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Insights into the evolution of language: A comparative analysis of dopaminergic innervation of thalamic nuclei among humans and nonhuman primatesDeraway, Stacy Leigh M., Deraway 14 August 2018 (has links)
No description available.
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Thalamic contributions to motor learning and performanceSibener, Leslie Joan January 2023 (has links)
Movement is the key to animal behavior. From fighting off predators to reaching for food, our survival relies on movement. Losing the ability to move the body through the world in a purposeful way would be dire. We learn to perform a wide variety of actions, which require exact motor control. How are such skilled actions refined over time? The neural mechanism of motor learning has been posited to arise from integrating neuronal signals about motor commands, environmental context, and outcome through the cortico-basal ganglia-thalamic loop. Here, I investigate the role of two thalamic nuclei — the parafascicular (Pf) and ventroanterior/ventrolateral (VAL) —in the process of motor learning.
In an introductory Chapter 1, I introduce some key behavioral signatures of motor learning and the distributed neural circuity for movement through the cortico-basal ganglia-thalamic network. Pf and VAL are at the center of this network. Both receive basal ganglia output but differ in primary projection patterns. Pf sends large excitatory projections directly to the striatum (the main input area of the basal ganglia), while VAL projects back to the cortex. Despite their critical place in the movement system, little is known about their changing roles in motor learning.
In Chapter 2, I highlight a novel skilled forelimb joystick target task for mice; the JTT. In the JTT, head-fixed mice learn reaches to spatial targets in 2D space by moving an unrestricted joystick without visual feedback. This task allows for multiple windows of learning and refinement of various reaches in space. Over the learning of targeted reaching movements, mice increase their accuracy and individual trajectories become less variable, showing that they have learned the location of the target in space, and also refine the reaching movements.
In Chapter 3, I use 2-photon calcium imaging of the forelimb-related areas of Pf and VAL to investigate how their activity changes over learning of forelimb reaching actions. Both Pf and VAL are highly engaged during movements. Neural population engagement of Pf decreases over time, suggesting a specific role early in learning. Additionally, the underlying neural dynamics of Pf and VAL shift and occupy different state spaces over learning, as shown through principal component analysis. To investigate if neural activity in Pf or VAL encodes behavioral information, we used a ridge regression model to predict the initial direction of movements from neural data. We were able to predict the initial direction from Pf activity on early training days, but not from VAL.
In Chapter 4, I performed pre and post-learning lesions to Pf or VAL to investigate if they are needed for learning and/or performance of targeted reaches. Results show that Pf is needed for learning, but not the performance of accurate spatial reaches. VAL, on the other hand, does not affect the learning or performance of target reaches, but does affect the speed of movements. In a discussion-based Chapter 5, I summarize these above experiments, which suggest different roles for PF and VAL over learning of multiple targeted reaches, and reflect on future directions of my findings in the broader context of motor learning research in neuroscience. In particular, my findings highlight a novel and critical role for Pf in learning and processing directional information during early skill learning. This work demonstrates that the thalamus is an essential node of the brain networks involved in motor learning.
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The role of the dopamine D4 receptor in modulating state-dependent gamma oscillationsFurth, Katrina Eileen 03 November 2016 (has links)
Rhythmic oscillations in neuronal activity display variations in amplitude (power) over a range of frequencies. Attention and cognitive performance correlate with increases in cortical gamma oscillations (40-70Hz) that are generated by the coordinated firing of glutamatergic pyramidal neurons and GABAergic interneurons, and are modulated by dopamine. In the medial prefrontal cortex (mPFC) of rats, gamma power increases during treadmill walking, or after administration of an acute subanesthetic dose of the NMDA receptor antagonist ketamine. Ketamine is also used to mimic symptoms of schizophrenia, including cognitive deficits, in healthy humans and rodents. Additionally, the ability of a drug to modify ketamine-induced gamma power has been proposed to predict its pro-cognitive therapeutic efficacy. However, the mechanism underlying ketamine-induced gamma oscillations is poorly understood. We hypothesized that gamma oscillations induced by walking and ketamine would be generated by a shared mechanism in the mPFC and one of its major sources of innervation, the mediodorsal thalamus (MD). Recordings from chronically implanted electrodes in rats showed that both treadmill walking and ketamine increased gamma power, firing rates, and spike-gamma LFP correlations in the mPFC. By contrast, in the MD, treadmill walking increased all three measures, but ketamine decreased firing rates and spike-gamma LFP correlations while increasing gamma power. Therefore, walking- and ketamine-induced gamma oscillations may arise from a shared circuit in the mPFC, but different circuits in the MD.
