Motor unit recruitment by intraspinal microstimulation and long-term neuromuscular adaptations

Bamford, Jeremy Andrew.

January 2009

Thesis (Ph.D.)--University of Alberta, 2009. / A thesis submitted to the Faculty of Graduate Studies and Research in partial fulfillment of the requirements for the degree of Doctor of Philosophy, Centre for Neuroscience. Title from pdf file main screen (viewed on October 11, 2009). Includes bibliographical references.

The impact of type II diabetes on behavioral and cellular aspects of neuroplasticity /

Georgescu, Tania.

January 1900

Thesis (M.Sc.) - Carleton University, 2007. / Includes bibliographical references (p. 81-88). Also available in electronic format on the Internet.

Mechanism of centaurin-alpha-1 control of neuronal differentiation

Hill, Donna Monique.

January 2010

Thesis (M.S.)--University of Alabama at Birmingham, 2009. / Title from PDF t.p. (viewed June 30, 2010). Additional advisors: Lori McMahon, Stephen Watts. Includes bibliographical references (p. 31-35).

Seasonal plasticity of physiological systems, brain, and behavior

Pyter, Leah M,

January 2006

Thesis (Ph. D.)--Ohio State University, 2006. / Title from first page of PDF file. Includes bibliographical references (p. 198-229).

Signaling events in activity dependent neuroprotection, neurodegeneration, and synaptic plasticity

Lee, Bo Young.

January 2007

Thesis (Ph. D.)--Ohio State University, 2007. / Title from first page of PDF file. Includes bibliographical references (p. 130-169).

Bases moléculaires et cellulaires des effets antidépresseurs de l'électro-convulsivothérapie (ECT) / Molecular and cellular bases for antidepressant effects of electro-convulsivo-therapy (ECT).

Jonckheere Ruiz de Larrinaga, Julie

10 February 2017

L'électroconvulsivothérapie (ECT) est une réponse thérapeutique reconnue comme efficace face à la résistance et au délai d'action des agents pharmacologiques, pour les épisodes dépressifs majeurs. Bien que l'efficacité thérapeutique des ECT soit reconnue de tous, la connaissance incomplète des effets biologiques qui sous tendent l'effet thérapeutique contribue à discréditer ce soin. Les marqueurs biologiques ne sont pas facilement accessible chez l’Homme, il a donc été développé chez les rongeurs, l’équivalent des ECT : les stimulations électro-convulsives (ECS). A ce jour, les divers résultats provenant des études chez les animaux n’ont permis d’obtenir des conclusions claires, et ceci est majoritairement dû à l’utilisation d’animaux naïfs. Dans ce contexte, l'objectif du projet de thèse était d'analyser les effets biologiques et comportementaux des ECS répétées, modèle de l'électro convulsivothérapie, sur un modèle animal de troubles psychiatriques : la souris MAP6 KO. En effet, ces souris expriment constitutivement des altérations biologiques et comportementales assimilées à certains symptômes de la dépression. Nous avons montré qu’un traitement par ECS améliore certaines des altérations comportementales des souris MAP6 KO, avec un maintien dans le temps différent selon le comportement analysé. Au niveau biologique, le traitement par ECS n’induit pas de modification détectable de l’expression des protéines dans le cerveau, mais induit une augmentation de la neurogénèse adulte hippocampal, et plus particulièrement une augmentation du taux d'intégration des neurones néoformés. L'augmentation du nombre de nouveaux neurones survivants pourrait être favorisée par l’augmentation de la complexité de l’arborisation dendritique et de la densité synaptique. De plus nous observons une augmentation de la densité des épines dendritiques dans les neurones corticaux et une augmentation de l’expression du BDNF dans l’hippocampe. En conclusion, le projet de thèse montre que les ECS appliquées aux souris MAP6 KO-ont un effet important au niveau de la plasticité cérébrale et plus particulièrement au niveau de l’intégration des nouveaux neurones issus de la neurogénèse adulte hippocampique. / In Major depressive disorder, the electroconvulsive therapy (ECT) is recognized as an effective treatment to face drug-resistance and action latency of pharmacological agents. Although the therapeutic efficacy of ECT is internationally recognized, the ill-characterized biological effects of ECT contribute to discredit this treatment. Direct access of specific markers in human is not easy, prompting the development of the animal counterpart of ECT, the electro convulsive stimulations (ECS). To date, current results arising from ECS studies in animals remain not fully conclusive because mainly data have been obtained with unchallenged/naive animals. The objective of this project was to analyze the biological and behavioral effects of ECS treatment, on an animal model of psychiatric disorder: the MAP6-KO mice. Indeed MAP6-KO mice (also known as STOP KO mice) constitutively exhibit behavioural and biological features relevant to some aspects of major depressive disorder. We found that ECS treatment has an overall beneficial effect on several constitutive behavioural defects, displayed by MAP6 KO mice, with variable lasting times. At biological levels, ECS treatment did not induce detectable modification of brain proteins expression pattern, but induce an overall increase of hippocampal neurogenesis, and more particularly potentiate the survival rate of newborn neurons, probably through an increase dendritic complexity and dendritic spines density. We also found that ECS enhance dendritic spines density in vivo in cortical neurons and increase hippocampal levels of the trophic factor, BDNF. In summary our work provide evidence that ECS treatment when applied to MAP6 KO mice induces major neuronal plasticity events, the stronger being the increased integration rate of hippocampal new-born neurons.

