Global ETD Search

61	Visual learning deficits after cerebellar damage in rats. Buchtel, Henry A., (Henry Augustus) January 1969 (has links) No description available. Perceptual learning. Cerebellum -- Physiology. Rats -- Physiology.
62	GABA(A) receptor subunit expression and assembly in rat cerebellar neurons Nadler, Laurie Sue January 1996 (has links) No description available. Biology, Neuroscience Cerebellum Neurons Receptors, GABA-A
63	Gene expression in the mouse cerebellar cortex Popesco, Magdalena C. 04 February 2004 (has links) No description available. Biology, Neuroscience Gene expression mouse cerebellum
64	Phenotype analysis of Pdss2 conditional knockout mouse Lu, Song, 鲁嵩 January 2010 (has links) published_or_final_version / Biochemistry / Doctoral / Doctor of Philosophy Cerebellum - Diseases - Genetic aspects. Cerebellum - Diseases - Animal models. Ubiquinones. Transgenic mice - Genetics.
65	General principles of cerebellar organization : correlating anatomy, physiology and biochemistry in the pigeon vestibulocerebellum Pakan, Janelle. January 2009 (has links) 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 August 25, 2009). Includes bibliographical references.
66	Cerebellar disease in the Arabian horse Beatty, Margaret Turner. January 1984 (has links) Call number: LD2668 .T4 1984 B423 / Master of Science / Diagnostic Medicine/Pathobiology Cerebellum--Diseases. Masters theses
67	The contribution of cerebellar inputs to the properties of otolith neurons in the vestibular nucleus of rats Jiang, Bin, 姜斌 January 1999 (has links) published_or_final_version / Physiology / Doctoral / Doctor of Philosophy Olivary nucleus. Cerebellum. Otoliths. Vestibular nuclei. Rats - Physiology.
68	Protein Kinase Mzeta (PKM-ζ) Regulates Kv1.2 Dependent Cerebellar Eyeblink Classical Conditioning Chihabi, Kutibh 01 January 2017 (has links) Learning and memory has been a topic that has captured the attention of the scientific and public communities since the dawn of scientific discovery. Without the faculty of memory, mammals cannot experience nor function in the world; among homosapiens specifically, language, relationships, and personal identity cannot be developed (Eysenck, 2012). After all, some philosophers such as John Locke argued we are nothing but a collection of past memories in which we have developed and improved upon (Nimbalkar, 2011). Understanding the cellular mechanisms behind learning, and the subsequent formation of memory, has been a topic that has garnered scientific interest for many decades. One particular kinase that has been at the center of attention in the last decade is the serine/threonine kinase PKM-ζ, an N-terminal truncated form of PKC-ζ that renders it constitutively active (Hernandez et al., 2003). PKM-ζ has long been implicated in a cellular correlate of learning, long-term potentiation (LTP). Inhibition of PKM-ζ with Zeta-inhibitory peptide (ZIP) has been shown in many brain structures to disrupt maintenance of AMPA receptors, irreversibly disrupting numerous forms of learning and memory that have been maintained for weeks. The voltage-gated potassium channel Kv1.2 is a critical modulator of neuronal physiology, including dendritic excitability, action potential propagation, and neurotransmitter release. While expressed in various mammalian tissues, Kv1.2 is most prevalent in the cerebellum where it modulates both dendritic excitability of Purkinje cells (PCs) and basket cell (BC) inhibitory input to PCs. Because PCs are the main computational unit of the cerebellar cortex and provide its sole output (Napper et al., 1988; Harvey et al., 1991), regulation of synaptic Kv1.2 is predicted to have a major role in cerebellar function. Pharmacological inhibition of Kv1.2 in cerebellar PC dendrites increases excitability (Khavandgar et al., 2005), while its inhibition in BC axon terminals increases inhibition to PCs (Southan & Robertson, 1998). Interestingly, two prior studies have demonstrated that PKC-ζ, an atypical Protein Kinase C, is able to phosphorylate and bind cerebellar Kvβ2, a Kv1.2 auxiliary subunit. (Gong et al., 1999; Croci et al., 2003). Delay eyeblink conditioning (EBC) is an established model for the assessment of cerebellar learning. Despite being highly expressed in the cerebellum, no studies have examined how regulation of cerebellar PKM-ζ may affect cerebellar-dependent learning and memory nor have they examined the possible effect PKM-ζ may have on Kv1.2. The goal of this dissertation was to determine whether