to a better understanding of therelationship between cerebral activity and behavior.In the first experiment, we used a central motor perturbation, i.e. subjects were asked toresist or to assist a movement evoked directly at the cortical level using TMS. We showed thatcognitive processes can directly influence cortical and corticospinal excitability before anyinvolvement of the sensorimotor processes related to the movement execution. When subjectsprepared to resist the TMS-evoked movement, the anticipatory increased activity of theintracortical inhibitory networks of M1 decreased the cortical excitability, leading to adecreased corticospinal excitability and thus to a reduced TMS-evoked movement.In the following experiments (2, 3 and 4), we were interested in cortical andcorticospinal mechanisms engaged during the preparation and the reaction to a peripheralmovement perturbation. We asked subjects either to resist or to not-react (to “let-go”) to apassive wrist extension, and we studied the mechanisms underlying the modulation of the longlatency stretch reflex (LLSR, starting about 50 ms after the perturbation) according to theintention. Concerning the corticospinal excitability, the results showed that, during thepreparation of a reaction to a peripheral perturbation, the anticipatory tuning of thecorticospinal excitability takes into account sensorimotor integrative phenomenons induced bythe afferent input due to the perturbation in such a way that the reaction, triggered by theafferent inputs, is adapted to the subject’s intention (experiment 2). At the cortical level, achange of M1 intracortical network activity (before the perturbation) precedes the modulationof the primary sensorimotor cortex activity that is linked to the LLSR generation (after theperturbation). This strongly suggests that anticipatory processes preset the primarysensorimotor cortex in order to adapt its early response to the perturbation according to thesubject’s intention (experiment 3). Finally, temporary inactivation of SMA proper (induced byTMS) showed that this non-primary motor area is also implicated in the modulation of thestretch reflex according to the intention (experiment 4).In conclusion, when we expect a motor perturbation, intention-specific preparatoryprocesses are engaged in SMA proper and the primary sensorimotor cortex that are differentfrom those involved in the realization of a movement without external force variations. Thesepreparatory processes allow the early motor reaction, generated by the primary sensorimotorcortex (triggered by the afferent input induced by the perturbation) to be adapted to thesubject’s intention.
87

Optimizing the efficacy of transcranial direct current stimulation on cortical neuroplasticity based on a neurovascular coupling model

Jamil, Asif 24 January 2017 (has links)
No description available.
88

Avaliação da estimulação magnética transcraniana navegada no mapeamento anatômico e funcional não invasivo do córtex motor / Evaluation of navigated transcranial magnetic stimulation in anatomical and functional mapping of the motor cortex