Ecs

Souris KO-MAP6

Depression

Neuroplasticité

Ecs

MAP6-KO mice

Depression

Neuroplasticity

570

610

Expressão da proteína prion celular no modelo da pilocarpina de epilepsia do lobo temporal

Rockenbach, Isabel Cristina

January 2010

Ratos que não expressam a proteína prion celular (PrPc) são mais sensíveis a crises epilépticas induzidas por diferentes protocolos. O hipocampo desses animais apresenta um brotamento supragranular de fibras musgosas semelhante ao observado em pacientes com epilepsia de lobo temporal relacionada a esclerose hipocampal (ELT-EH). Esses achados sugerem que a PrPc pode estar envolvida na epileptogênese da ELT-EH. Nós estudamos nessa tese a localização imunoistoquímica da PrPc no hipocampo de animais submetidos ao modelo de epilepsia de lobo temporal por pilocarpina (MELTP)em diferentes tempos de status epilepticus em ratos. Nesse trabalho induzimos estado de mal epileptico (EE) com o uso de pilocarpina em três diferentes grupos de ratos Wistar adultos. Os animais foram sacrificados 18 horas, 5 dias e 2 meses após a indução do EE. Os resultados foram comparados com cérebros controles de ratos que receberam injeções de solução salina. As lâminas foram processadas para coloração por hematoxilinaeosina, imunohistoquímica e neo-Timm. Observamos um aumento da expressão de PrPc nas regiões CA1 e CA3 do hipocampo 18 horas depois da injeção de pilocarpina. Essa expressão aumentada persistiu na região CA1 no quinto dia após a injeção. Não observamos diferenças significativas na expressão de PrPc durante a fase aguda do MELTP nas regiões CA2 e granular do hipocampo. No grupo crônico (2 meses) a PrPc foi observada na mesma localização em que se observou brotamento de fibras musgosas. Concluímos com esse trabalho que a expressão da PrPc é diferente nas diversas fases do modelo de epilepsia induzido por pilocarpina. A expressão transitória da proteína prion durante a fase aguda do modelo pode refletir mudanças de expressão visando tornar as células mais resistentes ao dano induzido pelas crises convulsivas. Alternativamente, essa expressão aumentada pode estar relacionadas à apotose ou então às fases iniciais da neuroplasticidade. A expressão de PrPc na mesma região dos brotamentos de fibras musgosas na fase crônica pode estar relacionada à neuroplasticidade, epileptogênese, neurotransmissão ou, ainda, estar implicada na proteção celular contra crises convulsivas recorrentes. Devido aos diversos achados relacionados a PrPc, sugerimos que o modelo de epilepsia do lobo temporal induzido pela pilocarpina possa ser um interessante modelo para o estudo do papel fisiológico da PrPc. / Mice lacking cellular prion protein (PrPc) are more sensitive to seizures induced by four different pharmacological protocols. The hippocampal formation of these animals exhibits supragranular mossy fiber sprouting which resembles that observed in patients with mesial temporal lobe epilepsy related to hippocampal sclerosis (MTLEHS). These findings suggest that the PrPc may be involved in epileptogenesis in MTLE-HS. Here we investigated the immunohistochemical localization of the PrPc in the hippocampus of animals submitted to the pilocarpine model of temporal lobe epilepsy (PMTLE). Status epilepticus (SE) was induced with pilocarpine in three different groups of adult Wistar rats. The animals were sacrificed 18 hours, 5 days, and 2 months after SE induction and the results were compared to the respective saline-injected control animals. Slices were processed for hematoxylin-eosin, PrPc immunohistochemistry and neo-Timm .PrPc was increased in the CA1 and in CA3 regions of the hippocampus 18 hours after pilocarpine injection. PrPc continued to be increased in the CA1 region of the hippocampus five days after pilocarpine injection. In the CA2 and granular regions of the hippocampus we did not observe significant differences in PrPc expression during the acute phase of PMTLE. In the chronic group, PrPc was expressed co-localized with mossy fiber sprouting. Cellular prion protein is differentially expressed at different phases of the pilocarpine model of epilepsy. Transient expression of PrPc during the acute phase of the pilocarpine model may reflect changes which may render cells more resistant to seizure-induced damage and may be related to apoptosis or may to the initial phases of neuroplasticity. During the chronic period, PrPc is co-expressed in the same regions of mossy fiber sprouting. In chronic animals, PrPc might be related to neuroplasticity, epileptogenic processes, neurotransmission, or alternatively may be implicated in cellular protection against recurrent seizures.

