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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

The Role of Bone Morphogenetic Proteins in Reactive Gliosis after Demyelinating Spinal Cord Lesions

Fuller, Molly Lynn 11 July 2007 (has links)
No description available.
2

Comparing Two Different Statins in a Delayed Pharmacological Treatment for Ischemic Stroke

Hagerty, Kailyn M. 16 July 2012 (has links)
No description available.
3

An in vitro model of the brain tissue reaction to chronically implanted recording electrodes reveals essential roles for serum and bFGF in glial scarring

Polikov, Vadim Steven January 2009 (has links)
<p>Chronically implanted recording electrode arrays linked to prosthetics have the potential to make positive impacts on patients suffering from full or partial paralysis [1;2]. Such arrays are implanted into the patient's cortical tissue and record extracellular potentials from nearby neurons, allowing the information encoded by the neuronal discharges to control external devices. While such systems perform well during acute recordings, they often fail to function reliably in clinically relevant chronic settings [3]. Available evidence suggests that a major failure mode of electrode arrays is the brain tissue reaction against these implants (termed the glial scar), making the biocompatibility of implanted electrodes a primary concern in device design. Previous studies have focused on modifying the form factor of recording arrays, implanting such arrays in experimental animals, and, upon explantation, evaluating the glial scarring in response to the implant after several weeks in vivo. Because of a lack of information regarding the mechanisms involved in the tissue reaction to implanted biomaterials in the brain, it is not surprising that these in vivo studies have met with limited success. This dissertation describes the development of a simple, controlled in vitro model of glial scarring and the utilization of that model to probe the cellular and molecular mechanisms behind glial scarring.</p><p>A novel in vitro model of glial scarring was developed by adapting a primary cell-based system previously used for studying neuroinflammatory processes in neurodegenerative disease [4]. Midbrains from embryonic day 14 Fischer 344 rats were mechanically dissociated and grown on poly-D-lysine coated 24 well plates to a confluent layer of neurons, astrocytes, and microglia. The culture was injured with either a mechanical scrape or foreign-body placement (segments of 50 mm diameter stainless steel microwire), fixed at time points from 6 h to 10 days, and assessed by immunocytochemistry. Microglia invaded the scraped wound area at early time points and hypertrophied activated astrocytes repopulated the wound after 7 days. The chronic presence of microwire resulted in a glial scar forming at 10 days, with microglia forming an inner layer of cells coating the microwire, while astrocytes surrounded the microglial core with a network of cellular processes containing upregulated GFAP. Neurons within the culture did not repopulate the scrape wound and did not respond to the microwire, although they were determined to be electrically active through patch clamp recording. </p><p>This initial model recreated many of the hallmarks of glial scarring around electrodes used for recording in the brain; however, the model lacked the reproducibility necessary to establish a useful characterization tool. After the protocol was amended to resemble protocols typically used to culture neural stem/precursor cells, an intense scarring reaction was consistently seen [5]. To further optimize and characterize the reaction, six independent cell culture variables (growth media, seeding density, bFGF addition day, serum concentration in treatment media, treatment day, and duration of culture) were varied systematically and the resulting scars were quantified. The following conditions were found to give the highest level of scarring: Neurobasal medium supplemented with B27, 10% fetal bovine serum at treatment, 10 ng/ml b-FGF addition at seeding and at treatment, treatment at least 6 days after seeding and scar growth of at least 5 days. Seeding density did not affect scarring as long as at least 500,000 cells were seeded per well, but appropriate media, bFGF, and serum were essential for significant scar formation. </p><p>The optimized in vitro model was then used to help uncover the underlying molecular and cellular mechanisms behind glial scarring. A microwire coating that mimics the basal lamina present within glial scars was developed that allows cells responding to the coated microwire to be isolated and evaluated (i.e. through cell counting or cell staining). A panel of soluble factors known to be involved in glial scar formation was added to the media and the cellular response was recorded. The extent of cell accumulation on the coated microwires was significantly increased by titration of the culture with serum, the pleotropic growth factor bFGF, the inflammatory cytokines IL-1&alpha; and IL-1&beta;, and the growth factors PDGF and BMP-2. The other fourteen soluble factors tested had little to no effect on the number of cells that attached to the coated microwires, although a specific blocker of the bFGF receptor was able to abrogate the effect of bFGF. This study proposes essential roles in glial scarring of serum, which infiltrates brain tissue upon disruption of the blood-brain barrier, and bFGF, which is a necessary growth and survival factor for the neural precursor cells that respond to injury. These insights suggest repeated rounds of implant micromotion-induced cellular damage, with the resultant neuronal death, serum release, and bFGF deposition may thicken the glial scar and lead to recording signal loss.</p> / Dissertation
4

