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Estudo da regeneração simpática pós simpaticotomia seletiva experimental (ramocotomia) / Study of sympathetic regeneration post experimental selective sympathicotomy (ramicotomy)Humberto Alves de Oliveira 06 March 2009 (has links)
Introdução: A simpatectomia torácica é o único tratamento, definitivo e eficaz, para a hiperidrose primária. A ramicotomia é um procedimento cirúrgico tão eficaz, mais conservador e com menos efeitos adversos que a simpatectomia convencional, contudo foi abandonada pela alta taxa de recidiva, atribuída, até então, à secção incompleta dos ramos comunicantes, ao desenvolvimento de outras vias de condução para o estímulo central e à regeneração neural. A avaliação histológica dos ramos comunicantes simpáticos após a ramicotomia, pode ajudar a entender o processo de recidiva dos sintomas da hiperidrose e, dessa forma contribuir para o desenvolvimento de estratégias para evitá-la. MATERIAL E MÉTODOS: 28 suínos foram submetidos à ramicotomia por videotoracospia e divididos randomicamente em 5 grupos, sacrificados com 15, 45, 90, 135 e 180 dias de pós-operatório (DPO). Os segmentos operados foram removidos cirurgicamente e submetidos à avaliação macroscópica da regeneração assim como análise histológica dos ramos comunicantes brancos e cinzentos para quantificação da reação inflamatória, deposição de fibras de colágeno grossas e finas, fibras reticulares e células de Schwann por imuno-histoquímica. Os dados foram comparados ao grupo controle, composto por segmentos intactos, não operados. RESULTADOS: Não houve regeneração macroscópica no grupo de 15 DPO sendo presente em 41,6% dos casos no grupo 180 DPO (p < 0,05). A reação inflamatória foi determinante no processo de degeneração Walleriana, com presença importante das células de Schwann nos ramos pré-ganglionares (p < 0,05), as células de Schwann apresentaram evolução semelhante nos dois ramos a partir do grupo de 45DPO, mantendo-se em menor número nos ramos cinzentos. As fibras de colágeno foram cruciais na cicatrização e as fibras reticulares importantes na regeneração neural, com correlação negativa entre elas (r = - 0,414; p < 0,01). A deposição de fibras de colágeno foi maior nos ramos cinzentos, apresentando pico de deposição no grupo 135 DPO e declínio importante no grupo 180 DPO (p < 0,05). CONCLUSÕES: A ramicotomia permite a secção completa de todos os ramos comunicantes do gânglio simpático. A taxa de regeneração histológica deve ser maior que a taxa de recidiva dos sintomas no humano, devido a regenerações não funcionais. O processo regenerativo é similar nos ramos brancos e cinzentos, com tendências menores para os últimos. A regeneração dos ramos comunicantes deve ser um dos principais fatores de recidiva da hiperidrose após a ramicotomia / INTRODUCTION: Thoracic sympathectomy is the only definitive and efficient treatment for primary hyperhidrosis. The ramicotomy is a surgical procedure that is as efficient as conventional sympathectomy but more conservative, having less adverse effects then conventional sympathectomy. This procedure was abandoned on account of the high recurrence rate, attributed to the incomplete section of the rami communicantes and to the development of new pathways of conduction to the central stimuli. MATHERIAL AND METHODS: Twenty-eight swine underwent bilateral videothoracoscopic ramicotomy and were randomly divided into 5 groups. The animals were sacrificed at 15, 45, 90, 135 and 180 days post-operative POD. The segments were removed and evaluated for macroscopic regeneration and histological analysis of the white and gray rami communicantes analyzing the inflammatory reaction, deposition of thin and thick collagen fibers, reticular fibers and Schwann cells. The data was compared to intact segments of sympathetic trunk as a positive control. RESULTS: There was neither macroscopic nor microscopic regeneration at the 15 POD group. The remaining groups had an average of 41,6% of regeneration, more significant at the 180 POD group (p<0.05). The inflammatory reaction was crucial in the process of Wallerian degeneration, with an important participation of the Schwann cells in the pre-ganglionic rami (p<0.05). The Schwann cells presented a similar evolution in both rami beginning at the 45 POD group, with a smaller count in the gray rami. The collagen fibers were significant in the cicatrization and the reticular fibers were important in neural regeneration, with a meaningful negative correlation between them (r = - 0,414; p < 0,01). The rate of deposition of the collagen fibers was greater in the white rami when compared to the gray rami in the first trimester and less important in the second trimester (p<0.05). CONCLUSIONS: Ramicotomy allows complete section of all rami communicantes of the sympathetic ganglia. The histological regeneration might be greater than the recurrence rates of clinical symptoms as seen in the human being due to non-functional regenerations. The restoration process is similar in both white and gray rami, with smaller tendencies in the last one. The regeneration of the could be one of the main factors for recurrence of hyperhidrosis following ramicotomy
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Die Auswirkung von verschiedenen Proteasom-Inhibitoren auf die Wallersche Degeneration peripherer Nerven in vitro und in vivo / The effect of different proteasome inhibitors on Wallerian degeneration of peripheral nerves in vivo and in vitroDenninger, Stefan Christoph 04 September 2013 (has links)
No description available.
