Global ETD Search

221	Mechanisms controlling the cell body response to axon injury in dorsal root ganglion neurons Bani Hammad, Rasheed Ahmed 22 June 2010 (has links) Successful axon regeneration appears to depend on the development of an injury response. Dorsal root ganglion neurons exemplify the necessity of this injury response in a unique way. Peripheral nerve transection leads to development of an injury response and successful regeneration whereas central root transection does neither. The injury response may involve extracellular and intracellular pathways. To investigate the extraneuronal influences, we performed nerve transection of either the central or peripheral axon branches and studied the expression of GAP-43, a key growth associated protein, and the transcription factors ATF3, c-Jun, and STAT3. Our results show that the responses to peripheral versus central nerve transection are fundamentally different. Peripheral but not central nerve transection increases GAP-43, ATF3, and c-Jun expression. STAT3, however, is upregulated as a result of central but not peripheral nerve transection. To investigate potential intracellular signalling pathways, we applied FGF-2, an extracellular mitogen, or an analog of cAMP, an intracellular second messenger to the cut end of the peripheral axon. Our results indicate that FGF-2 and cAMP act as activators of GAP-43 expression. On the other hand, FGF-2 and cAMP act to downregulate the expression of ATF3. FGF-2 upregulates c-Jun and the activated form of STAT3. Paradoxically, the regulation of GAP-43 expression by cAMP or by FGF-2 in vivo shows opposing results from the previously reported in vitro studies. Our present results suggest that the peripheral nerve injury response may be governed by at least three different signalling pathways. STAT3 ATF3 cAMP GAP-43 transcription factors peripheral nerve injury transection dorsal root ganglion sensory neurons FGF-2 c-Jun
222	The Effects Of Early Postnatal Ethanol Intoxication On Retina Ganglion Cell Morphology And The Development Of Retino-geniculate Projections In Mice Dursun, Ilknur 01 February 2010 (has links) (PDF) Experimental and clinical data have documented the adverse effects of perinatal ethanol intoxication on peripheral organs and the central nervous system. There is little known, however, about potential damaging effects of perinatal ethanol on the developing visual system. The purpose of this study was to examine the effects of neonatal ethanol intoxication on RGC morphology, estimate the total number of neurons in RGC layer and dorsolateral geniculate nucleus (dLGN), and on the eye-specific fiber segregation in the dLGN), in YFP and C57BL/6 mice pups. Ethanol (3 g/kg/day) was administered by intragastric intubation throughout postnatal days (PD) 3-20 or 3-10. Intubation control (IC) and untreated control (C) groups were included. Blood alcohol concentration (BAC) was measured in separate groups of pups on PD3, PD10, and PD20 at 4 different time points, 1, 1.5, 2 and 3 h after the second intubation. Numbers neurons in the RGCs and dLGN were quantified on PD10, PD20 using unbiased stereological procedures. The RGC images were taken using a confocal microscope and images were traced using Neurolucida software. On PD9, intraocular injections of cholera toxin- QP Nervous System 361-430
223	Langzeitstabilisierung der regenerierenden visuellen Bahn der Ratte (Rattus norvegicus) Chiwitt, Carolin 16 November 2010 (has links) (PDF) Durchtrennte Axone adulter retinaler Ganglienzellen (RGZ) können in periphere Nerventransplantate (PNT) einwachsen, die als “bypass” des distalen Sehnervenstumpfes verwendet werden. Das Transplantationsmodell, bei dem der durchtrennte Sehnerv durch ein Ischiasnervsegment ersetzt wird, ist in der Regenerationsforschung ein seit Jahren fest etabliertes Verfahren. In dieser Arbeit soll der Frage nachgegangen werden, ob a) der Ersatz des Sehnervs durch ein peripheres Nervensegment RGZ über einen langen Zeitraum hinweg morphologisch und funktionell stabilisiert, ob b) Unterschiede der Stabilisierung in Abhängigkeit von der Hirnregion, mit der das PNT in Kontakt tritt, zu beobachten sind und c) inwieweit regenerierende RGZ dadurch selbst peripher-nervöse Eigenschaften annehmen. Der Sehnerv adulter Ratten wurde zunächst komplett intraorbital durchtrennt. Der okuläre Stumpf wurde über ein autologes Ischiasnervsegment mit verschiedenen visuellen Zentren (Kortex, Mittelhirn) oder mit Fremdzielgebieten (z. B. Muskel) verbunden. Weitere Kontrollgruppen bestanden in der