PKM-ζ could modulate EBC in a Kv1.2 dependent manner. Through the use of microscopy techniques we have shown that PKM-ζ is highly expressed in the cerebellar cortex, primarily in the PC, and by the use of pharmacological manipulations, it was found that PKM-ζ has an important role in regulating the acquisition of EBC. Through the use of biotinylation, flow cytometry, and behavioral manipulations, it was determined that PKM-ζ regulates Kv1.2 during eyeblink conditioning. These studies provided the first evidence that PKM-ζ has a role for learning and memory in the cerebellum, and the first evidence of PKM-ζ regulating a voltage-gated ion channel rather than a ligand-gated ion channel such as AMPA receptors. Cerebellum Kv1.2 Learning Memory PKC PKM-Zeta Neuroscience and Neurobiology Psychology
69	Expression of interleukin-6 (IL-6) in the cerebellum is not altered in the absence of Fragile X Mental Retardation Protein (FMRP) or with motor skill learning Tabatabaei, Dina 06 September 2016 (has links) The ability of the brain to change structurally and functionally with experience is called brain plasticity. High levels of pro-inflammatory cytokines impair normal memory formation and consolidation. To better understand the role of pro-inflammatory cytokines in learning, the contribution of the cytokine interleukin-6 (IL-6) to a motor skill learning task investigated. The Fmr1 Knockout (KO) mouse, an animal model of Fragile X Syndrome, has demonstrated impaired neural plasticity and learning. Fmr1 KO and control wild-type (WT) mice were trained on the dowel and flat beam runways to study motor skill learning and motor activity respectively. The cerebellum from the animals was examined for IL-6 protein using ELISA. No significant differences in the levels of IL-6 in the cerebellum of the Fmr1 KO and WT normal mice were found. The expression of IL-6 was not altered by the behavioural training. These results suggest lack of association between IL-6, and FMRP and motor skill learning. / October 2016
70	Analysis of Purkinje Cell Responses in the Oculomotor Vermis during the Execution of Smooth Pursuit Eye Movements Raghavan, Ramanujan Tens January 2016 (has links) <p>Smooth pursuit eye movements are movements of the eyes that are used to foveate moving objects. Their precision and adaptation is believed to depend on a constellation of sites across the cerebellum, but only one region’s contribution is well characterized, the floccular complex. Here, I characterize the response properties of neurons in the oculomotor vermis, another major division of the oculomotor cerebellum whose role in pursuit remains unknown. I recorded Purkinje cells, the output neurons of this region, in two monkeys as they executed pursuit eye movements in response to step ramp target motion. The responses of these Purkinje cells in the oculomotor vermis were very different from responses that have been documented in the floccular complex. The simple spikes of these cells encoded movement direction in retinal, as opposed to muscle coordinates. They were less related to movement kinematics, and had smaller values of trial-by-trial correlations with pursuit speed, latency, and direction than their floccular complex counterparts. Unlike Purkinje cells in the floccular complex, simple spike firing rates in the oculomotor vermis remained unchanged over the course of pursuit adaptation, likely excluding the oculomotor vermis as a site of directional plasticity. Complex spikes of these Purkinje cells were only partially responsive to target motion, and did not fall into any clear opponent directional organization with simple spikes, as has been found in the floccular complex. In general, Purkinje cells in the oculomotor vermis were responsive to both pursuit and to saccadic eye movements, but maintained tuning for the direction of these movements along separate directions at a population level. Predictions of caudal fastigial nucleus activity, generated on the basis of our population of oculomotor vermal Purkinje cells, faithfully tracked moment-by-movement changes in pursuit kinematics. By contrast, these responses did not faithfully track moment-by-moments changes in saccade kinematics. These results suggest that the oculomotor vermis is likely to play a smaller role in influencing pursuit eye movements by comparison to the floccular complex.</p> / Dissertation Neurosciences Psychobiology Cerebellum Oculomotor Vermis Primate Smooth Pursuit

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