Paiva, Wellingson Silva 02 May 2012 (has links)
Introdução e objetivos: A estimulação magnética transcraniana (EMT) é um método exclusivo para estimulação cerebral não-invasiva. A diferença fundamental entre EMT e as outras técnicas disponíveis de mapeamento por imagem do cérebro é que se estabelece haver uma relação de causa e efeito entre a resposta fisiológica evocada e o estímulo magnético. A relação entre estrutura e função como a principal característica, constitui uma modalidade de mapeamento cerebral ainda não estabelecido. Os recentes avanços no processamento de imagem permitiram refinar EMT através de sua combinação com a ressonância magnética utilizando-se do sistema de neuronavegação para orientar o posicionamento da bobina em relação ao córtex. Assim a posição da bobina sobre o couro cabeludo pode ser mantida constante conforme verificado pela orientação de navegação em tempo real com registro visual. O objetivo deste estudo foi avaliar a utilidade da EMT no mapeamento cortical motor em comparação com o mapeamento cirúrgico com estimulação cortical direta. Métodos: O estudo foi conduzido com 30 mapeamentos consecutivos em pacientes com programação de cirurgia para tumores adjacentes ao córtex motor. O mapeamento pré-operatório foi realizado com o sistema de estimulação magnética transcraniana navegada. Esta estimulação gera um pulso magnético através de uma bobina. Este método permite estimulação diretamente no córtex cerebral. Eletródios de superfície foram anexados ao abdutor curto do polegar. Em seguida, o limiar motor em repouso (LM) foi determinado através da aplicação de estimulação para região cortical da mão presumida. Mapeamento peritumoral foi realizado na intensidade de 120% do LM. O mapeamento foi realizando com definição de coordenadas vetoriais. Estas coordenadas foram ponderadas previamente por potencial evocado motor. O mapeamento intra-operatório foi realizado pelo cirurgião antes da ressecção do tumor também com neuronavegação. Os locais de estimulação intraoperatória foram selecionados de forma independente dos resultados da EMT. Resultados: Os pontos obtidos na ECD foram comparados ao mapa da EMT segundo coordenadas vetoriais dos centros geométricos da nuvem de pontos obtidos. Verificamos que a distância dos pontos vetoriais médios (centro geométrico) dos pontos obtidos nos dois métodos de mapeamentos diferiu em 4,85 +/- 1,89 mm. A análise de correlação intraclasse revelou uma correlação de 0,901 com p<0,001. As distâncias dos pontos obtidos para o tumor, identificamos uma alta correlação entre estas variáveis com r=0,87, p=0,001. O Limiar motor na EMT é maior no córtex motor do adjacente ao tumor, comparado ao córtex normal. Não há correlação entre os limiares motores de repouso na EMT e na estimulação elétrica. A exatidão do mapeamento com EMT é mantida em pacientes com déficits motores. A condição clínica dos pacientes melhorou significativamente em 3 meses após a cirurgia. Conclusões: A estimulação magnética transcraniana navegada é uma ferramenta confiável e precisa com congruência de pontos obtidos comparados com o mapeamento intraoperatório. EMT navegada é um método promissor para o mapeamento funcional pré-operatória em cirurgia de tumor adjacente ao motor córtex / Introduction and aims: Transcranial magnetic stimulation (TMS) is a unique method for non-invasive brain stimulation. The fundamental difference between TMS and other available non-invasive brain imaging techniques is that when a physiological response is evoked by stimulation of a cortical area, that specific cortical area is causally related to the response. The relationship between structure and function as the major feature constituting a brain mapping modality can therefore not be established. Recent advances in image processing allowed us to refine TMS by combining magnetic resonance imaging modalities with TMS using a neuronavigation system to measure the position of the stimulating coil and map this position onto a MRI data set. This technique has several advantages over recent TMS mapping strategies. The position of the coil on the scalp can be held constant as verified by real time visual guidance. The aim of this study was to evaluate the usefulness of navigayed TMS for cortical mapping compared with surgical mapping with direct cirtical stimulation. Methods: The study was performed with 30 neurosurgeries for tumors in or near precentral gyrus. Preoperative mapping was performed with the navigated transcranial brain stimulation system. The TMS system calculates the strength, location, and direction of the stimulating electric field in cortical tissue. It allows online targeting of stimulation directly to peritumoral córtex. The coordinates of TMS mapping were weighted by motor evoked potential. Surface electromyography electrodes were attached to abductor pollicis brevis. Next, the resting motor threshold was determined. The motor threshold was then defined traditionally as the lowest stimulation intensity capable of eliciting motor evoked potentials in at least 5 of 10 trials. The motor threshold was reported both as the percentage of the maximum stimulator intensity. Peritumoral mapping was performed at 120% motor threshold. The intraoperative mapping was performed by the surgeon performing the tumor resection. The Intraoperative direct cortical stimulation locations were chosen independently of the TMS results. The direct electric cortical stimulation points were compared with TMS responses according to original distances of vectorial modules. Results: There is a similarity of the points performed in two mapping methods. We found the distances between geometric centers of TMS and DCS 4,85 +/- 1,89. We identified a strong correlation between these vectorial points (r = 0.901 and p < 0.001). The motor threshold in TMS is the largest in the motor cortex near to the tumor compared to normal cortex (p<0,001). Patients with deficits presented excellent accuracy in two methods. The clinical performance of the patient improved significantly 3 months after surgery. Conclusion: TMS allowed for reliable, precise application in brain mapping and the peritumoral somatotopy corresponded well between the 2 modalities. Navigated TMS is a promising method for preoperative functional mapping in motor cortex tumor surgery
89

Neuroplasticidade induzida pelo exercício: efeitos sobre o hipocampo e regiões motoras do encéfalo de ratos. / Exercise-induced neuroplasticity: effects on the hippocampus and motor regions of the rat brain.