Modulation of CSPG sulfation patterns through siRNA silencing of sulfotransferase expression to promote CNS regeneration

Millner, Mary Angela 10 July 2008 (has links)
Injury to the central nervous system (CNS) results in the formation of a highly inhibitory glial scar consisting mainly of chondroitin sulfate proteoglycans (CSPGs). CSPGs are comprised of a protein core with covalently attached chondroitin sulfate glycosaminoglycan (CS-GAG) side chains. CSPGs and CS-GAGs have been implicated in the regenerative failure of the CNS, though the mechanism underlying inhibition is unclear. Sulfation affects both the physical and chemical characteristics of CS-GAGs and, therefore, it has been hypothesized that certain sulfation patterns are more inhibitory than others. To investigate this hypothesis, specific chondroitin sulfate sulfotransferases (CSSTs), the enzymes responsible for CS-GAG sulfation, were knocked down in vitro using siRNA. C4ST-1, C4ST-2, and C46ST were chosen as targets for gene knockdown in this study based on their expression in neural tissue and the extent of inhibition caused by their respective CS-GAG. It was hypothesized that transfection of primary rat astrocytes with siRNAs designed to prevent the expression of C4ST-1, C4ST-2, and C46ST would decrease specific sulfation patterns of CSPGs, resulting in improved neurite extension in a neurite guidance assay. Through optimization of siRNA dose, astrocyte viability was maintained while successfully knocking down mRNA levels of C4ST-1, C4ST-2, and C46ST and significantly reducing total levels of secreted CS-GAGs. However, no increase in the incidence of neurite extension was observed using conditioned media collected from siRNA transfected astrocytes compared to non-transfected controls. These data suggest that sulfation does not contribute to CSPG-mediated neurite inhibition, though further investigation is necessary to confirm these findings. Significantly, this work has established a paradigm for investigating the role of CSPG sulfation patterns in CNS regeneration.
5

The Role of NG2+ Cells in Regeneration Failure After Spinal Cord Injury

Filous, Angela R., Ph.D. 11 June 2014 (has links)
No description available.
6

Development and Characterization of Anti-Inflammatory Coatings for Implanted Neural Probes

Zhong, Yinghui 21 November 2006 (has links)
Stable single-unit recordings from the nervous system using microelectrode arrays can have significant implications for the treatment of a wide variety of sensory and movement disorders. However, the long-term performance of the implanted neural electrodes is compromised by the formation of glial scar around these devices, which is a typical consequence of the inflammatory tissue reaction to implantation-induced injury in the CNS. The glial scar is inhibitory to neurons and forms a barrier between the electrode and neurons in the surrounding brain tissue. Therefore, to maintain long-term recording stability, reactive gliosis and other inflammatory processes around the electrode need to be minimized. This work has succeeded in the development of neural electrode coatings that are capable of sustained release of anti-inflammatory agents while not adversely affecting the electrical performance of the electrodes. The effects of coating methods, initial drug loadings on release kinetics were investigated to optimize the coatings. The physical properties of the coatings and the bioactivity of released anti-inflammatory agents were characterized. The effect of the coatings on the electrical property of the electrodes was tested. Two candidate anti-inflammatory agents were screened by evaluating their anti-inflammatory potency in vitro. Finally, neural electrodes coated with the anti-inflammatory coatings were implanted into rat brains to assess the anti-inflammatory potential of the coatings in vivo. This work represents a promising approach to attenuate astroglial scar around the implanted silicon neural electrodes, and may provide a promising strategy to improve the long-term recording stability of silicon neural electrodes.
7

Influence des processus inflammatoires sur la neuroplasticité et sur les récupérations fonctionnelles après lésion spinale chez le rat adulte / Influence of inflammatory processes on neuroplasticity and functional recovery after spinal cord injury in the adult rat