Recent work in normal animals suggests that dopamine D4 receptors (D4Rs) synergize with the neuregulin/ErbB4 signaling pathway to modulate gamma oscillations and cognitive performance. Consequently, we hypothesized that drugs targeting the D4Rs and ErbB receptors would show pro-cognitive potential by reducing ketamine-induced gamma oscillations in mPFC. However, when injected before ketamine, neither the D4R agonist nor antagonist altered ketamine’s effects on gamma power or firing rates in the mPFC, but the pan-ErbB antagonist potentiated ketamine’s increase in gamma power, and prevented ketamine from increasing firing rates. This indicates that D4Rs and ErbB receptors influence gamma power via distinct mechanisms that interact with NMDA receptor antagonism differently. Our results highlight the value of using ketamine-induced changes in gamma power as a means of testing novel pharmaceutical agents.
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Movement, Arousal, and Attention in Secondary Sensory ThalamusPetty, Gordon Highsmith January 2023 (has links)
Neocortical sensory areas have associated primary and secondary thalamic nuclei. While primary nuclei transmit sensory information to cortex, secondary nuclei remain poorly understood. I recorded juxtasomally from the secondary somatosensory (POm) and visual (LP) nuclei of awake mice. POm activity correlated with whisking, but not precise whisker kinematics.
This movement modulation was not a result of sensory reafference, nor was it due to input from motor or somatosensory cortex, nor the superior colliculus. Whisking and pupil dilation were strongly correlated, reflecting arousal. Indeed LP, which is not part of the whisker system, tracked whisking equally well, indicating that POm activity does not encode whisker movement per se. The semblance of movement-related activity is likely instead a global effect of arousal on both nuclei. I then investigated how POm and LP may support feature-based attention.
I trained head-fixed mice to attend to one sensory modality while ignoring a second modality. I used multielectrode arrays to record simultaneously from both regions. In mice trained to respond to tactile stimuli and ignore visual stimuli, POm was robustly activated by touch and largely unresponsive to visual stimuli. The reverse pattern was observed when mice were trained to respond to visual stimuli and ignore touch, with POm now more robustly activated during visual trials. This POm activity was not explained by differences in movements (i.e., whisking, licking) resulting from the two tasks. LP exhibited similar phenomena.
I conclude that behavioral training reshapes activity in secondary thalamic nuclei. Secondary nuclei may respond to behaviorally relevant, reward-predicting stimuli regardless of stimulus modality.
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Effects of lesions to the anterior thalamic nuclei on two spatial, working memory tasks in ratsLeri, Francesco January 1995 (has links)
No description available.
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DEVELOPMENT OF THE AUDITORY THALAMUS IN THE FERRETHOWARD, JENNIFER DIXON 24 September 2002 (has links)
No description available.
