Global ETD Search

861	Efecto de la hipertensión ocular en la población de células ganglionares de la retina de rata y ratón Salinas Navarro, Manuel Ángel 11 March 2011 (has links) En esta tesis estudiamos la población total de las células ganglionares de la retina (CGR) en rata y ratón, y desarrollamos un modelo experimental de hipertensión ocular mediante fotocoagulación láser. La población de CGR proyecta masivamente a los colículos superiores. Se observa una estría visual en la retina dorsal donde se encuentra las densidades más altas de CGR. La pequeña población de CGR ipsilateral se distribuye mayoritariamente en la periferia de la retina temporal. El aumento de la presión intraocular induce una compresión de los axones en la cabeza del nervio óptico que provoca una alteración del transporte axonal retrógrado, que induce una degeneración sectorial localizada y difusa de las CGR, preferentemente en la retina dorsal, así como de sus axones. La pérdida selectiva de las CGR en la capa de CGR, sugiere que la causa de la muerte de las CGR no se debe a una isquemia retiniana. / In this thesis we have studied the total population of retinal ganglion cells (RGCs) in rat and mouse, and developed an experimental model of ocular hypertension by laser photocoagulation. The RGC population projects massively to the superior colliculi. There is a visual streak in the dorsal retina where the highest densities of RGCs are found. The small population of ipsilateral RGCs is distributed mainly in the periphery of the temporal retina. The increase of intraocular pressure induces a compression of the axons at the optic nerve head that causes a disturbed retrograde axonal transport, inducing a localized, diffuse and sectorial degeneration of RGCs and their axons, preferably in the dorsal retina. The selective loss of RGCs in the RGC layer, suggests that the cause of the RGC loss is not due to retinal ischemia. Células ganglionares de la retina retinal ganglion cells fotocoagulación láser laser photocoagulation Hipertensión ocular ocular hypertension Glaucoma nervio óptico optic nerve neurodegeneración neurodegeneration Ciencias de la visión 616.8
862	Analyse génétique de la fonction du gène Polycomb Bmi1 dans le développement et la survie des photorécepteurs chez la souris. Plamondon, Vicky 04 1900 (has links) La rétine est constituée de plusieurs types de neurones incluant les cellules amacrines, ganglionnaires, bipolaires et les photorécepteurs. Les photorécepteurs, qui englobent les cônes et les bâtonnets, sont des neurones sensoriels hautement spécialisés qui permettent la conversion de la lumière en signaux électriques par le mécanisme de phototransduction. Les mécanismes moléculaires par lesquels les progéniteurs rétiniens (RPCs) se différencient en différents neurones spécialisés comme les photorécepteurs sont encore peu connus. Le gène Polycomb Bmi1 appartient à la famille des gènes Polycomb qui forment des complexes multimériques impliqués dans la répression de l’expression génique via le remodelage de la chromatine. Au niveau biologique, le gène Bmi1 régule, entre autre, le contrôle de la prolifération cellulaire, le métabolisme des radicaux libres, et la réparation de l’ADN. Récemment, il a été démontré que Bmi1 joue un rôle critique dans la prolifération et l’auto-renouvellement d’un groupe de RPCs immatures. De plus, Bmi1 est essentiel au développement post-natal de la rétine. L'objectif de cette étude est d'analyser le rôle de Bmi1 dans le développement et la survie des photorécepteurs chez la souris. Nos résultats révèlent un phénotype de dégénérescence des photorécepteurs de types cônes chez notre modèle de souris déficiente pour Bmi1. Les bâtonnets sont insensibles à la mutation. De plus, Bmi1 est exprimé de façon prédominante dans les cônes. Nos expériences de culture de cellules rétiniennes suggèrent que le phénotype est cellule-autonome. Par ailleurs, la co-délétion du gène Chk2, membre de la réponse aux dommages à l'ADN, permet de ralentir la progression du phénotype. Les rétines Bmi1-/- et Bmi1-/-Chk2-/- présentent une augmentation importante des dommages oxydatifs à l'ADN. Ces résultats suggèrent que le stress oxydatif pourrait jouer un rôle important dans la survie des cônes. L'étude du rôle du gène Polycomb Bmi1 dans les photorécepteurs est importante pour une meilleure compréhension des mécanismes contribuant à la survie des cônes et pourrait mener à la découverte de nouveaux traitements des maladies dégénératives des cônes. / The retina is composed of several types of neurons such as amacrin, ganglion, bipolar and photoreceptor cells. Photoreceptors, which include cones