Quetschung des Sehnervs, der Durchtrennung ohne Transplantation und der Transplantation mit blind endendem Transplantat. Die Netzhautintegrität wurde pupillometrisch und elektroretinographisch regelmäßig überprüft, um eine eventuelle, funktionelle Wiederherstellung der visuellen Bahn zu erfassen. Nach einem, sechs und neun Monaten wurden die regenerierenden bzw. axotomierten oder gequetschten RGZ mit 4-(4-(didecylamino)styryl)-N-methylpyridinium (4-Di-10-ASP) retrograd markiert und morphometrisch quantifiziert (Fluoreszenz-, Konfokal- und Elektronenmikroskopie sowie Differentialinterferenzkontrast). Zusätzlich wurden immunhistochemische und anterograde Markierungsuntersuchungen durchgeführt. Regenerierende Ganglienzellen bleiben bis neun Monate nach der Transplantation am Nervus opticus stabil. Es gibt quantitative sowie morphometrisch erfassbare Unterschiede zwischen den experimentellen Gruppen und den Kontrollen, wobei die wieder verbundenen Ganglienzellen morphologisch am besten zu klassifizieren sind. Quantitativ zeigen die Retinae mit gequetschtem Sehnerv nach sechs Monaten die höchste Überlebensrate der RGZ. Die Effektivität dieses Verfahrens als Modell der zentralen Nervenläsion darf in Folge dieser Ergebnisse in Frage gestellt werden. Nach neun Monaten sind in den Retinae mit Rekonnektion zum Mittelhirn die meisten Ganglienzellen vorhanden. Elektrophysiologisch zeigen die Augen mit Verbindung zum Muskelgewebe die besten funktionellen Ergebnisse. Schlussfolgernd zeigt sich, dass adulte RGZ der Ratte über ein peripher-nervöses Transplantat, welches mit visuellen Zentren in Verbindung steht, über lange Zeit stabilisiert werden können. Retinale Ganglienzellen Sehnerv peripheres Nerventransplantat Regeneration retinal ganglion cells optic nerve peripheral nerve graft regeneration ddc:610
224	The Human Spiral Ganglion Tylstedt, Sven January 2003 (has links) Our knowledge of the fine structure of the Human Spiral Ganglion (HSG) is still inadequate and new treatment techniques for deafness using electric stimulation, call for further information and studies on the neuronal elements of the human cochlea. This thesis presents results of analyses of human cochlear tissue and specimens obtained during neurosurgical transpetrosal removal of life-threatening meningeomas. The use of surgical biopsies produced a well-preserved material suitable for ultrastructural and immunohistochemical studies on the human inner ear. The SG was studied with respect to fine structure, using TEM technique and the immunostaining pattern of synaptophysin, which is an integral membrane protein of neuronal synaptic vesicles. The immunostaining patterns of the tight junctional protein ZO-1 and the gap junctional proteins Cx26 and Cx43 in the human cochlea were also studied. The ultrastructural morphology revealed an absence of myelination pattern in the HSG, thus differing from that in other species. Furthermore, formation of structural units as well as signs of neural interaction between the type 1 neurons could be observed. Type 1 cells were tightly packed in clusters, sharing the ensheathment of Schwann cells. The cells frequently made direct physical contact in Schwann cell gaps in which membrane specializations appeared. These specializations consisted of symmetrically or asymmetrically distributed filamentous densities along the apposed cell membranes. The same structures were also present between individual unmyelinated nerve fibres and the type 1 cells. Synapses were observed on the type 2 neurons, with nerve fibres originating from the intraganglionic spiral bundle. Such synapses, though rare, were also observed on the type 1 cells. The ultrastructural findings were confirmed by the synaptophysin study. A 3-D model of a Schwann cell gap between two type 1 cells was constructed, describing the distribution pattern of membrane specializations. In the immunohistochemical studies on the human cochlea, ZO-1 was expressed in tissues lining scala media, thus contributing to the formation of a closed compartment system, important for the maintenance of the specific ionic composition of the endolymph. Protein Cx26 could be identified in non-sensory epithelial cells of the organ of Corti, in connective tissue cells of the spiral ligament and spiral limbus, as well as in the basal and intermediate cell layers of stria vascularis. Cx26 in this region may be involved in the recycling of potassium. Protein Cx43 stained weakly in the spiral ligament, but intense staining in the SG may indicate that gap junctions exist between these neurons. A different functional role for the HSG can be assumed from the morphological characteristics and the signs of a neural interaction between the SG cells. This might be relevant for neural processing mechanisms in speech coding and could have implications for cochlear implant techniques. Otorhinolaryngology human spiral ganglion ultrastructural morphology neural interaction synaptophysin connexin membrane specializations synapse gap junction tight junction Otorhinolaryngologi Otorhinolaryngology Otorhinolaryngologi