Prions

Pilocarpina

Epilepsia do lobo temporal

Modelos animais

Ratos Wistar

Prion

Epilepsy

Neuroplasticity

Isolamento social precoce e consumo de uma dieta hiperlipídica : implicações no comportamento do tipo depressivo e em aspectos cognitivos em ratos adultos

Arcego, Danusa Mar

January 2017

Intervenções ambientais, como a exposição precoce a estressores ou a dietas ricas em calorias, podem alterar a trajetória da maturação neural e influenciar na susceptibilidade a certas patologias a longo-prazo. Neste contexto, o objetivo do presente estudo foi investigar os efeitos de uma exposição ao isolamento social durante o período pré-pubere associado ou não ao consumo precoce e crônico de uma dieta hiperlipídica (HFD) sobre aspectos cognitivos e emocionais, e possíveis mecanismos neuroquímicos associados a essas alterações, no hipocampo, no córtex pré-frontal e no núcleo accumbens de ratos machos na idade adulta. Os resultados mostraram que os dois fatores, estresse e dieta (separadamente), induziram um comportamento do tipo depressivo nos animais na idade adulta. Além disso, os animais isolados apresentaram um déficit cognitivo associado à memória de curta-duração e de trabalho, enquanto que animais com acesso à HFD demonstraram prejuízo somente na memória de curta-duração. Curiosamente, a interação entre os fatores (estresse e dieta) causou uma reversão dos déficits na memória de curta-duração. Em relação às avaliações do comportamento alimentar hedônico, observamos que o grupo com consumo crônico de HFD apresentou uma menor motivação para obter diferentes tipos de alimentos palatáveis doces. Essa redução motivacional não parece ser associada a uma menor palatabilidade e/ou a uma maior saciedade induzida pela HFD. Em relação aos marcadores de plasticidade analisados no córtex pré-frontal, observamos interações entre os fatores estresse e dieta na atividade da enzima Na+K+-ATPase, nos níveis de BNDF e no imunoconteúdo das proteínas AKT e MAPK/ERK, sendo que os fatores quando aplicados isolados diminuem os níveis dos parâmetros analisados, porém quando associados, os níveis retornam ou aumentam em relação aos valores do grupo controle. O hipocampo foi a estrutura mais afetada pelas intervenções ambientais neste trabalho. Observamos que tanto o estresse, como a dieta hiperlipídica (separadamente) causaram uma redução da plasticidade sináptica hipocampal, por meio de diferentes mecanismos: o acesso crônico à HFD afeta proteínas relacionadas ao funcionamento das sinapses, enquanto o isolamento social parece afetar mais particularmente a via de sinalização do BDNF. Com relação aos achados neuroquímicos no núcleo accumbens, observamos uma redução dos receptores dopaminérgico-1 (D1) e canabinóide-1 (CB1) com o consumo de HFD, enquanto que os animais isolados na pré-puberdade apresentaram uma redução do metabolismo dopaminérgico nesta estrutura. Em suma, esta tese demonstra que tanto o isolamento social e como o consumo contínuo de HFD causam comportamento do tipo depressivo e outras alterações comportamentais, e reduzem marcadores de plasticidade importantes no córtex prefrontal e hipocampo. O acesso à HFD também causa uma menor motivação para o comportamento alimentar hedônico. Assim, tais eventos precoces podem