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Representation of the stationary visual environment in the anterior thalamus of the leopard frogSkorina, Laura January 2013 (has links)
The optic tectum of the leopard frog has long been known to process visual information about prey and looming threats, stimuli characterized by their movement in the visual field. However, atectal frogs can still respond to the stationary visual environment, which therefore constitutes a separate visual subsystem in the frog. The present work seeks to characterize the stationary visual environment module in the leopard frog, beginning with the hypothesis that this module is located in the anterior thalamus, among two retinorecipient neuropil regions known as neuropil of Bellonci (NB) and corpus geniculatum (CG). First, the puzzle of how a stationary frog can see the stationary environment, in the absence of the eye movements necessary for persistence of vision, is resolved, as we show that whole-head movements caused by the frog's respiratory cycles keep the retinal image in motion. Next, the stationary visual environment system is evaluated along behavioral, anatomic, and physiological lines, and connections to other brain areas are elucidated. When the anterior thalamic visual center is disconnected, frogs show behavioral impairments in visually navigating the stationary world. Under electrophysiological probing, neurons in the NB/CG region show response properties consistent with their proposed role in processing information about the stationary visual environment: they respond to light/dark and color information, as well as reverse-engineered "stationary" stimuli (reproducing the movement on the retina of the visual backdrop caused by the frog's breathing movements), and they do not habituate. We show that there is no visuotopic map in the anterior thalamus but rather a nasal-ward constriction in the receptive fields of progressively more caudal cell groups in the NB/CG region. Furthermore, each side of the anterior thalamic visual region receives information from only the contralateral half of the visual field, as defined by the visual midline, resulting from a pattern of partial crossing over of optic nerve fibers that is also seen in the mammalian thalamic visual system, a commonality with unknown evolutionary implications. We show that the anterior thalamic visual region shares reciprocal connections with the same area on the opposite side of the brain, as well as with the posterior thalamus on both sides; there is also an anterograde ipsilateral projection from the NB/CG toward the medulla and presumably pre-motor areas. / Biology
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Réseaux corticaux chez le primate adulte et en développement / Primate cortical networks in the adult and during developmentRibeiro Gomes, Ana Rita 18 December 2018 (has links)
Le traçage rétrograde des voies corticales chez le singe a permis d’étudier deux sujets liés. En premier lieu, des injections dans 40 aires d'un atlas cortical de 91 aires ont permis de constituer une base de données cohérente sur la connectivité corticale à l’échelle de l’hémisphère. Les structures sous-corticales favorisant la communication corticale via la formation de boucles cortico-sous-cortico-corticales ont été examinées. Nous montrons que la force des projections du claustrum (considéré comme ayant une affiliation étroite avec le cortex) vers chaque aire explorée est exceptionnelle. De plus, un chevauchement des neurones marqués dans le claustrum a été observé suite à des paires d'injections dans des aires largement éloignées, y compris dépourvues de connexions cortico-corticales directes. A l’aide d’outils de la théorie des graphes, nous avons examiné la centralité des 40 aires et du claustrum dans le réseau cortical. En particulier, le claustrum est le meilleur exemple d’une aire pouvant prétendre au statut de « hub ». Ces résultats soulignent l'importance d'étudier les principes organisationnels du cortex via l'analyse de la topologie de son réseau. En second lieu, nous avons étudié le développement de la voie corticospinale par laquelle le cortex influence la planification, l'exécution et le contrôle de la motricité fine. Nous montrons que la topologie des projections corticospinales chez l’adulte émerge suite à un processus développemental de raffinement des projections ipsi- et controlatérale étendues. Ces résultats suggèrent que le développement de la connectivité corticale pourrait être régulé de manière dynamique et spécifique aux primates / The retrograde tracing experiments in macaque cortex in this thesis had two related objectives. Firstly, injections in 40 cortical areas (from a 91-area atlas) allowed the construction of a hemisphere-wide consistent database of cortical connectivity. We examined which subcortical structures promote cortical