Thomaty, Sandie 09 December 2015 (has links)
Les lésions spinales conduisent à des altérations majeures des fonctions sensorimotrices. Les récupérations fonctionnelles consécutives à ces atteintes sont très limitées, notamment en raison des capacités réduites de réparation des tissus endommagés dans le SNC. En outre, ces récupérations dépendent notamment de plusieurs processus cellulaires tels que l'activation astrogliale qui conduit à la formation de la cicatrice gliale, ou encore l'inflammation dont les cellules microgliales et les mastocytes sont les effecteurs les plus précoces. Cette inflammation est connue pour exacerber les dommages tissulaires et restreindre les possibilités de récupération. Cependant, des études récentes chez l'animal et chez l'Homme montrent que l'inflammation pourrait également avoir des effets favorisant les processus de récupération. Le but de cette thèse était de mieux comprendre les liens qui existent entre neuroinflammation, neuroplasticité et récupérations fonctionnelles après lésion spinale. L’objectif expérimental visait à examiner les réactivités microgliales, mastocytaires et astrocytaires post-lésionnelles, en parallèle avec des restaurations fonctionnelles. Dans ce contexte nous nous sommes plus particulièrement intéressés à l'influence d'une cytokine pro-inflammatoire, le Granulocyte-Macrophage Colony Stimulating Factor (GM-CSF) sur ces processus inflammatoires et la plasticité fonctionnelle après une hémisection C4-C5 chez le rat adulte. L’ensemble de nos travaux suggère que le GM-CSF pourrait agir par l’intermédiaire de plusieurs événements cellulaires et moléculaires, en favorisant des phénomènes de plasticité adaptatifs et la récupération partielle de fonctions altérées. / Spinal cord injuries are mostly of traumatic origin and result in major sensorimotor deficits. Postlesion functional recovery is limited, especially because of the reduced capacity of repairing damaged tissues. Moreover, this recovery depends specifically on several cellular processes such as astroglial activation conducting to glial scar formation, or inflammation for which microglial and mast cells are the earliest effectors. This inflammation is known to exacerbate tissue damages and restrain the capacity to recover. However, recent studies in animals and humans show that inflammation may also have beneficial aeffects on recovery processes. The studies conducted during my doctoral research were intended to better understand the links between neuroinflammation, neuroplasticity and functional recovery following spinal cord injury. We aimed at examining microglial, mast cells and astroglial reactivities after the injury, in relation with functional recovery of somatosensory and motor functions. In this context, we were particularly interested in the influence of Granulocyte Macrophage-Colony Stimulating Factor (GM-CSF) on inflammatory and plasticity mechanisms after a C4-C5 hemisection in the adult rat. Our doctoral research suggests that GM-CSF could act through several cellular and molecular events promoting adaptive plasticity phenomena underlying partial recovery of impaired functions.
8

Chronic inflammation surrounding intra-cortical electrodes is correlated with a local, neurodegenerative state

McConnell, George Charles 18 November 2008 (has links)
Thanks to pioneering scientists and clinicians, prosthetic devices that are controlled by intra-cortical electrodes recording one's 'thoughts' are a reality today, and no longer merely in the realm of science fiction. However, widespread clinical use of implanted electrodes is hampered by a lack of reliability in chronic recordings, independent of the type of electrodes used. The dominant hypothesis has been that astroglial scar electrically impedes the electrodes. However, recent studies suggest that the impedance changes associated with the astroglial scar are not high enough to interfere significantly impair neural recordings. Furthermore, there is a time delay between when scar electrically stabilizes and when neural recordings fail (typically >1 month lag), suggesting that scar, per se, does not cause chronic recording unreliability. In this study, an alternative hypothesis was tested in a rat model, namely, that chronic inflammation surrounding microelectrodes causes a local neurodegenerative state. Chronic inflammation was varied in three ways: 1) stab wound control, 2) age-matched control, and 3) inter-shank spacing of a multishank electrode. The results of this study suggest that chronic inflammation, as indicated by activated microglia and reactive astrocytes, is correlated with local neurodegeneration, marked by neuron cell death and dendritic loss. Surprisingly, axonal pathology in the form of hyperphosphorylation of the protein Tau (the hallmark of many tauopathies, including Alzheimer's Disease) was also observed in the immediate vicinity of microelectrodes implanted for 16 weeks. Additionally, work is presented on a fast, non-invasive method to monitor the astrocytic response to intra-cortical electrodes using electrical impedance spectroscopy. This work provides a non-invasive monitoring tool for inflammation, albeit an indirect one, and fills a gap which has slowed the development of strategies to control the inflammatory tissue response surrounding microelectrodes and thereby improve the reliability of chronic neural recordings. The results of these experiments have significance for the field of neuroengineering, because a more accurate understanding of why recordings fail is integral to engineering reliable solutions for integrating brain tissue with microelectrode arrays.
9