and rods, are highly specialized neurons that convert light into electrical signals by phototransduction. The molecular mechanisms involved in differentiation of retinal progenitors (RPCs) into specialized neurons such as photoreceptors are poorly understood. The polycomb gene Bmi1 is a member of the Polycomb gene family that forms multimeric complexes involved in chromatin remodeling leading to gene repression. Biological functions of Bmi1 include regulation of cell proliferation, free radical metabolism, and DNA repair. Recently, it was shown that Bmi1 plays a critical role in the proliferation and self-renewal of a specific immature RPC group. Moreover Bmi1 is essential for post-natal retinal development. The objective of the current study is to analyze Bmi1 function in photoreceptor development and survival. Our results show that Bmi1 deficiency in mice causes degeneration of cone photoreceptors, but not of rods. Furthermore, Bmi1 is predominantly expressed in cones. Experiments using primary retinal cell cultures suggest a cell-autonomous phenotype. In addition, codeletion of Bmi1 and the critical DNA damage response protein Chk2 resulted in partial rescue and slow-down of cone degeneration. Bmi1-/- and Bmi1-/-Chk2-/- retinas also exhibit an important increase in oxidative DNA damage, suggesting that cellular redox state could play an important role in cone survival. Our studies on the role of Bmi1 in photoreceptors elucidate the mechanisms contributing to cone survival, and could lead to the development of new treatments for cone degenerative diseases. Rétine Photorécepteurs Survie Dégénérescence Gène Polycomb Bmi1 Cône Retina Photoreceptors Survival Degeneration Polycomb gene Bmi1 Cone
863	Régulation de l’expression du gène Six6 par les facteurs de transcription Lhx2 et Pax6 dans le contexte des cellules souches rétiniennes Champagne, Marie-Pier 08 1900 (has links) La rétinogésèse des vertébrés est la culmination de processus biologiques complexes parfaitement exécutés. Cette délicate orchestration est principalement contrôlée par les facteurs de transcription qui permettent aux progéniteurs rétiniens de proliférer, de s’auto-renouveler et de se différencier de façon appropriée. Les facteurs de transcription à homéodomaine sont les protéines qui sont responsables de la démarcation du site du primordium optique et participeront même à la différenciation tardive des différents types cellulaires de la rétine. Le contrôle génétique concernant l‘activation de l’expression de facteurs de transcription est peu connu. Nous avons étudié les séquences génomique avoisinant le gène Six6 afin d’identifier et mieux comprendre son promoteur. Des expériences d’immunoprécipitation de chromatine et des essais luciférases ont confirmé la liaison et la transactivation synergique du promoteur potentiel de Six6 par Lhx2 et Pax6 in vitro. Cette présente étude confirme et précise également le rôle de Lhx2 au niveau du développement précoce de l’oeil. La compréhension détaillée des réseaux génétiques régulant les progéniteurs rétiniens à former une rétine fonctionnelle est essentielle. En effet, lorsque ces connaissances seront acquises, nous serons en mesure d’appliquer les thérapies cellulaires pour rétablir les fonctions rétiniennes lors de pathologies dégénératives. / Vertebrate eye developement is the result of multiple perfectly executed biological process. This tight orchestration is principaly controled by transcription factors. Homeobox-containing transcription factors are expressed in the presumptive eye field and are required to initiate eye development and for final retinal cell differenciation. The genetic control of these transcription factors are poorly understood. We analysed Six6’s nearby genomic sequence to caracterise potential promoter regions. Chromatin immunoprecipitations and luciferase assays confirmed the binding and the in vitro synergic trans-activation of Six6 potential promoter by Lhx2 and Pax6. This study also demonstrate the contribution of Lhx2 for the establishment of presumptive retina field at the neural plate stage. The detailed knowledge of genetic networks regulating the formation of a fonctional retina by retinal progenitor is crucial. Indeed, when these mecanisms will be eluciated, we will be able to establish regenerative retinal cell therapy. Rétine Développement Lhx2 Pax6 Six6 Progéniteur rétinien Vésicule optique Facteur de transcription Homéodomaine Retina Homeobox Development Transcription factor Optic vesicle