225	La Visualisation in vivo des « espèces oxygénées radiculaires» au niveau des cellules ganglionnaires de la rétine. Mears, Katrina A. 04 1900 (has links) Titre: La Visualisation in vivo des « espèces oxygénées radiculaires» au niveau des cellules ganglionnaires de la rétine. Le But : Les espèces d'oxygène réactives sont non seulement produites à la suite de la blessure cellulaire, mais servent aussi des molécules faisantes des signes pour une variété de processus critiques, en incluant mitosis et de mort de cellule. Nous avons auparavant dit que la blessure à RGC axons incite un éclatement de superoxyde dans le corps de cellule, probablement de l'origine mitochondrial (Lieven et al, 2006). Nous décrivons maintenant une méthode pour refléter des espèces d'oxygène réactives dans la rétine de l'animal vivant en utilisant un confocal le lisant rapidement du laser ophthalmoscope a appelé la Rétine de Heidelberg Angiograph 2 (HRA2) équipé avec les lasers doubles. La méthodolologie : Après les études préliminaires en utilisant d'autres indicateurs (hydroethidium; HEt) pour les espèces d'oxygène réactives, nous avons essayé de refléter des espèces d'oxygène réactives dans le dans le modèle de vivo l'utilisation 5-(et 6)-chloromethyl-2', 7 '-dichlorodihydrofluorescein diacetate, l'acétyle ester (le CM-H2DCFDA). Un nerf optique de Longs-Evans rats a été écrasé intraorbitalement, en épargnant la circulation retinal. Dans certains rats colliculi supérieur de Longs rats Evans avait été auparavant exposé via craniotomy et surposé avec Gelfoam saturé avec le vert indocyanine (ICG). Aux points de temps variables les animaux ont été injectés intraveineusement ou intravitreally avec HEt ou le CM-H2DCFDA et reflétés avec fluorescein et-ou les filtres d'ICG en utilisant le HRA2. Les résultats: Nous avons démontré le foyer brillant multiple de fluorescence dans la couche de cellule de ganglion quand nous avons rétrogradement étiqueté d'ICG bilatéralement, en indiquant qu'ICG était un colorant rétrogradement transporté qui pourrait être découvert avec le HRA2. Après axotomy et l'injection intravitreal de CM-H2DCFDA, il y avait la fluorescence brillante dans le canal fluorescein dans quelques cellules dans la couche de cellule de ganglion, en accord avec la production d'une ou plusieurs espèces d'oxygène réactives. Les conclusions : RGCs peut être identifié et les niveaux d'espèces d'oxygène réactives mesurés en utilisant une fréquence double confocal Mots-clés : cellules ganglionnaires de la rétine; especes oxygenique radiculaire; la visualisation; / Title: Imaging Reactive Oxygen Species in RGCs In vivo Purpose: Reactive oxygen species not only are generated as a result of cellular injury, but also serve as signaling molecules for a variety of critical processes, including mitosis and cell death. We previously reported that injury to RGC axons induces a burst of superoxide within the cell body, probably of mitochondrial origin (Lieven et al, 2006). We now describe a method for imaging of reactive oxygen species within the retina of the living animal using a confocal scanning laser ophthalmoscope called the Heidelberg Retina Angiograph 2 (HRA2) equipped with dual lasers. Methods: Following preliminary studies using other indicators (hydroethidium; HEt) for reactive oxygen species, we attempted to image reactive oxygen species in the in vivo model using 5-(and-6)-chloromethyl-2',7'-dichlorodihydrofluorescein diacetate, acetyl ester (CM-H2DCFDA). The resultant images were quantified using ImageJ. One optic nerve of Long-Evans rats was crushed intraorbitally, sparing the retinal circulation. In some rats the superior colliculi of Long-Evans rats had been previously exposed via craniotomy and overlaid with Gelfoam saturated with indocyanine green (ICG). At varying time points the animals were injected intravenously or intravitreally with HEt or CM-H2DCFDA and imaged with fluorescein and/or ICG filters using the HRA2. Results: We demonstrated multiple bright foci of