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Der Einfluss unterschiedlicher Zellkulturmedien auf die Makrophagen in einem Co-Kultur-Modell von Nervengewebe und Peritonealzellen / The differential influence of cell culture media on macrophages in a co-culture model of nerve tissue and peritoneal cells.Schulte, Jana 13 May 2014 (has links)
No description available.
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Molecular Pathways Mediating Glial Responses during Wallerian Degeneration: A DissertationLu, Tsai-Yi 14 May 2015 (has links)
Glia are the understudied brain cells that perform many functions essential to maintain nervous system homeostasis and protect the brain from injury. If brain damage occurs, glia rapidly adopt the reactive state and elicit a series of cellular and molecular events known as reactive gliosis, the hallmark of many neurodegenerative diseases. However, the molecular pathways that trigger and regulate this process remain poorly defined. The fruit fly Drosophila melanogaster has glial cells that are strikingly similar to mammalian glia, and which also exhibit reactive responses after neuronal injury. By exploiting its powerful genetic toolbox, we are uniquely positioned to identify the genes that activate and execute glial responses to neuronal injury in vivo. In this dissertation, I use Wallerian degeneration in Drosophila as a model to characterize molecular pathways responsible for glia to recognize neural injury, become activated, and ultimately engulf and degrade axonal debris. I demonstrate a novel role for the GEF (guanine nucleotide exchange factors) complex DRK/DOS/SOS upstream of small GTPase Rac1 in glial engulfment activity and show that it acts redundantly with previously discovered Crk/Mbc/dCed-12 to execute glial activation after axotomy. In addition, I discovered an exciting new role for the TNF receptor associated factor 4 (TRAF4) in glial response to axon injury. I find that interfering with TRAF4 and the downstream kinase misshapen (msn) function results in impaired glial activation and engulfment of axonal debris. Unexpectedly, I find that TRAF4 physically associates with engulfment receptor Draper – making TRAF4 only second factor to bind directly to Draper – and show it is essential for Draper-dependent activation of downstream engulfment signaling, including transcriptional activation of engulfment genes via the JNK and STAT transcriptional cascades. All of these pathways are highly conserved from Drosophila to mammals and most are known to be expressed in mouse brain glia, suggesting functional conservation. My work should therefore serve as an excellent starting point for future investigations regarding their roles in glial activation/reactive gliosis in various pathological conditions of the mammalian central nervous system.
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Axon Death Prevented: Wld<sup>s</sup> and Other Neuroprotective Molecules: A DissertationAvery, Michelle A. 13 December 2010 (has links)
A common feature of many neuropathies is axon degeneration. While the reasons for degeneration differ greatly, the process of degeneration itself is similar in most cases. Axon degeneration after axotomy is termed ‘Wallerian degeneration,’ whereby injured axons rapidly fragment and disappear after a short period of latency (Waller, 1850). Wallerian degeneration was thought to be a passive process until the discovery of the Wallerian degeneration slow (Wlds) mouse mutant. In these mice, axons survive and function for weeks after nerve transection. Furthermore, when the full-length protein is inserted into mouse models of disease with an axon degeneration phenotype (such as progressive motor neuronopathy), Wlds is able to delay disease onset (for a review, see Coleman, 2005). Wlds has been cloned and was found to be a fusion event of two neighboring genes: Ube4b, which encodes an ubiquitinating enzyme, and NMNAT-1 (nicotinamide mononucleotide adenylyltransferase-1), which encodes a key factor in NAD (nicotinamide adenine dinucleotide) biosynthesis, joined by a 54 nucleotide linker span (Mack et al., 2001).