communication via the formation of cortico-subcortical-cortical loops. The claustrum, which we argue has a tight affiliation with the cortex, showed uniquely strong outputs to every cortical area. Widely separated injection pairs led to overlapping labelled neurons in the claustrum including those pairs lacking direct cortico-cortical connections. Using graph theoretic tools, we examined how central the 40 areas and claustrum are in the cortical network, specifically with respect to hub status. This showed that the claustrum is, beyond doubt, the prime hub of the cortex. These findings emphasise the importance of studying the organizational principles of the cortex via the analysis of its network topology. Secondly, we investigated the development of the corticospinal pathway, a route over which the cortex directly influences the planning, execution and control of fine voluntary movements. We show that the adult pattern of corticospinal projections emerges via a developmental process from a widespread ipsi- and contralateral distribution. These findings suggest that the developmental refinement of cortical connectivity might be dynamically regulated and primate specific
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Traitement des informations thalamiques au travers des ganglions de la base : approche électrophysiologique et optogénétique in vivo / Treatment of thalamic information through the basal ganglia : combining electrophysiology and optogenetics in vivoHanini-Daoud, Maroua 16 December 2016 (has links)
Le centre médian/parafasciculaire (CM/Pf) du thalamus a récemment émergé comme un élément d'intérêt dans le contexte de la maladie de Parkinson. Ainsi le fonctionnement normal et pathologique des GB ne peut pas être pleinement élucidé sans qu'il ne soit pris en considération. Dans ce contexte, nous avons analysé le transfert des informations thalamiques dans les GB en enregistrant, in vivo, les réponses évoquées au niveau de la structure de sortie des GB, la substantce noire pars reticulata (SNr) soit par la stimulation électrique ou optogénétique du CM/Pf. Ensuite, nous avons étudié les composantes des GB impliquées dans ces réponses en analysant les réponses évoquées par l'activation optogenetique spécifique des voies thalamo-striée, thalamo-subthalamique ou thalamo-nigrale. À la fois l'activation électrique et optogenetique du CM/Pf évoquent des réponses complexes dans la SNr qui sont composées d'une inhibition qui peut être précédée et/ou suivie d'excitations. L'inhibition et l'excitation tardive dépendent de l'activation des voies trans-striatales, alors que les premières excitations mettent en jeu les voies thalamo-subthalamique et thalamo-nigrale. Nous avons également étudié l'impact des interneurones cholinergiques du striatum ainsi que les afférences dopaminergiques sur le transfert des informations thalamiques dans les GB. Pour ce faire, nous avons enregistré les réponses évoquées au niveau des neurones de projection du striatum suite à la stimulation électrique du CM/Pf avec ou sans l'inhibition optogénétique des CINs. Nous serons alors en mesure de déterminer comment les CINs sont impliqués dans le transfert des informations thalamiques au sein des GB. / The centre median/parafascicular (CM/Pf) of the thalamus has recently emerged as a component of interest in the context of Parkinson’s disease. Thus normal and pathological dynamics of BG cannot be fully understood unless it is taken into account. Here, we analyzed the transfer of CM/Pf information through BG by recording, in vivo, the evoked responses of BG output neurons in the substantia nigra pars reticulata (SNr) to either electrical or optogenetic CM/Pf stimulations. Then, we investigated the BG components involved in these responses by analyzing the responses evoked by specific optogenetic activation of the thalamo-striatal, thalamo-subthalamic or thalamo-nigral pathways. Both electrical and optogenetic activation of CM/Pf evoke complex responses in SNr that are composed of an inhibition that can be preceded and/or followed by excitations. The inhibition and the late excitation rely on the activation of the trans-striatal pathways, whereas the early excitations involve thalamo-subthalamic and thalamo-nigral projections. We are currently analyzing whether and how the striatal cholinergic interneurons (CINs) and the dopaminergic afferent system modulate the transfer of thalamic information within the BG. For the second part of my project, we analyzed the treatment of thalamic information from CM/Pf at the level of the striatum. To do this, we recorded the evoked responses of striatal projection neurons by the electrical stimulation of the CM/Pf with or without the inhibition of the CINs by optogenetics. We will then be able to determine how CINs are involved in the transfer of thalamic information at the level of the striatum.
