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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

Exploring the roles of inputs to hippocampal area CA1

Allison, Elizabeth Anastasia Margaret Alice January 2016 (has links)
Place cells in the hippocampus fire in specific locations within an environment. The aim of this thesis is to investigate the different inputs to the hippocampus and what they contribute to place cell activity and performance of hippocampus-dependent tasks. Place cell activity can also be modulated by relevant features of a task such as a future destination or trajectory. Initial experiments investigated the origin and function of this trajectory-dependent activity and later experiments targeted the medial entorhinal cortex inputs to the hippocampal formation and investigated what they contributed to place cell activity and behaviour. The purpose of the first study was to determine whether trajectory dependent activity occurs in CA3 in a hippocampus-dependent serial-reversal task on the double-Y-maze and to compare it with that seen in CA1. Place cells in both CA3 and CA1 were recorded in rats trained on a serial-reversal task on a double-Y-maze. Rats were trained to run from a start box through two Y-junctions to one of four goal locations. After 10 trials the reward was moved to a new location, until all the boxes had been rewarded. Previous research has found that 44% of CA1 place cells with fields in the start areas of the maze show trajectory-dependent activity in rats trained on the task. This study found that a similar proportion of CA3 place cells also show trajectory-dependent activity in rats trained on this task and that this activity develops at the same time point as the task is learned. This result suggests that trajectory-dependent activity may be generated earlier in the circuit than CA1. Secondly, the contribution of the nucleus reuniens (N.Re) to spatial tasks was investigated. Previously, trajectory-dependent activity has been found to reach the hippocampus via N.Re, however this was shown in a hippocampus-independent task. To investigate the possible role that this input may play in behaviour, N.Re was lesioned and animals were tested on acquisition and performance of the double-Y-maze serial-reversal task described previously. Surprisingly, lesions had no effects on either learning or performance. Taken together with previous data from other studies, this suggests that trajectory dependent activity is not one unique phenomenon but is rather multiple similar phenomena which may originate in different brain regions and fulfil different roles in navigation depending on the demands of the task. In addition, animals were tested on tasks involving allocentric or egocentric navigation. Results suggest that N.Re may have a role in the selection or performance of allocentric navigation but not egocentric navigation. Thirdly, the role of inputs from the medial entorhinal cortex (MEC) to place cells was investigated. Consistent with previous research, MEC lesions resulted in larger, less precise place fields in CA1 place cells. By performing cue-rotation experiments using either distal or proximal cues it was observed that place fields in the MEC lesion animals were not anchored to distal cues but were either stable or anchored to other aspects of the environment. However, place cells in the MEC lesion group still followed proximal cues suggesting that the deficit is restricted to distal landmarks. This suggests that the MEC may process distal landmark information allowing the use of distal landmarks for orientation and self-location within an environment. This thesis contributes a better understanding of the role and origins of trajectory dependent activity as well as a novel finding that the MEC contributes information about distal landmarks to the hippocampus.
2

Cells of Origin of the Hippocampal Afferent Projection From the Nucleus Reuniens Thalami - a Combined Golgi-HRP Study in the Rat

Baisden, Ronald H., Hoover, Donald B. 01 December 1979 (has links)
Neurons of the nucleus reuniens thalami stained with Golgi methods are compared to cells in this nucleus labelled in retrograde fashion after hippocampal injections of horseradish peroxidase. The cellular morphology ranges from fusiform to multiangular with most cells showing radiating processes characteristic of neurons in the reticular core. Dendrites are long and relatively smooth, with a few sparsely distributed spinous processes. These cells are comparable to the cholinergic cells of the median septal/diagonal band area which also project into the hippocampal formation.
3

Rôle des noyaux réuniens (Re) et rhomboïde (Rh) du thalamus dans la plasticité structurale associée à la persistance d’un souvenir spatial chez le rat / Role of the reuniens and rhomboid thalamic nuclei in the structural plasticity associated with spatial memory persistence in rat

Klein, Marie-Muguet 14 December 2018 (has links)
La théorie standard de la consolidation postule que l’information est initialement encodée dans le réseau hippocampo-cortical, créant une trace mnésique au sein de l’hippocampe (HIP). Au cours du temps, la trace est transférée au cortex préfrontal médian (CPFm), et notamment au cortex cingulaire antérieur (CCA). À la suite de lésion des noyaux reuniens et rhomboide (ReRh), réciproquement connectés à l’HIP et au CPFm, le souvenir spatial se forme normalement mais ne persiste pas dans le temps. Ainsi, nous avons évalué l’impact de la lésion ReRh sur la plasticité structurale sous-tendant la persistance du souvenir spatial. Des rats lésés ReRh ont été entraînés en piscine de Morris et testés pour un rappel récent (5j) ou ancien (25j). La plasticité structurale a été évaluée par coloration de Golgi dans l’HIP et le CPFm. La lésion ReRh n'avait aucun effet sur l’apprentissage et le souvenir récent, mais a altéré celui du souvenir ancien. Dans le CA1 des rats Sham, le nombre d'épines dendritiques a été augmenté aux deux délais (5 et 25j) post-acquisition comparé au niveau basal. Après la lésion, cette augmentation n’a pas persisté entre 5 et 25j. Dans le CCA des rats Sham, le nombre d'épines dendritiques a été augmenté uniquement à 25j comparé au niveau de base, une modification non observée chez les rats lésés. Ainsi, à la lésion des noyaux ReRh perturbe la plasticité structurale sous-tendant le souvenir spatial ancien indiquant un rôle crucial de ces noyaux dans l’établissement d’un souvenir persistant. / The standard model of systemic consolidation posits that information is initially encoded in the hippocampo-neocortical network, the memory trace being first created in the sole hippocampus (HIP). Over time, the trace is progressively transferred to modules of the medial prefrontal cortex (mPFC), particularly to the anterior cingulate cortex (ACC). Following lesions of the thalamic reuniens and rhomboid nuclei (ReRh), which are reciprocally connected with both the Hipp and mPFC, a spatial memory forms normally but does not persist (Loureiro et al 2012). Therefore, we assessed the impact of ReRh lesions on structural plasticity underlying spatial memory persistence. Male Long-Evans rats subjected to NMDA lesions of the ReRh nuclei were trained in the Morris Water Maze and tested for retrieval of recent (5 days) or remote (25 days) memory. Structural plasticity was assessed on Golgi-stained material in the HIP and CPFm. ReRh lesions had no effect on learning and recent memory, but altered remote memory. In the HIP (CA1) of sham-operated rats, the spine number was increased at both 5 and 25 days post-acquisition vs baseline. After ReRh lesion, the increase did not persist from 5 to 25 days. In the mPFC (ACC) of sham-operated rats, the spine number was increased only at 25 days vs baseline, a modification not observed in ReRh lesioned rats. Thus, following lesion of ReRh nuclei, structural plasticity underlying remote spatial memory formation does not operate correctly in the mPFC and Hip, pointing to a crucial role of ReRh in memory persistence.

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