To address the role of Wlds domains in axon protection and to characterize the subcellular localization of Wlds in neurons, our lab developed a novel method to study Wallerian degeneration in Drosophila in vivo (MacDonald et al., 2006). Using this method, we have discovered that mouse Wlds can also protect Drosophila axons for weeks after acute injury, indicating that the molecular mechanisms of Wallerian degeneration are well conserved between mouse and Drosophila. This observation allows us to use an easily manipulated genetic model to move the Wlds field forward; we can readily identify what Wlds domains give the greatest protection after injury and where in the neuron protection occurs. In chapter two of this thesis, I identify the minimal domains of Wlds that are needed for protection of severed Drosophila axons: the first 16 amino acids of Ube4b fused to Nmnat1. Although Nmnat1 and Wlds are nuclear proteins, we find evidence of a non-nuclear role in axonal protection in that a mitochondrial protein, Nmnat3, protects axons as well as Wlds.
In chapter 3, I further explore a role for mitochondria in Wlds-mediated severed axon protection and find the first cell biological changes seen in a Wlds-expressing neuron. The mitochondria of Wlds- and Nmnat3-expressing neurons are more motile before injury. We find this motility is necessary for protection as suppressing the motility with miro heterozygous alleles suppresses Wldsmediated axon protection. We also find that Wlds- and Nmnat3- expressing neurons show a decrease in calcium fluorescent reporter, gCaMP3, signal after axotomy. We propose a model whereby Wlds, through production of NAD in the mitochondria, leads to an increase in calcium buffering capacity, which would decrease the amount of calcium in the cytosol, allowing for more motile mitochondria. In the case of injury, the high calcium signal is buffered more quickly and so cannot signal for the axon to die.
Finally, in chapter 4 of my thesis, I identify a gene in an EMS-based forward genetic screen which can suppress Wallerian degeneration. This mutant is a loss of function, which, for the first time, definitively demonstrates that Wallerian degeneration is an active process. The mammalian homologue of the gene encodes a mitochondrial protein, which in light of the rest of the work in this thesis, highlights the importance of mitochondria in neuronal health and disease.
In conclusion, the work presented in this thesis highlights a role for mitochondria in both Wlds-mediated axon protection and Wallerian degeneration itself. I identified the first cell biological changes seen in Wlds-expressing neurons and show that at least one of these is necessary for its protection of severed axons. I also helped find the first Wallerian degeneration loss-of-function mutant, showing Wallerian degeneration is an active process, mediated by a molecularly distinct axonal degeneration pathway. The future of the axon degeneration field should focus on the mitochondria as a potential therapeutic target.
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Elevated activity and microglial expression of myeloperoxidase in demyelinated cerebral cortex in multiple sclerosisGray, E., Thomas, T. L., Betmouni, S., Scolding, N., Love, S. January 2008 (has links)
No / Recent studies have revealed extensive cortical demyelination in patients with progressive multiple sclerosis (MS). Demyelination in gray matter lesions is associated with activation of microglia. Macrophages and microglia are known to express myeloperoxidase (MPO) and generate reactive oxygen species during myelin phagocytosis in the white matter. In the present study we examined the extent of microglial activation in the cerebral cortex and the relationship of microglial activation and MPO activity to cortical demyelination. Twenty-one cases of neuropathologically confirmed multiple sclerosis, with 34 cortical lesions, were used to assess microglial activation. HLA-DR immunolabeling of activated microglia was significantly higher in demyelinated MS cortex than control cortex and, within the MS cohort, was significantly greater within cortical lesions than in matched non-demyelinated areas of cortex. In homogenates of MS cortex, cortical demyelination was associated with significantly elevated MPO activity. Immunohistochemistry revealed MPO in CD68-positive microglia within cortical plaques, particularly toward the edge of the plaques, but not in microglia in adjacent non-demyelinated cortex. Cortical demyelination in MS is associated with increased activity of MPO, which is expressed by a CD68-positive subset of activated microglia, suggesting that microglial production of reactive oxygen species is likely to be involved in cortical demyelination.