fluorescence in the ganglion cell layer when we retrogradely labeled with ICG bilaterally, indicating that ICG was a retrogradely transported dye that could be detected with the HRA2. Following axotomy and intravitreal injection of CM-H2DCFDA, there was bright fluorescence in the fluorescein channel in a few cells in the ganglion cell layer, consistent with production of one or more reactive oxygen species. There was no cross-talk between the fluorescein and ICG channels when detecting ICG or CM-H2DCFDA, respectively. Conclusions: Retrograde labeled RGCs can be identified and levels of reactive oxygen species measured using a dual frequency confocal scanning laser ophthalmoscope. Keywords RGCs, oxidative radical, imaging Retinal ganglion cells Oxidative radicals Imaging Cellules ganglionnaires de la rétine Especes oxygenique radiculaire La visualisation
226	The transition from progenitor cell to neuron : fibroblast growth factors and their role in retinal ganglion cell neurogenesis / McCabe, Kathryn Leigh. January 2000 (has links) Thesis (Ph. D.)--University of Washington, 2000. / Vita. Includes bibliographical references (leaves 100-117).
227	Role of RANKL in the differentiation of B cell associated stroma in secondary lymphoid organs / Rôle de RANKL dans la différenciation du stroma associé aux lymphocytes B dans les organes lymphoïdes secondaires Allouche, Farouk 12 January 2018 (has links) RANKL (ligand du récepteur activateur de NF-KB) est un membre de la famille des TNF dont la signalisation passe par RANK et qui joue un rôle important dans la régulation immunitaire. Chez l'adulte, RANKL est exprimé constitutivement par des cellules réticulaires marginales (MRC) des ganglions lymphatiques. Comme les MRCs sont physiquement proches des lymphocytes B (LB) et ont été proposé d’être des précurseurs de cellules dendritiques folliculaires (FDC), RANKL pourrait jouer un rôle dans la différenciation du stroma associé aux LB et dans la réponse humorale. Afin de mieux comprendre la fonction de RANKL exprimé par les MRC, nous avons généré des souris déficitaires pour RANKL dans les cellules stromales. Nous avons constaté que la formation du follicule B était perturbée ainsi que le réseau FDC. Bien que RANKL ne soit pas requis pour la formation des MRC, il est nécessaire pour l'expression de la chimiokine CXCL13 par ces mêmes cellules. Parmi les TNFRSF dont la signalisation est requise pour l’expression de CXCL13 et la différenciation des FDC, le TNFR1 était significativement réduit dans les cellules stromales des souris dépourvues de RANKL stromal. Ainsi, RANKL pourrait constituer une nouvelle cible thérapeutique contre les immunopathologies des LB en agissant sur son stroma. / RANKL (receptor activator of NF-κB ligand), a member of the TNF family that signals via RANK, plays an important role for immune regulation. In the adult, RANKL is constitutively expressed by marginal reticular cells (MRCs) of the lymph nodes. Because MRCs are positioned in close vicinity to B cells and may be precursors of follicular dendritic cells (FDCs), RANKL could play a role in the differentiation of B cell-associated stroma and the humoral immune response. In order to better understand the role of RANKL expressed by the MRCs, we generated mice with conditional RANKL deficiency in the stromal compartment. We found that the B cell follicle structure was disrupted and FDC network formation was reduced. Although RANKL was not required for MRC formation, it was necessary for the expression of B cell attracting chemokine CXCL13. Among the TNFRSF members known to control CXCL13 expression and FDC formation, we found that TNFR1 was significantly reduced in the RANKL cKO mice. Thus, RANKL may present a novel therapeutic strategy against B cell-mediated immunopathologies by acting on its stroma. RANKL Ganglion lymphatique MRC Follicule B CXCL13 TNFR1 RANKL Lymph node MRC B cell follicle CXCL13 TNFR1 571.96
228	La Visualisation in vivo des « espèces oxygénées radiculaires» au niveau des cellules ganglionnaires de la rétine Mears, Katrina A. 04 1900 (has links) No description available. Retinal ganglion cells Oxidative radicals Imaging Cellules ganglionnaires de la rétine Especes oxygenique radiculaire La visualisation