afetar a plasticidade neural levando a importantes alterações comportamentais, e assim predispor a diferentes patologias durante a vida. / Environmental interventions, such as early exposure to stressors or high calorie-diets, can alter the trajectory of neural maturation and influence the susceptibility to some pathologies throughout life. In this context, the aim of the present study was to investigate the effects of exposure to social isolation, during the pre-pubertal period, associated or not with early and chronic consumption of a hyperlipid diet (HFD) on cognitive and emotional aspects, and possible mechanisms associated with these changes, in the hippocampus, the prefrontal cortex and the nucleus accumbens of male rats in adulthood. The results showed that both pre-pubertal social isolation and chronic access to a hyperlipidic diet induced a depressive-like behavior in animals during adulthood. In addition, isolated animals had a cognitive deficit associated with short-term and working memory, whereas animals with access to HFD demonstrated impairment only in short-term memory. Interestingly, the interaction between the factors (stress and diet) caused a reversal in relation to short-term memory, remaining similar to the control group. Regarding the evaluations of the hedonic eating behavior, we observed that HFD group presented a lower motivation to obtain different sweet palatable foods. This impaired motivation does not appear to be associated with less palatability and/or satiety induced by the high-fat diet. Concerning plasticity markers in the prefrontal cortex, we observed interactions between stress and diet on Na+ K+-ATPase activity, BNDF levels and AKT and MAPK/ERK immunocontents. These interactions follow a similar profile: when applied alone, the levels of the analyzed parameters decrease, but when associated, the levels return or increase in relation to the values of the control group. The hippocampus was the structure most affected by the environmental interventions. Both stress and HFD caused a reduction of hippocampal synaptic plasticity through different mechanisms: chronic access to HFD affects proteins related to synaptic function, while social isolation affects the BDNF signaling pathway more significantly. Regarding the neurochemical findings in the nucleus accumbens, we observed a reduction in dopaminergic-1 (D1) and cannabinoid-1 (CB1) receptors with chronic HFD intake, whereas isolated animals had a reduction of dopaminergic metabolism in this same structure. In summary, this thesis shows that both social isolation and chronic consumption of HFD lead to depressive-like behavior and to other behavioral changes; they reduce plasticity markers in prefrontal cortex and hippocampus. HFD access also induced a lower motivation for hedonic feeding. Therefore, these early interventions may affect neural plasticity, leading to important behavioral changes, and thus, predispose to different pathologies later in life.

Isolamento social

Dieta hiperlipidica

Estresse

Depressão

Plasticidade neuronal

Neuroplasticity

High fat diet

Stress

Depression

Characterization of Spontaneous Motor Recovery and Changes in Plasticity-Limiting Perineuronal Nets Following Cortical and Subcortical Stroke