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Inhibiting Axon Degeneration in a Mouse Model of Acute Brain Injury Through Deletion of Sarm1Henninger, Nils 24 May 2017 (has links)
Traumatic brain injury (TBI) is a leading cause of disability worldwide. Annually, 150 to 200/1,000,000 people become disabled as a result of brain trauma. Axonal degeneration is a critical, early event following TBI of all severities but whether axon degeneration is a driver of TBI remains unclear. Molecular pathways underlying the pathology of TBI have not been defined and there is no efficacious treatment for TBI.
Despite this significant societal impact, surprisingly little is known about the molecular mechanisms that actively drive axon degeneration in any context and particularly following TBI. Although severe brain injury may cause immediate disruption of axons (primary axotomy), it is now recognized that the most frequent form of traumatic axonal injury (TAI) is mediated by a cascade of events that ultimately result in secondary axonal disconnection (secondary axotomy) within hours to days.
Proposed mechanisms include immediate post-traumatic cytoskeletal destabilization as a direct result of mechanical breakage of microtubules, as well as catastrophic local calcium dysregulation resulting in microtubule depolymerization, impaired axonal transport, unmitigated accumulation of cargoes, local axonal swelling, and finally disconnection. The portion of the axon that is distal to the axotomy site remains initially morphologically intact. However, it undergoes sudden rapid fragmentation along its full distal length ~72 h after the original axotomy, a process termed Wallerian degeneration.
Remarkably, mice mutant for the Wallerian degeneration slow (Wlds) protein exhibit ~tenfold (for 2–3 weeks) suppressed Wallerian degeneration. Yet, pharmacological replication of the Wlds mechanism has proven difficult. Further, no one has studied whether Wlds protects from TAI. Lastly, owing to Wlds presumed gain-of-function and its absence in wild-type animals, direct evidence in support of a putative endogenous axon death signaling pathway is lacking, which is critical to identify original treatment targets and the development of viable therapeutic approaches.
Novel insight into the pathophysiology of Wallerian degeneration was gained by the discovery that mutant Drosophila flies lacking dSarm (sterile a/Armadillo/Toll-Interleukin receptor homology domain protein) cell-autonomously recapitulated the Wlds phenotype. The pro-degenerative function of the dSarm gene (and its mouse homolog Sarm1) is widespread in mammals as shown by in vitro protection of superior cervical ganglion, dorsal root ganglion, and cortical neuron axons, as well as remarkable in-vivo long-term survival (>2 weeks) of transected sciatic mouse Sarm1 null axons. Although the molecular mechanism of function remains to be clarified, its discovery provides direct evidence that Sarm1 is the first endogenous gene required for Wallerian degeneration, driving a highly conserved genetic axon death program.
The central goals of this thesis were to determine (1) whether post-traumatic axonal integrity is preserved in mice lacking Sarm1, and (2) whether loss of Sarm1 is associated with improved functional outcome after TBI. I show that mice lacking the mouse Toll receptor adaptor Sarm1 gene demonstrate multiple improved TBI-associated phenotypes after injury in a closed-head mild TBI model. Sarm1-/- mice developed fewer beta amyloid precursor protein (βAPP) aggregates in axons of the corpus callosum after TBI as compared to Sarm1+/+ mice. Furthermore, mice lacking Sarm1 had reduced plasma concentrations of the phosphorylated axonal neurofilament subunit H, indicating that axonal integrity is maintained after TBI. Strikingly, whereas wild type mice exhibited a number of behavioral deficits after TBI, I observed a strong, early preservation of neurological function in Sarm1-/- animals. Finally, using in vivo proton magnetic resonance spectroscopy, I found tissue signatures consistent with substantially preserved neuronal energy metabolism in Sarm1-/- mice compared to controls immediately following TBI. My results indicate that the Sarm1-mediated prodegenerative pathway promotes pathogenesis in TBI and suggest that anti-Sarm1 therapeutics are a viable approach for preserving neurological function after TBI.
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