Ferreira, Ana Francisca Barros 06 May 2011 (has links)
O exercício físico traz inúmeros benefícios para o sistema nervoso, dentre eles a melhora da memória e cognição, além de um efeito protetor em relação ao declínio mental decorrente do envelhecimento e de lesões do sistema nervoso. Este estudo teve como objetivo observar os efeitos plásticos do exercício moderado de curta duração no hipocampo e em regiões motoras do encéfalo de ratos, frequentemente afetadas por lesões ou doenças neurodegenerativas. As metodologias empregadas nestas análises foram a imuno-histoquímica, o Western blotting,o PCR em tempo real, avaliação dos níveis de neurogênese pela injeção de BrdU e imageamento de Ca2+ de astrócitos corticais. Os resultados encontrados mostram que o exercício moderado de curta duração promoveu alterações plásticas específicas em todas as regiões estudadas, variando na dependência do marcador utilizado e do decurso temporal do exercício. Acreditamos que este é suficiente para promover plasticidade difusa no sistema nervoso, que pode ser parte do substrato do efeito benéfico do exercício no sistema nervoso. / Evidence shows that physical exercise is neuroprotective and enhances brain function by improving cognition, learning and memory. It has also been associated with structural changes such as angiogenesis, synaptogenesis and neurogenesis. The aim of this study was to observe the effects of a moderate, short-term exercise protocol on the hippocampus and brain regions related to motor function, commonly affected by neurodegenerative diseases. The methods used for these analyses were immunohistochemistry, Western blotting, real-time PCR, evaluation of the levels of hippocampal neurogenesis with injections of BrdU and Ca2+ imaging of cortical astrocytes. Our results show that short-term moderate physical exercise induced specific plastic changes in all regions studied, which varied depending on the marker and time course of exercise and is enough to modulate synaptic and structural elements of neurons as well as astrocytes, playing an important role in the diffuse exercise-dependent plasticity which may underlie the beneficial effects of exercise in the brain.
90

Contrôle dopaminergique de la motricité au niveau cortical et striatal / Dopaminergic control of motor function in the cortex and the striatum

Vitrac, Clément 24 September 2014 (has links)
Le cortex moteur primaire et le striatum permettent la planification et la sélection de mouvements. La dopamine régule l'activité des neurones dans ces deux structures. La perte des neurones à dopamine projetant de la substance noire compacte vers le striatum est à l'origine de troubles moteurs observés dans la maladie de Parkinson. Nous avons caractérisé le contrôle par la dopamine des neurones du cortex moteur primaire chez la souris et avons démontré que les fibres dopaminergiques innervent préférentiellement la représentation des membres antérieurs dans les couches corticales profondes. Nous avons montré que la dopamine module localement l’activité électrophysiologique des neurones cortico-striataux via les récepteurs D2. Ces résultats montrent que la dopamine peut exercer un contrôle direct sur la motricité au niveau des neurones du cortex moteur primaire. Nous avons par la suite déterminé le potentiel des thérapies cellulaires dans un modèle animal de la maladie de Parkinson. Les approches actuelles privilégient la greffe ectopique de neurones à dopamine dans la région cible, le striatum. Nous avons choisi une approche alternative consistant à pratiquer la greffe au niveau de la région lésée, la substance noire compacte. Nous avons montré chez la souris que la lésion des neurones dopaminergiques altère les propriétés électrophysiologiques des neurones du striatum et que la greffe homotopique de neurones entraîne une meilleure récupération de ces caractéristiques électrophysiologiques que la greffe ectopique dans le striatum.Ces résultats ouvrent des perspectives d'étude des effets de la greffe homotopique sur l'activité des autres structures contrôlant la motricité. / Primary motor cortex and striatum are involved in movement planification and selection. Dopamine regulates the neuronal activity of these two structures. The motor impairments observed in Parkinson's disease originates from the loss of dopamine neurons projecting from the substantia nigra pars compacta to the striatum.We characterized the dopaminergic control of the neurons of primary motor cortex in mice and we demonstrated that dopaminergic fibers preferentially innervate the forelimb representation map in the deep cortical layers. Furthermore, we demonstrated that dopamine locally modulates the electrophysiological activity of the cortico-striatal neurons through D2 receptors. These results show that dopamine can directly control motor function by influencing neuronal activity in primary motor cortex.Thereafter, we determined the potential of cell replacement therapies in an animal model of Parkinson's disease. In most studies, the transplanted dopamine neurons have been placed within the striatum. We have chosen an alternative approach by grafting neurons into the lesioned nucleus, substantia nigra. We showed in mice that the lesion of dopaminergic neurons impaired the electrophysiological properties of the striatal neurons. Whereas these properties are not fully restored with an intra-striatal transplant, all the electrophysiological characteristics are recovered with an intra-nigral graft. This result opens new perspectives to study the homotopic graft effects on the activity of the other structures controlling motor function.

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