864	Effect of hormone replacement therapy on retinal and optic nerve head blood flow and topography in postmenopausal women, and retinal tissue perfusion in ovariectomized rats Deschênes, Micheline Céline January 2007 (has links) Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal Femmes Women Ménopause Menopause Rats Rats Ovariectomie Ovariectomy Estrogènes Estrogens Hormonothérapie Hormonotherapy Débit sanguin Blood flow Rétine Retina Fibres nerveuses rétiniennes Retinal nerve fiber layer Neuroprotection Neuroprotection
865	The role of non-linearities in visual perception studied with a computational model of the vertebrate retina Hennig, Matthias H. January 2006 (has links) Processing of visual stimuli in the vertebrate retina is complex and diverse. The retinal output to the higher centres of the nervous system, mediated by ganglion cells, consists of several different channels. Neurons in these channels can have very distinct response properties, which originate in different retinal pathways. In this work, the retinal origins and possible functional implications of the segregation of visual pathways will be investigated with a detailed, biologically realistic computational model of the retina. This investigation will focus on the two main retino-cortical pathways in the mammalian retina, the parvocellular and magnocellular systems, which are crucial for conscious visual perception. These pathways differ in two important aspects. The parvocellular system has a high spatial, but low temporal resolution. Conversely, the magnocellular system has a high temporal fidelity, spatial sampling however is less dense than for parvocellular cells. Additionally, the responses of magnocellular ganglion cells can show pronounced nonlinearities, while the parvocellular system is essentially linear. The origin of magnocellular nonlinearities is unknown and will be investigated in the first part of this work. As their main source, the results suggest specific properties of the photoreceptor response and a specialised amacrine cell circuit in the inner retina. The results further show that their effect combines in a multiplicative way. The model is then used to examine the influence of nonlinearities on the responses of ganglion cells in the presence of involuntary fixational eye movements. Two different stimulus conditions will be considered: visual hyperacuity and motion induced illusions. In both cases, it is possible to directly compare properties of the ganglion cell population response with psychophysical data, which allows for an analysis of the influence of different components of the retinal circuitry. The simulation results suggest an important role for nonlinearities in the magnocellular stream for visual perception in both cases. First, it will be shown how nonlinearities, triggered by fixational eye movements, can strongly enhance the spatial precision of magnocellular ganglion cells. As a result, their performance in a hyperacuity task can be equal to or even surpass that of the parvocellular system. Second, the simulations imply that the origin of some of the illusory percepts elicited by fixational eye movements could be traced back to the nonlinear properties of magnocellular ganglion cells. As these activity patterns strongly differ from those in the parvocellular system, it appears that the magnocellular system can strongly dominate visual perception in certain conditions. Taken together, the results of this theoretical study suggest that retinal nonlinearities may be important for and strongly influence visual perception. The model makes several experimentally verifiable predictions to further test and quantify these findings. Furthermore, models investigating higher visual processing stages may benefit from this work, which could provide the basis to produce realistic afferent input. 152.140113
866	Subcortical pathways for colour vision Szmajda, Brett A. Unknown Date (has links) (PDF) Visual sub-modalities, such as colour, form and motion perception, are analysed in parallel by three visual “pathways” – the parvocellular (PC), magnocellular (MC) and koniocellular (KC) pathways. This thesis aims to further elucidate some properties of the subcortical pathways for colour vision. The experimental animal used throughout is a New World monkey, the common marmoset Callithrix jacchus. (For complete abstract open document)
867	Microfabrication of an Implantable silicone Microelectrode array for an epiretinal prosthesis Maghribi, M January 2003 (has links) Thesis (Ph.D.); Submitted to the Univ. of California, Davis, CA (US); 10 Jun 2003. / Published through the Information Bridge: DOE Scientific and Technical Information. "UCRL-LR-153347" Maghribi, M. 06/10/2003. Report is also available in paper and microfiche from NTIS.
