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Estimulação do córtex motor e antinocicepção: envolvimento da via de analgesia serotonérgica descendente. / Motor cortex stimulation and antinociception: involvement of descending serotonergic pain pathway.Patrícia Sanae de Souza Lopes 20 September 2013 (has links)
A estimulação epidural do córtex motor (ECM) é eficaz no tratamento da dor neuropática refratária, porém seus mecanismos de ação ainda são incertos. Sabendo que a ECM ativa a via analgésica descendente em ratos, fomos investigar o efeito da ECM sobre os núcleos serotonérgicos descendentes, dorsal da rafe (NDR) e magno da rafe (NMR) e sobre os neurônios da coluna posterior da medula espinhal (CPME). Ratos Wistar, submetidos à ECM, foram avaliados no teste de pressão da pata e seus tecidos foram avaliados frente à imunorreatividade (IR) para Egr-1 (marcador de ativação neuronal), serotonina (5HT) e substância P (SP). A ECM induziu antinocicepção em 62% nos animais, não alterou a ativação do NDR, entretanto ativou o NMR (67%), quando comparado com ratos não estimulados. A ECM aumentou a IR-5HT em 75% no NDR e em 92% no NMR. Na CPME, a ECM inibiu os neurônios nociceptivos (48%), porém não interferiu com a IR-SP. Estes resultados sugerem que a ECM induz analgesia, em parte, via ativação do sistema serotonérgico descendente. / Motor cortex stimulation (MCS) is effective in the treatment of refractory neuropathic pain; however, its mechanisms of action remain unclear. Since the MCS activates the descending pain pathway in rats, we investigated the MCS effect on the descending serotonergic nuclei, dorsal raphe nucleus (DRN) and the magnus raphe nucleus (MRN) and also on the neurons of the dorsal horn of the spinal cord (DHSC). Wistar rats, submitted to MCS, were evaluated by paw pressure test and its tissues were evaluated by immunoreactivity (IR) to Egr-1 (neuronal activation marker), serotonin (5HT) and substance P (SP). MCS induced antinociception by 62% in animals, although did not modify the NDR activation; however, activated the MRN (67%), when compared to control groups. MCS increased the IR-5HT by 75% in the NDR and 92% in the MRN. In the DHSC, MCS inhibited the nociceptive neurons (48%), however did not change the IR-SP. These results suggest that MCS induce antinociception, partly, by the descending serotonergic pathway activation.
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Recovery of function after lesions of the anterior thalamic nuclei: CA1 neuromorphologyHarland, Bruce January 2013 (has links)
The anterior thalamic nuclei (ATN) are a critical part of an extended hippocampal system that supports key elements of episodic memory. Damage or disconnection of the ATN is a component of clinical conditions associated with severe anterograde amnesisa such as the Korsakoff’s syndrome, thalamic stroke, and neurodegenerative disorders. Previous studies have demonstrated that the ATN and hippocampus are often interdependent, and that ATN damage can result in ‘covert pathology’ in ostensibly healthy distal regions of the extended hippocampal system. Adult male rats with neurotoxic bilateral ATN lesions or sham surgery were post-operatively housed in an enriched environment or standard housing after a lesion-induced spatial working memory deficit had been established. These rats were retested on cross-maze and then trained in radial-arm maze spatial memory tasks. Other enriched rats received pseudo-training only after the enrichment period. The detailed neuromorphology of neurons was subsequently examined in the hippocampal CA1. Soma characteristics were also examined in the retrosplenial granular b cortex and the prelimbic cortex. In Experiment 1, ATN lesions produced clear deficits in both the cross-maze and radial-arm maze tasks and reduced hippocampal CA1 dendritic complexity, length, and spine density, while increasing the average diameter of the dendrites. Post-operative enrichment reversed the ATN lesion-induced deficits in the cross-maze and radial-arm maze, and returned CA1 basal and apical spine density to a level comparable to that of sham standard housed trained rats. The sham enriched rats exhibited improved radial-arm maze performance and increased CA1 branching complexity and spine density in both basal and apical arbors compared to sham standard housed rats. The neuromorphological changes observed in the enriched ATN and sham rats may be in part responsible for the spatial working memory improvements observed. Experiment 2 provided support for this contention by demonstrating that the CA1 spine changes were explicitly relevant to spatial learning and memory, because trained enriched sham and ATN rats had increased spines, particularly in the basal tree when compared to closely comparable pseudo-trained enriched rats. Interestingly, spatial memory training increased the numbers of both thin and mushroom spines, whereas enrichment was only associated with an increase in thin spines. In Experiment 3, ATN lesions increased cell body size in layer II of the retrosplenial granular b cortex, whereas enrichment decreased cell body size in layer V of this region. Neither ATN lesions nor enrichment had any effect on cell body morphology in the prelimbic cortex. The current research provides some of the strongest evidence to date of ATN and hippocampal interdependence within the extended hippocampal system, and provides the first evidence of neuromorphological correlates of recovery after ATN lesions.
