1 |
Direct Connections between the Lateral Entorhinal Cortex and Hippocampus or Medial Prefrontal cortex: Their Role in the Retrieval of Associative MemoriesTanninen, Stephanie 27 November 2012 (has links)
Consolidation of associative memories may depend on communication between the lateral entorhinal cortex (LEC) and hippocampus (HPC) for recently learned memories and the LEC and medial prefrontal cortex (mPFC) for remote memories. To determine whether direct connections between these regions are necessary for the retrieval of a recently or remotely learned memory, rats acquired an associative memory through trace eyeblink conditioning and were tested for memory retention after inactivating the regions of interest with the GABAA agonist, muscimol. Inactivating the LEC-HPC connection did not impair memory retrieval. However, inactivating the LEC-mPFC connection impaired remote, but not recent, memory retrieval. Thus, the LEC and mPFC connection is necessary for the retrieval of a remotely, but not recently learned associative memory. Increased reliance on the entorhinal-prefrontal connection indicates the strengthening of functional connectivity between the two regions, which may be a biological correlate for the proposed reorganization during systems consolidation.
|
2 |
Direct Connections between the Lateral Entorhinal Cortex and Hippocampus or Medial Prefrontal cortex: Their Role in the Retrieval of Associative MemoriesTanninen, Stephanie 27 November 2012 (has links)
Consolidation of associative memories may depend on communication between the lateral entorhinal cortex (LEC) and hippocampus (HPC) for recently learned memories and the LEC and medial prefrontal cortex (mPFC) for remote memories. To determine whether direct connections between these regions are necessary for the retrieval of a recently or remotely learned memory, rats acquired an associative memory through trace eyeblink conditioning and were tested for memory retention after inactivating the regions of interest with the GABAA agonist, muscimol. Inactivating the LEC-HPC connection did not impair memory retrieval. However, inactivating the LEC-mPFC connection impaired remote, but not recent, memory retrieval. Thus, the LEC and mPFC connection is necessary for the retrieval of a remotely, but not recently learned associative memory. Increased reliance on the entorhinal-prefrontal connection indicates the strengthening of functional connectivity between the two regions, which may be a biological correlate for the proposed reorganization during systems consolidation.
|
3 |
Cognitive and neural processes underlying memory for time and contextPersson, Bjorn Martin January 2017 (has links)
The aim of this thesis is to examine the underlying cognitive and neural processes at play during retrieval of temporal and contextual source information. This was assessed across three experimental chapters. In the first experimental chapter, Chapter 2, the neural loci of context associations were assessed. Rats trained on an odour-context association task were given lesions to either the Lateral Entorhinal Cortex (LEC) or sham lesions. After surgery, performance on the odour-context task was assessed. It was hypothesised that memory for previously learned odour-context associations would be impaired following LEC lesions but not sham lesions. The results supported this hypothesis, demonstrating impaired memory for the previously learned odour-context associations in the LEC lesion group compared to the Sham lesion. In Chapter 3, the underlying retrieval processes used to retrieve time and context in human memory was assessed across three experiments. It was hypothesised that time would be remembered accurately using both recollection and familiarity, while correct context memory should rely on recollection alone. Two out of the three experiments supported this hypothesis, demonstrating that temporal information can be retrieved using familiarity in certain instances. The final experimental Chapter 4 used fMRI to extend Chapter 3 and examine whether neural activity would be greater in regions associated with recollection during memory for context, while activity in familiarity-related regions would be higher during memory for time. Results revealed no support for these predictions with no regions linked to recollection showing greater context-related activity, and no regions previously linked to familiarity exhibiting increased activation as temporal information was retrieved. The results are discussed in relation to established recollection and familiarity frameworks and previous work examining the neural substrates supporting memory for time and context.
|
4 |
Bases neuronales de l’apprentissage associatif multisensoriel : implication différentielle du cortex entorhinal et de l’hippocampe chez le rat / Neuronal basis of multisensory associative learning : differential involvement of the entorhinal cortex and the hippocampus in the ratBoisselier, Lise 02 December 2016 (has links)
L'objectif de cette thèse est d'étudier l'implication de deux structures de la formation hippocampique, le cortex entorhinal latéral (CEL) et l'hippocampe dorsal (DH), dans les processus sous-tendant la formation et la flexibilité d'associations entre deux stimuli de modalités sensorielles différentes : l'olfaction et le toucher. Pour cela, une tâche bimodale olfacto-tactile (OT) est développée chez le rat. Dans celle-ci, l'animal doit apprendre à identifier une combinaison "odeur-texture" spécifique parmi les trois proposées afin d'obtenir un renforcement (ex: O1T1+ O2T1 O1T2, + désignant la combinaison renforcée). Aucun indice spatial ou contextuel n'est pertinent pour résoudre cette tâche. Suite à l'acquisition de deux tâches différentes, les stimuli sont réassociés sous forme de combinaisons inédites dans une troisième tâche appelée « recombinaison ». La manipulation pharmacologique de l'activité du CEL a mis en évidence l'implication des systèmes glutamatergique NMDA et cholinergique de cette structure dans les processus sous-tendant ces deux types de tâche. En revanche, si le DH n'est pas indispensable pour l'acquisition, son système cholinergique est critique pour la recombinaison. En comparaison avec l'acquisition, l'étude électrophysiologique a montré que la recombinaison repose sur un découplage de la synchronisation entre les activités oscillatoires du CEL et celles du DH dans la bande thêta (5-12 Hz). De plus, cet apprentissage est associé à une augmentation de l'amplitude des oscillations bêta (15-45 Hz) dans le CEL. Ces travaux montrent que le CEL et le DH interviennent dans les processus sous-tendant la flexibilité des représentations bimodales / The goal of this thesis is to study the involvement of two structures of the hippocampal formation, the lateral entorhinal cortex (LEC) and the dorsal hippocampus (DH), in the processes underlying the formation and the flexibility of associations of stimuli between two different sensory modalities. To this aim, a new olfactory-tactile (OT) bimodal task has been developed in the rat. To solve the task, animals have to identity one “odor-texture” combination between three in order to obtain a reinforcement (ex: O1T1+ O2T1 O1T2, + for the baited cup). This procedure excludes the use of any spatial or contextual cues for solving the task. After the acquisition of two different tasks, the familiar stimuli used in acquisition were recombined in a third task (called “recombination”). The pharmacological manipulation of the LEC showed that the NMDA glutamatergic and cholinergic system in this structure are involved in the processes underlying the acquisition and the recombination. In contrast, the cholinergic system in the DH is selectively and critically involved in the recombination processes. Compared to acquisition, our electrophysiological data showed that the recombination is based on a desynchronization between the oscillatory activities of the LEC and of the DH in the theta band (5-12 Hz). Moreover, this task is associated with increased amplitude of beta oscillations (15-45 Hz) in the LEC. These data demonstrated that the LEC and the DH are critically involved in the processes underlying the flexibility of bimodal representations
|
Page generated in 0.1212 seconds