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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.
1

Glutamate receptors in the ventral tegmental area: a potential mechanism involved in long term potentiation

Barnett, Scott Thomas Charles January 2006 (has links)
In the present study, footshock, which produces a powerful aversive emotional response was used in a Pavlovian conditioning experiment as an unconditioned stimulis (UCS), and was paired with the presentation of a light used as a conditioned stimulis (CS). There is an accumulation of evidence that supports the assertion that dopaminergic (DA) neurons within the ventral tegmental area (VTA) are active in processes that contribute to the amygdala-based circuitry involved in regulating emotionally salient responses. To build upon findings implicating VTA DA, excitatory glutamate (Glu), NMDA and AMPA receptors, were examined with respect to their role in Pavlovian conditioned fear responding. Fear potentiated startle (FPS) was used to assess the effects of intra-VTA infused AP5, and intra-VTA infused CNQX on conditioned fear responding in laboratory rats. The administration of the NMDA receptor antagonist AP5 (at 1.0, 2.5, and 5.0ug doses), blocked the ability of a conditioned stimulus (CS) previously paired with footshock to become conditioned to the UCS. Similarly, administration of the AMPA receptor antagonist CNQX (at 1.0, 2.5, 5.0ug doses), inhibited the ability of the CS to become conditioned to the UCS. The results of this study indicate the VTA is an important site for synaptic modifications associated with fear learning, and that activation of excitatory Glutamatergic receptors in the VTA play a necessary part of the processing underlying fear conditioning. Measures of shock reactivity demonstrated that the infusion of AP5 and CNQX into the VTA did not inhibit baseline startle amplitudes. The administration of AP5 and CNQX did not suppress the perception of footshock as an aversive stimulus. This study provides further definition to established knowledge surrounding the neural processes whereby neutral environmental cues gain negative emotional salience as occurs in fear conditioning. It was hypothesised that the action of excitatory glutamatergic transmission within the VTA acts on NMDA and AMPA receptors is to assist in the acquisition of Pavlovian conditioned fear, possibly through the same synaptic mechanisms that govern LTP.
2

Glutamate receptors in the ventral tegmental area: a potential mechanism involved in long term potentiation

Barnett, Scott Thomas Charles January 2006 (has links)
In the present study, footshock, which produces a powerful aversive emotional response was used in a Pavlovian conditioning experiment as an unconditioned stimulis (UCS), and was paired with the presentation of a light used as a conditioned stimulis (CS). There is an accumulation of evidence that supports the assertion that dopaminergic (DA) neurons within the ventral tegmental area (VTA) are active in processes that contribute to the amygdala-based circuitry involved in regulating emotionally salient responses. To build upon findings implicating VTA DA, excitatory glutamate (Glu), NMDA and AMPA receptors, were examined with respect to their role in Pavlovian conditioned fear responding. Fear potentiated startle (FPS) was used to assess the effects of intra-VTA infused AP5, and intra-VTA infused CNQX on conditioned fear responding in laboratory rats. The administration of the NMDA receptor antagonist AP5 (at 1.0, 2.5, and 5.0ug doses), blocked the ability of a conditioned stimulus (CS) previously paired with footshock to become conditioned to the UCS. Similarly, administration of the AMPA receptor antagonist CNQX (at 1.0, 2.5, 5.0ug doses), inhibited the ability of the CS to become conditioned to the UCS. The results of this study indicate the VTA is an important site for synaptic modifications associated with fear learning, and that activation of excitatory Glutamatergic receptors in the VTA play a necessary part of the processing underlying fear conditioning. Measures of shock reactivity demonstrated that the infusion of AP5 and CNQX into the VTA did not inhibit baseline startle amplitudes. The administration of AP5 and CNQX did not suppress the perception of footshock as an aversive stimulus. This study provides further definition to established knowledge surrounding the neural processes whereby neutral environmental cues gain negative emotional salience as occurs in fear conditioning. It was hypothesised that the action of excitatory glutamatergic transmission within the VTA acts on NMDA and AMPA receptors is to assist in the acquisition of Pavlovian conditioned fear, possibly through the same synaptic mechanisms that govern LTP.
3

Implication de l’habénula latérale dans les processus mnésiques chez le rat / Involvement of the lateral habenula in memory processes in rat