868	The role of bHLH gene ash1 in the developing chick eye Mao, Weiming. January 2008 (has links) (PDF) Thesis (Ph.D.)--University of Alabama at Birmingham, 2008. / Title from PDF title page (viewed on Sept. 17, 2009). Includes bibliographical references.
869	Magnetic Resonance Imaging of the Rat Retina: a Dissertation Bhagavatheeshwaran, Govind 04 March 2008 (has links) The retina is a thin layer of tissue lining the back of the eye and is primarily responsible for sight in vertebrates. The neural retina has a distinct layered structure with three dense nuclear layers, separated by plexiform layers comprising of axons and dendrites, and a layer of photoreceptor segments. The retinal and choroidal vasculatures nourish the retina from either side, with an avascular layer comprised largely of photoreceptor cells. Diseases that directly affect the neural retina like retinal degeneration as well as those of vascular origin like diabetic retinopathy can lead to partial or total blindness. Early detection of these diseases can potentially pave the way for a timely intervention and improve patient prognosis. Current techniques of retinal imaging rely mainly on optical techniques, which have limited depth resolution and depend mainly on the clarity of visual pathway. Magnetic resonance imaging is a versatile tool that has long been used for anatomical and functional imaging in humans and animals, and can potentially be used for retinal imaging without the limitations of optical methods. The work reported in this thesis involves the development of high resolution magnetic resonance imaging techniques for anatomical and functional imaging of the retina in rats. The rats were anesthetized using isoflurane, mechanically ventilated and paralyzed using pancuronium bromide to reduce eye motion during retinal MRI. The retina was imaged using a small, single-turn surface coil placed directly over the eye. The several physiological parameters, like rectal temperature, fraction of inspired oxygen, end-tidal CO2, were continuously monitored in all rats. MRI parameters like T1, T2, and the apparent diffusion coefficient of water molecules were determined from the rat retina at high spatial resolution and found to be similar to those obtained from the brain at the same field strength. High-resolution MRI of the retina detected the three layers in wild-type rats, which were identified as the retinal vasculature, the avascular layer and the choroidal vasculature. Anatomical MRI performed 24 hours post intravitreal injection of MnCl2, an MRI contrast agent, revealed seven distinct layers within the retina. These layers were identified as the various nuclear and plexiform layers, the photoreceptor segment layer and the choroidal vasculature using Mn54Cl2emulsion autoradiography. Blood-oxygenlevel dependent (BOLD) functional MRI (fMRI) revealed layer-specific vascular responses to hyperoxic and hypercapnic challenges. Relative blood volume of the retina calculated by using microcrystalline iron oxide nano-colloid, an intravascular contrast agent, revealed a superfluous choroidal vasculature. Fractional changes to blood volume during systemic challenges revealed a higher degree of autoregulation in the retinal vasculature compared to the choroidal vasculature, corroborating the BOLD fMRI data. Finally, the retinal MRI techniques developed were applied to detect structural and vascular changes in a rat model of retinal dystrophy. We conclude that retinal MRI is a powerful investigative tool to resolve layerspecific structure and function in the retina and to probe for changes in retinal diseases. We expect the anatomical and functional retinal MRI techniques developed herein to contribute towards the early detection of diseases and longitudinal evaluation of treatment options without interference from overlying tissue or opacity of the visual pathway. Magnetic Resonance Imaging Retina Retinal Degeneration Retinal Diseases Diagnostic Imaging Rats Animal Experimentation and Research Cardiovascular Diseases Diagnosis Endocrine System Diseases Eye Diseases Investigative Techniques Sense Organs Tissues
870	Analyse génétique de la fonction du gène Polycomb Bmi1 dans le développement et la survie des photorécepteurs chez la souris Plamondon, Vicky 04 1900 (has links) No description available. Rétine Photorécepteurs Survie Dégénérescence Gène Polycomb Bmi1 Cône Retina Photoreceptors Survival Degeneration Polycomb gene Bmi1 Cone

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