THE ROLE OF PTPs IN REGENERATION FAILURE FOLLOWING SPINAL CORD INJURY

Lang, Bradley Thomas 13 February 2015 (has links)
No description available.
10

Efeito neuroprotetor do transplante de células-tronco mesenquimais derivadas de dente decíduo humano em ratos Wistar submetidos à lesão medular

Nicola, Fabrício do Couto January 2017 (has links)
A lesão medular (LM) é uma patologia incapacitante que resulta em déficits sensoriais e motores. No Brasil, a incidência anual é de 30 novos casos de lesão medular a cada 1 milhão de indivíduos e, infelizmente, a LM permanece sem um tratamento eficaz. Células-tronco derivadas do dente decíduo humano estão entre as potenciais fontes de células-tronco para transplante após a lesão medular, cujo objetivo é de promover a proteção ou a recuperação da lesão na medula espinal. Buscou-se nesta tese avaliar os efeitos do transplante, uma hora após a lesão, das células tronco de dente decíduo humano (SHED) no período agudo, subagudo e crônico sobre a neuroproteção, proteção tecidual e recuperação funcional em ratos Wistar submetidos à lesão medular por contusão. Os principais objetivos foram: a) investigar os efeitos do transplante das SHED sobre a recuperação funcional, volume da lesão e morte neuronal; b) verificar os efeitos do transplante sobre as células progenitoras, formação da cicatriz glial e modificações astrocitárias após o modelo de contusão medular Observou-se a melhora na recuperação funcional, redução do volume da lesão e morte neuronal na medula espinal dos animais que receberam o transplante de SHED após a lesão medular. As SHED aumentam o número de células precursoras na medula espinal, no período subagudo, reduzem a expressão da proteína fibrilar glial ácida (GFAP) e aumentam a expressão do canal retificador de influxo de potássio 4.1, ambas proteínas astrocitárias. Concluímos que o transplante de células-tronco derivadas do dente decíduo humano após a lesão medular promove a recuperação funcional a partir do efeito neuroprotetor iniciado na fase aguda, confirmado pelo maior número de neurônios motores presentes seis semanas após a contusão. As SHED são capazes de aumentar o número de células precursoras e de produzir modificações astrocitárias na medula espinal de ratos lesados na fase subaguda, reduzindo a formação da cicatriz glial. / Spinal cord injury (SCI) is a disabling condition that results in sensory and motor deficits. The estimated annual incidence in Brazil is of 30 new cases of spinal cord injury per 1 million of individuals; unfortunately SCI remains without an effective treatment. Stem cells from human exfoliated deciduous teeth (SHED) are one among potential sources of stem cells for transplantation after spinal cord injury in order to promote protection or tissue and functional recovery after spinal cord injury. The aim of this Thesis was to evaluate the effects of stem cells from human exfoliated deciduous teeth (SHED) transplantation, one hour after lesion, in the acute, subacute and chronic phases on neuroprotection, tissue protection and functional recovery in Wistar rats submitted to spinal cord injury by contusion The main goals were: a) to investigate the effects of SHED transplantation on functional recovery, lesion volume, and neuronal death; b) to verify the effects of the transplantation on the progenitor cells number, glial scar formation and astrocytic modifications after spinal cord contusion. Improvement of functional recovery, reduction of lesion volume and neuronal death were observed in the spinal cord of animals submitted to spinal cord injury and SHED transplantation. SHEDs increased the number of precursor cells in the spinal cord in the subacute period, reduced the expression of glial fibrillary acidic protein (GFAP) and increased the expression of the potassium influx rectifier channel 4.1, both astrocyte proteins. We conclude that transplantation of stem cells from human exfoliated deciduous teeth after spinal cord injury promotes functional recovery from the neuroprotection effect, which starts in the acute phase and is confirmed six weeks after the contusion with a higher number of motor neurons in the ventral horn of spinal cord. SHEDs are able to increase the number of precursor cells and produce astrocyte modifications in the spinal cord of injured rats in the subacute phase, reducing glial scar formation.

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