229	Image Compression and Channel Error Correction using Neurally-Inspired Network Models Watkins, Yijing Zhang 01 May 2018 (has links) Everyday an enormous amount of information is stored, processed and transmitted digitally around the world. Neurally-inspired compression models have been rapidly developed and researched as a solution to image processing tasks and channel error correction control. This dissertation presents a deep neural network (DNN) for gray high-resolution image compression and a fault-tolerant transmission system with channel error-correction capabilities. A feed-forward DNN implemented with the Levenberg-Marguardt learning algorithm is proposed and implemented for image compression. I demonstrate experimentally that the DNN not only provides better quality reconstructed images but also requires less computational capacity as compared to DCT Zonal coding, DCT Threshold coding, Set Partitioning in Hierarchical Trees (SPIHT) and Gaussian Pyramid. An artificial neural network (ANN) with improved channel error-correction rate is also proposed. The experimental results indicate that the implemented artificial neural network provides a superior error-correction ability by transmitting binary images over the noisy channel using Hamming and Repeat-Accumulate coding. Meanwhile, the network’s storage requirement is 64 times less than the Hamming coding and 62 times less than the Repeat-Accumulate coding. Thumbnail images contain higher frequencies and much less redundancy, which makes them more difficult to compress compared to high-resolution images. Bottleneck autoencoders have been actively researched as a solution to image compression tasks. However, I observed that thumbnail images compressed at a 2:1 ratio through bottleneck autoencoders often exhibit subjectively low visual quality. In this dissertation, I compared bottleneck autoencoders with two sparse coding approaches. Either 50\% of the pixels are randomly removed or every other pixel is removed, each achieving a 2:1 compression ratio. In the subsequent decompression step, a sparse inference algorithm is used to in-paint the missing the pixel values. Compared to bottleneck autoencoders, I observed that sparse coding with a random dropout mask yields decompressed images that are superior based on subjective human perception yet inferior according to pixel-wise metrics of reconstruction quality, such as PSNR and SSIM. With a regular checkerboard mask, decompressed images were superior as assessed by both subjective and pixel-wise measures. I hypothesized that alternative feature-based measures of reconstruction quality would better support my subjective observations. To test this hypothesis, I fed thumbnail images processed using either bottleneck autoencoder or sparse coding using either checkerboard or random masks into a Deep Convolutional Neural Network (DCNN) classifier. Consistent, with my subjective observations, I discovered that sparse coding with checkerboard and random masks support on average 2.7\% and 1.6\% higher classification accuracy and 18.06\% and 3.74\% lower feature perceptual loss compared to bottleneck autoencoders, implying that sparse coding preserves more feature-based information. The optic nerve transmits visual information to the brain as trains of discrete events, a low-power, low-bandwidth communication channel also exploited by silicon retina cameras. Extracting high-fidelity visual input from retinal event trains is thus a key challenge for both computational neuroscience and neuromorphic engineering. % Here, we investigate whether sparse coding can enable the reconstruction of high-fidelity images and video from retinal event trains. Our approach is analogous to compressive sensing, in which only a random subset of pixels are transmitted and the missing information is estimated via inference. We employed a variant of the Locally Competitive Algorithm to infer sparse representations from retinal event trains, using a dictionary of convolutional features optimized via stochastic gradient descent and trained in an unsupervised manner using a local Hebbian learning rule with momentum. Static images, drawn from the CIFAR10 dataset, were passed to the input layer of an anatomically realistic retinal model and encoded as arrays of output spike trains arising from separate layers of integrate-and-fire neurons representing ON and OFF retinal ganglion cells. The spikes from each model ganglion cell were summed over a 32 msec time window, yielding a noisy rate-coded image. Analogous to how the primary visual cortex is postulated to infer features from noisy spike trains in the optic nerve, we inferred a higher-fidelity sparse reconstruction from the noisy rate-coded image using a convolutional dictionary trained on the original CIFAR10 database. Using a similar approach, we analyzed the asynchronous event trains from a silicon retina camera produced by self-motion through a laboratory environment. By training a dictionary of convolutional spatiotemporal features for simultaneously reconstructing differences of video frames (recorded at 22HZ and 5.56Hz) as well as discrete events generated by the silicon retina (binned at 484Hz and 278Hz), we were able to estimate high frame rate video from a low-power, low-bandwidth silicon retina camera. Error Correction Image Compression Neurally-Inspired Network Model Retinal Ganglion Cell Model Silicon Retina Camera Sparse Coding