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The thalamus in Parkinson's disease: a multimodal investigation of thalamic involvement in cognitive impairmentBorlase, Nadia Miree January 2013 (has links)
Parkinson’s disease patients present with the highest risk of dementia development. The thalamus, integral to several functions and behaviours is involved in the pathophysiology of Parkinson’s disease. The aim of this thesis was to determine if anatomical abnormalities in the thalamus are associated with the development of dementia in Parkinson’s disease.
We examined the thalamus using macro and microstructural techniques and the white matter pathways that connect the thalamus with areas of the surrounding cortex using diffusion tensor imaging (DTI) based tractography. T1-weighted magnetic resonance and DT images were collected in 56 Parkinson’s disease patients with no cognitive impairment, 19 patients with mild cognitive impairment, 17 patients with dementia and 25 healthy individuals who acted as control subjects. An established automated segmentation procedure (FIRST FSL) was used to delineate the thalamus and a modified k-means clustering algorithm applied to segment the thalamus into clusters assumed to represent thalamic nuclei. Fibre tracts were determined using DTI probabilistic tracking methods available in FIRST. Microstructural integrity was quantified by fractional anisotropy and mean diffusivity (MD) DTI measures.
Results show that microstructural measures of thalamic integrity are more sensitive to cognitive dysfunction in PD than macrostructural measures. For the first time we showed a progressive worsening of cellular integrity (MD) in the groups who had greater levels of cognitive dysfunction. Thalamic degeneration was regionally specific and most advanced in the limbic thalamic nuclei which influenced executive function and attention, areas of cognition that are known to be affected in the earliest stages of PD. The integrity of the fibre tracts corresponding to these thalamic regions was also compromised. Degeneration of fibre tracts was most evident in the dementia group, indicating that they may be more protected against Lewy pathology than the nuclei of the thalamus.
Our findings confirm previous histological, animal and lesion studies and provide a reliable estimate of cortical degeneration in PD that can be applied non-invasively and in vivo. A longitudinal study is needed to monitor the progression of cognitive decline in PD but we have provided the basis for further investigation into the predictive validity of thalamic degeneration for cognitive dysfunction. In the future, the microstructural changes of the thalamus could be used as biomarkers for the identification of individuals with a higher risk for dementia development and for the longitudinal monitoring of any interventions into cognitive decline.
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Implication de l'hippocampe ventral et des noyaux reuniens et rhomboïde du thalamus dans les processus cognitifs sous-tendant la mémoire spatiale chez le Rat / lnvolvement of the ventral hippocampus and reuniens and rhomboid thalamic nuclei in cognitive processes underlying spatial memory in ratsLoureiro, Michaël 30 November 2012 (has links)
Ce travail de thèse avait pour objectif d’étudier le rôle de l’hippocampe (HPC) ventral et des noyaux reuniens (Re) et rhomboïde (Rh) du thalamus dans les processus cognitifs qui sous-tendent la mémoire spatiale chez le Rat. Par l’utilisation d’approches complémentaires combinant l’imagerie cérébrale, la lésion excitotoxique, l’inactivation fonctionnelle réversible et des évaluations comportementales, nos résultats ont mis en évidence : (1) l’implication spécifique de l’HPC ventral uniquement dans le rappel d’informations spatiales ; (2) un rôle-clé des noyaux Re et Rh dans la persistance d’un souvenir spatial ; (3) l’implication des noyaux Re et Rh dans le labyrinthe du double-H, un nouveau test nécessitant d’une part, l’utilisation d’informations spatiales dépendant de l’intégrité de l’HPC dorsal, et d’autre part, une flexibilité comportementale, impliquant le cortex préfrontal médian. Ainsi, l’ensemble de ces résultats permet de proposer l’existence d’un circuit HPC-préfronto-thalamique impliqué dans divers aspects du traitement des informations spatiales. / The main objective of this thesis was to investigate the role of the ventral hippocampus (HPC) and the reuniens (Re) and rhomboid (Rh) thalamic nuclei in the cognitive processes underlying spatial memory in the Rat. If our results first confirmed, in the Morris water maze, the role of the dorsal HPC in the acquisition and retrieval of a spatial reference memory, we demonstrated the specific involvement of the ventral HPC only in the recall of spatial information. In addition, by using complementary approaches combining brain imaging, excitotoxic lesion and reversible functional inactivation, we were able to show for the first time a key role for the Re and Rh in the persistence of a spatial memory (25 days). Finally, the third set of experiments has highlighted the involvement of the Re and Rh in a mnemonic task performed in a new test, the double-H maze, which requires the use of spatial information depending on the integrity of the dorsal HPC, and a behavioral flexibility, involving the medial prefrontal cortex. Thus, taken together, these results suggest the involvement of a HPC-prefronto-thalamic network in various aspects of spatial information processing.
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