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Stimulation, surveillance et algorithme de détection du noyau antérieur du thalamus dans le cadre d'un modèle d'épilepsie focale motrice chez le primate / STIMULATION THERAPY, MONITORING AND CLOSED-LOOP ALGORITHMS INTERFACING TO THE ANTERIOR NUCLEUS (AN) OF THE THALAMUS IN A FOCAL EPILEPSY MONKEY MODELSherdil, Ariana 05 July 2017 (has links)
Dans le cadre de l’étude du contrôle de l’épilepsie du lobe mésio temporal (MTLE), il a été montré que le noyau antérieur du thalamus (ANT) est impliqué dans les crises; son rôle exact n’a cependant pas encore été décrit. Cette implication ainsi que sa position stratégique au sein du circuit limbique de Papez en ont fait une cible de choix pour la stimulation cérébrale profonde (Deep Brain Stimulation, DBS). De nombreuses études ont ainsi été menées depuis une vingtaine d’années chez l’animal comme chez l’Homme, utilisant de nombreux paradigmes de stimulation, et de nombreuses conclusions, parfois contradictoires en ont découlé. Mais afin de pouvoir stimuler le ANT de manière adéquate pour obtenir un effet sur les crises, il faut comprendre de quelle façon il est impliqué dans la MTLE. Un modèle animal fiable et représentatif de la pathologie de l’Homme est nécessaire pour répondre à ces questions. Dans la première partie de ce travail nous avons caractérisé un modèle de MTLE à la demande chez le primate non-humain (NHP). Nous avons montré chez 5 NHPs qu’une injection de pénicilline (PNC) dans l’hippocampe (HPC) entraînait la survenue de crises typiques pendant 4 à 5 heures. La cinétique d’apparition et d’extinction des évènements ictaux ne varient pas entre les animaux et entre les différentes expériences ; de plus, la fréquence des crises présente un plateau stable, ce qui permettrait d’agir pendant cette période afin de tester de nouvelles drogues ou thérapies. Une sclérose hippocampique accompagnée de remaniements cellulaires a également pu être observée dans l’HPC injecté. Dans une seconde partie, nous avons utilisé ce modèle de MTLE afin d’identifier la nature de l’implication du ANT (simple relais passif ou nœud au sein du circuit épileptique primaire). Pour ce faire, nous avons évalué les effets de la neuromodulation chimique et électrique du ANT sur l’activité ictale de l’HPC. Nous avons pu observer un changement de l’épilepsie suite à la neuromodulation chimique du ANT, et également une variation de l’activité électrique de base de l’HPC à une certaine fréquence donnée de stimulation du ANT. Il s’est ensuite avéré que cette fréquence de stimulation entraînait une amélioration significative du nombre de crises et du temps total passé en crise. Enfin, nous avons essayé d’identifier au travers de l’analyse de cohérence entre les activités enregistrées simultanément dans le ANT et l’HPC des biomarqueurs électrophysiologiques prédictifs d’une bonne efficacité de la DBS. Cette démarche pourrait ainsi apporter des pistes afin de proposer une stimulation plus intelligente et mieux adaptée à chaque patient. / It has been shown that the anterior nucleus of the thalamus (ANT) is involved in the mésio temporal lobe epilepsy (mTLE); but its role has not been described yet. This implication, in addition to its strategic position within the Papez circuit makes it a prime target for the deep brain stimulation (DBS). Many studies have then been led for twenty years in humans and animals, using many stimulation paradigms, and several conclusions, sometimes conflicting resulted. In order to stimulate the ANT in an adequate manner to obtain an effect on seizures, it is crucial to understand how the ANT is involved during mTLE. A reliable and representative animal model of the human pathology is needed to answer these questions. In the first part of this work, an on demand model of mTLE in the non-human primate (NHP) has been characterized. It has been shown in five NHPs that a penicillin (PNC) injection in the hippocampus (HPC) led to the occurrence of typical seizures during 4 to 5 hours. The onset and disappearance kinetic of ictal events doesn’t vary between animals and experiments; in addition, the seizure frequency presents a stable plateau which could be useful to test new drugs or therapies. A hippocampic sclerosis supported by cellular adjustments has also been observed in the injected HPC). In a second part, we used this model of mTLE in order to identify the involvement type of the ANT (common passive relay or node within the primary epileptic circuit). To do so, we evaluated the effects of chemical and electrical neuromodulation of the ANT on the HPC ictal activity. We observed variation of the HPC baseline electric activity at a specific stimulation frequency of the ANT. Then we found out that this stimulation frequency led to a significate improvement of the number of seizures and of the total time spent in seizure. Then, we tried to identify using coherence analysis between activities recorded in the ANT and the HPC some electrophysiological biomarkers to prevent a good efficacy of the DBS. This approach could then lead to solutions which could offer a smarter and better suited stimulation to the patients.
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