Mathis, Victor 08 December 2016 (has links)
Ce travail de thèse avait pour objectif d’étudier le rôle de l’habénula latérale (HbL) dans les processus mnésiques chez le Rat en utilisant une approche par inactivation réversible grâce à l’administration de muscimol ou de CNQX. Nous avons ainsi montré l’implication de l’HbL dans : i) les processus d’encodage et de rappel d’une mémoire spatiale en piscine de Morris ; ii) la mémoire de travail, comme relais potentiel d’informations en provenance du cortex préfrontal médian, dans un paradigme de non-appariement différé à la position en boites de conditionnement opérant; iii) la réponse émotionnelle, aux niveaux comportemental et physiologique, à une situation stressante. L’ensemble de ces résultats suggèrent que l’HbL est impliquée dans les processus « online » de gestion des informations sensorielles, et qu’elle participe à la prise en compte de l’aspect émotionnel d’une situation. Ces particularités en font un lien important potentiel entre gestion des émotions et cognition. / The main objective of this thesis was to investigate the role of the lateral habenula (LHb) in mnemonic processes in rats using reversible inactivations with muscimol or CNQX. We have shown the involvement of the LHb in : i) encoding and retrieval of spatial reference memory in the Morris water maze ; ii) working memory, as a potential relay of top-down information coming from the medial prefrontal cortex, in a delayed non-matching to position paradigm using operant chambers ; iii) the behavioral and physiological responses to stressful situations. Altogether, those results suggest that the LHb is involved in the « online » process of sensory information. They also suggest that it is involved in coping with particularly stressful situations, and further position the LHb as an interface between emotions and cognition.
4

Les mécanismes synaptiques et intrinsèques qui sous-tendent l’activité des cellules réticulospinales (RS) en réponse à une stimulation sensorielle de type cutané chez la lamproie

Fénelon, Karine 11 1900 (has links)
Chez diverses espèces animales, les informations sensorielles peuvent déclencher la locomotion. Ceci nécessite l’intégration des informations sensorielles par le système nerveux central. Chez la lamproie, les réseaux locomoteurs spinaux sont activés et contrôlés par les cellules réticulospinales (RS), système descendant le plus important. Ces cellules reçoivent des informations variées provenant notamment de la périphérie. Une fois activées par une brève stimulation cutanée d’intensité suffisante, les cellules RS produisent des dépolarisations soutenues de durées variées impliquant des propriétés intrinsèques calcium-dépendantes et associées à l’induction de la nage de fuite. Au cours de ce doctorat, nous avons voulu savoir si les afférences synaptiques ont une influence sur la durée des dépolarisations soutenues et si l’ensemble des cellules RS partagent des propriétés d’intégration similaires, impliquant possiblement les réserves de calcium internes. Dans un premier temps, nous montrons pour la première fois qu’en plus de dépendre des propriétés intrinsèques des cellules réticulospinales, les dépolarisations soutenues dépendent des afférences excitatrices glutamatergiques, incluant les afférences spinales, pour perdurer pendant de longues périodes de temps. Les afférences cutanées ne participent pas au maintien des dépolarisations soutenues et les afférences inhibitrices glycinergique et GABAergiques ne sont pas suffisantes pour les arrêter. Dans un deuxième temps, nous montrons que suite à une stimulation cutanée, l’ensemble des cellules RS localisées dans les quatre noyaux réticulés possèdent un patron d’activation similaire et elles peuvent toutes produire des dépolarisations soutenues dont le maintien ne dépend pas des réserves de calcium internes. Enfin, les résultats obtenus durant ce doctorat ont permis de mieux comprendre les mécanismes cellulaires par lesquels l’ensemble des cellules RS intègrent une brève information sensorielle et la transforment en une réponse soutenue associée à une commande motrice. / In various animal species, sensory information can initiate locomotion. This relies on the integration of sensory inputs by the central nervous system. In lampreys, the spinal locomotor networks are activated and controlled by the reticulospinal cells (RS) which constitute the main descending system. In turn, RS cells receive information coming from various synaptic inputs such as the sensory afferents. Once activated by a brief cutaneous stimulation of sufficient strength, RS cells display sustained depolarizations of various durations that rely on calcium-dependant intrinsic properties and lead to the onset of escape swimming. During the course of this Ph.D, we aimed at determining whether synaptic inputs can modulate the duration of the sustained depolarizations and if the different populations of RS cells share the same integrative properties, possibly involving the internal calcium stores. First, our results show for the first time that excitatory glutamatergic inputs, including ascending spinal feedback, contribute to prolong the sustained depolarizations for long periods of time. Cutaneous inputs do not contribute to maintain the sustained depolarizations and inhibitory glycinergic and GABAergic inputs are not sufficient to stop them. Second, we show that in response to cutaneous stimulation, the RS located in the four reticular nuclei display a similar activation pattern and can all produce sustained depolarizations which do not depend on internal calcium release to be maintained. Finally, the results obtained during this Ph.D allowed us to better understand the cellular mechanisms by which the RS cells integrate and transform a brief sensory information into a sustained response associated with a motor command.
5