Karthikeyan, Sai Sudarshan

January 2017

Stroke is a leading cause of neurological disability, often resulting in long-term motor impairments due to damage to the striatum and/or motor cortex. While both humans and animals show spontaneous recovery following stroke, little is known about how the injury location affects recovery and what causes recovery to plateau. This information is essential in order to improve current rehabilitation practice and develop new therapies to enhance recovery. In this thesis, we used endothelin-1 (ET-1), a potent vasoconstrictor, to produce focal infarcts in the forelimb motor cortex (FMC), the dorsolateral striatum (DLS) or both the FMC and DLS in male Sprague-Dawley rats. In the first experiment, the spontaneous recovery profile of animals was followed over an 8-week period using multiple behavioural tasks assessing motor function and limb preference to identify how recovery varies depending on injury location. Infarct volumes were measured to determine the association between injury and behavioural outcome. All three groups had significant functional impairments on the Montoya staircase, beam traversal, and cylinder tests following stroke, with the combined group having the largest and most persistent impairments. Importantly, spontaneous recovery was not simply dependent on lesion volume but on the lesion location and the behavioural test employed. In the second experiment, we focused on a potential cellular mechanism thought to underlie post-stroke plasticity and functional recovery. In a separate cohort of animals, we assessed how plasticity-limiting perineuronal nets (PNNs) and associated parvalbumin-positive (PV) GABAergic interneurons change following similar ET-1 strokes as in the prior experiment. A significant reduction in the density of PNNs was observed in the perilesional cortex of animals that received a cortical-only or combined stroke but not a striatal-only injury. Although there were no significant differences in the density of PV interneurons between sham and stroked groups, a significant negative correlation existed between cortical infarct volume and the density of PV interneurons in the perilesional cortex. Taken together these results demonstrate that lesion location influences motor recovery and neuroplastic changes following stroke. This supports the idea that a “one size fits all” approach for stroke rehabilitation may not be effective and treatment needs to be individualized to the patient.

Stroke Recovery

Neuroplasticity

Cortex

Striatum

Focal Ischemia

Animal Models

Perineuronal Nets

Parvalbumin

A phase II randomised controlled trial of amiloride as a neuroprotective treatment in optic neuritis : studying in vivo neurodegeneration, neuroprotection and cortical plasticity after an inflammatory insult to the visual system

McKee, Justin

January 2017

Basic science and early clinical trial evidence suggest the safe diuretic drug amiloride, may exert a neuroprotective effect in multiple sclerosis (MS) through blockade of the acid sensing ion channel. Neuroprotective treatments are a key unmet need in multiple sclerosis. Optic neuritis (ON) is a discrete CNS inflammatory event leading to neuro-axonal injury in the optic nerve and retina. The optic nerve is part of the visual system, one of the most functionally and structurally eloquent systems in the central nervous system, which affords a number of unique modalities to assess neurodegeneration and neuroprotection. The visual system can be classified into two parts, the anterior and posterior visual systems, which are defined by the lateral geniculate nucleus, where the two components synapse. The extent of neurodegeneration following ON in the anterior visual system can be imaged in vivo through scanning laser polarimetry (GDx) and optical coherence tomography (OCT). The posterior visual system can be imaged by quantitative and functional magnetic resonance imaging (MRI) of the brain, giving insights into white matter structural integrity and cortical plasticity over time. Combining these modalities in a longitudinal study, allows assessment of the impact of neurodegeneration in the anterior visual system on neurodegeneration downstream in the posterior visual system and on changes in functional connectivity over time in the visual cortex. Furthermore, in the clinical trial setting the neuroprotective effect of any intervention both on direct anterior neurodegeneration and downstream processes can be assessed. The functional relevance of changes in all of these biomarkers can be tested through a number of visual measures, including low contrast visual acuity. In MS, the contribution of transsynaptic neurodegeneration to the global neuronal loss experienced by patients is an area of incomplete understanding. In addition, the role of the visual cortex, through neuroplasticity, in aiding visual recovery from optic neuritis, is unclear. To address these issues, this thesis reports the results of the first clinical trial of amiloride in ON, and shows that despite the pre- and early clinical evidence of neuroprotection of amiloride, no neuroprotective benefit was found. It goes on to explore reasons for this lack of effect including the finding of early retinal neurodegeneration in ON, and the need for early recruitment windows in the future. From there, it makes a detailed assessment of the longitudinal changes in retinal OCT for 12 months following ON, including a novel finding of the temporal evolution of inner nuclear layer swelling, previously reported only cross-sectionally. Next, for the first time macular retinal neurodegeneration is shown to influence diffusion tensor MRI derived measures of white matter integrity in the optic radiations, indicating transsynaptic neurodegeneration. Finally, longitudinal changes in resting state functional connectivity following ON are found in the visual system for the first time. The interaction between this cortical functional, retinal neurodegeneration and visual recovery is probed.