230	Avaliação estrutural e quantitativa dos efeitos do envelhecimento sobre o gânglio trigeminal de ratos Wistar / Structural and quantitative evaluation of aging process on trigeminal ganglion of Wistar rats Ricardo Eustáquio da Silva 23 February 2010 (has links) O envelhecimento é uma falha progressiva nos processos fisiológicos celulares, produzindo alterações morfológicas nas células e nos tecidos. No sistema nervoso, produz uma redução no número de neurônios, nas fibras nervosas, principalmente nas arborizações dendríticas e nas espinhas sinápticas, e nas células da glia que, de acordo com sua localização e tipo celular, podem diminuir, permanecer constantes ou mesmo aumentar numericamente. Na presente pesquisa, avaliou-se os efeitos do envelhecimento sobre o gânglio trigeminal (GT) de ratos Wistar em animais jovens (2 meses de vida), adultos (12 meses de vida) e idosos (24 meses de vida). Os GT foram submetidos às técnicas histológicas da hematoxilina e eosina e Picro-sírius, onde avaliou-se, respectivamente, a densidade das células satélites glias (CGS) e o componente colágeno ganglionar. Através da técnica histoquímica da NADH-d, avaliou-se a área do perfil do GT, a área do perfil dos corpos celulares dos neurônios ganglionares e a densidade neuronal. Uma avaliação qualitativa foi também realizada relativamente à imunorreatividade dos neurônios ganglionares à substância P (SP) e ao peptídeo intestinal vasoativo (VIP). A densidade das CGS foi maior nos animais jovens do que nos animais adultos e idosos. Verificou-se, qualitativamente, que à medida que o animal envelhece há uma diminuição das fibras colágenas do tipo III, passando a predominar, nos animais idosos, as fibras do tipo I. A área do perfil celular dos corpos neuronais foi maior nos animais adultos sendo que em todos os grupos predominaram neurônios de tamanho médio, com a área do perfil celular entre 490 e 1100 μm2. A densidade neuronal apresentou-se maior nos animais jovens, e sem variações estatísticas entre os animais adultos e idosos. Em todos os grupos estudados, os neurônios pequenos foram os que apresentaram maior imunorreatividade à SP e ao VIP. / Aging is a progressive failure in cellular physiological processes. It determines morphological changes in cells of different tissues. In the nervous system, a reduction in neuron number and in neuron fibers, mainly in dendritic tree and synaptic, are described. With aging the glial cells may increase or decrease in number or also remain constant. In the present work the effects of aging were evaluated on the trigeminal ganglion (TG) comparing young (2 months age), adult (12 months age) and old rats (24 months age). Histological sections of TG were stained with hematoxilin-eosin technique to determine the density of satellite glial cells and Picro-sirius under polarized light to evaluate the Types I and III of collagen fibers. The NADH-diaphorase technique allowed determining the perycarion area. The immunoreactivity of ganglionar neurons to Substance P (SP) and vasoactive intestinal peptide (VIP) were also qualitatively evaluated. The glial cells density was higher in young and adult animals than in old animals. The type I collagen fibers predominates in ganglia of old animals whereas in the young animals is characteristic the presence of the type III collagen fibers. Although the perycarion area was higher in adult animals the medium-sized neurons predominated in all groups. Their areas ranged from 490 to 1100 μm2. It was also observed that the neuron density was higher in young animals. In the adult and old animals the neuron density was similar. In all groups the immunoreactivity both to SP an VIP was detected mainly in neurons of small perycarion. Células satélites gliais Envelhecimento Fibras colágenas Gânglio trigeminal Imunohistoquímica Aging Collagen fibers Immunohistochemistry Satellite glial cells Trigeminal ganglion

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