Les mécanismes synaptiques et intrinsèques qui sous-tendent l’activité des cellules réticulospinales (RS) en réponse à une stimulation sensorielle de type cutané chez la lamproie

Fénelon, Karine 11 1900 (has links)
Chez diverses espèces animales, les informations sensorielles peuvent déclencher la locomotion. Ceci nécessite l’intégration des informations sensorielles par le système nerveux central. Chez la lamproie, les réseaux locomoteurs spinaux sont activés et contrôlés par les cellules réticulospinales (RS), système descendant le plus important. Ces cellules reçoivent des informations variées provenant notamment de la périphérie. Une fois activées par une brève stimulation cutanée d’intensité suffisante, les cellules RS produisent des dépolarisations soutenues de durées variées impliquant des propriétés intrinsèques calcium-dépendantes et associées à l’induction de la nage de fuite. Au cours de ce doctorat, nous avons voulu savoir si les afférences synaptiques ont une influence sur la durée des dépolarisations soutenues et si l’ensemble des cellules RS partagent des propriétés d’intégration similaires, impliquant possiblement les réserves de calcium internes. Dans un premier temps, nous montrons pour la première fois qu’en plus de dépendre des propriétés intrinsèques des cellules réticulospinales, les dépolarisations soutenues dépendent des afférences excitatrices glutamatergiques, incluant les afférences spinales, pour perdurer pendant de longues périodes de temps. Les afférences cutanées ne participent pas au maintien des dépolarisations soutenues et les afférences inhibitrices glycinergique et GABAergiques ne sont pas suffisantes pour les arrêter. Dans un deuxième temps, nous montrons que suite à une stimulation cutanée, l’ensemble des cellules RS localisées dans les quatre noyaux réticulés possèdent un patron d’activation similaire et elles peuvent toutes produire des dépolarisations soutenues dont le maintien ne dépend pas des réserves de calcium internes. Enfin, les résultats obtenus durant ce doctorat ont permis de mieux comprendre les mécanismes cellulaires par lesquels l’ensemble des cellules RS intègrent une brève information sensorielle et la transforment en une réponse soutenue associée à une commande motrice. / In various animal species, sensory information can initiate locomotion. This relies on the integration of sensory inputs by the central nervous system. In lampreys, the spinal locomotor networks are activated and controlled by the reticulospinal cells (RS) which constitute the main descending system. In turn, RS cells receive information coming from various synaptic inputs such as the sensory afferents. Once activated by a brief cutaneous stimulation of sufficient strength, RS cells display sustained depolarizations of various durations that rely on calcium-dependant intrinsic properties and lead to the onset of escape swimming. During the course of this Ph.D, we aimed at determining whether synaptic inputs can modulate the duration of the sustained depolarizations and if the different populations of RS cells share the same integrative properties, possibly involving the internal calcium stores. First, our results show for the first time that excitatory glutamatergic inputs, including ascending spinal feedback, contribute to prolong the sustained depolarizations for long periods of time. Cutaneous inputs do not contribute to maintain the sustained depolarizations and inhibitory glycinergic and GABAergic inputs are not sufficient to stop them. Second, we show that in response to cutaneous stimulation, the RS located in the four reticular nuclei display a similar activation pattern and can all produce sustained depolarizations which do not depend on internal calcium release to be maintained. Finally, the results obtained during this Ph.D allowed us to better understand the cellular mechanisms by which the RS cells integrate and transform a brief sensory information into a sustained response associated with a motor command.

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