Global ETD Search

211	CHARACTERIZATION OF THE ROLE AND UNDERLYING MECHANISMS OF TRAUMATIC BRAIN INJURY ON REWARD SEEKING BEHAVIOR USING PRECLINICAL ANIMAL MODELS Cannella, Lee Anne January 2019 (has links) Traumatic brain injury (TBI) is a prominent healthcare concern in the U.S. as millions of TBI-related emergency department visits occur annually. Recent reports estimate more than 5 million Americans currently suffer from life-long disabilities and psychiatric complications associated with TBI. While the risk of TBI has conventionally been considered to be male dominated, analyses of sex-comparable sports indicate that rates of concussions are higher and recovery time is longer following brain injury in females. Following anxiety and depression, substance use disorder (SUD) is the third most common de-novo neuropsychiatric condition diagnosed in both male and female TBI patients. Importantly, during adolescence the primary neuronal networks that regulate reward behaviors and perception of drug-induced euphoria are not fully developed, corroborating epidemiological studies identifying TBI sustained during adolescence as a risk factor for problematic drug use. Yet, to date, little is known about how TBI-induced molecular changes affect brain structures essential for the perception of reward and processing drug-induced euphoria. The following experiments were designed to test the hypothesis that adolescent TBI-induced neuroinflammation in areas such as prefrontal cortex (PFC) and nucleus accumbens (NAc) results in remodeling of neuronal reward networks and affect how the rewarding effects of cocaine shift as a consequence of TBI. Notably, the extent of sex differences in SUD susceptibility in TBI has not be investigated. Therefore, we also investigated whether the immune response stimulated by early-life TBI alters maturation of reward neurocircuits, leading to increased SUD vulnerability in a sex-dependent manner. Following the induction of TBI using the controlled cortical impact (CCI) model of brain injury, we utilized a biased, three-phased cocaine conditioned place preference (CPP) assay to assess the behavioral response to the rewarding effects of cocaine following adolescent injury in male and female C57BL6 mice. Furthermore, we characterized the effect of CCI-TBI on the stimulation of neuroinflammation within the PFC and NAc, comprising the reward pathway. Specifically, our studies revealed a sex-specific increase in 1) sensitivity to the rewarding efficacy of a subthreshold doses of cocaine interpreted from significantly higher cocaine CPP shifts, 2) the activation and phagocytosis of microglia observed by the positive expression of neuronal synaptic proteins in microglia sorted using flow cytometry, 3) increase in permeability of the blood-brain barrier indicated by discontinuous and depleted expression of tight junction proteins that line microvasculature isolated from reward nuclei, 4) decreased neuronal complexity, arborization, and spine density quantified from Golgi-cox stained NAc neurons, 5) changes in expression of genes related to the dopamine system analyzed by qRT-PCR in only male mice injured during adolescence. Additionally, our results imply that high levels of female hormones can promote neuroprotection against increased sensitivity to the rewarding properties of cocaine following injury, associated with decreased neuroinflammatory profiles after TBI in adolescent females. The studies herein aimed to elucidate underlying neuropathological outcomes following TBI in the reward circuitry that could be contributing to increased risk of addiction-like behavior observed clinically. Our findings suggest that TBI during adolescence may enhance the abuse liability of cocaine in adulthood and vulnerability to the rewarding effects of cocaine could be higher as a result of brain injury. Key pathological findings in the NAc such as activated microglial phagocytosis, BBB changes, reduced neuronal complexity, and changes in dopamine gene expression in areas of the reward pathways support the notion that neuroinflammation may contribute to how the rewarding efficacy of cocaine are affected post-TBI during adolescence. The ultimate goal of this research is to 1) advance TBI and SUD literature with the potential to increase awareness and help health care providers inform TBI patients about the increased risk for SUDs, and 2) to translate identified correlated mechanisms into novel targeted therapies that would provide a launching point for the treatment of patients with TBI-related SUD. / Biomedical Sciences Neurosciences Adolescence Animal Models Behavior Neuroinflammation Substance Use Disorders Traumatic Brain Injury
212	Antioxidant enzyme targeting to ICAM-1 improves outcomes following experimental traumatic brain injury Lutton, Evan Mitchel January 2019 (has links) Traumatic brain injury, hereon referred to as TBI, can be simply defined as a disruption to normal brain function as a result of an outside force to the head. TBI contributes to one third of all injury related deaths in the United States, and treatment strategies for TBI are supportive. Although primary and secondary mechanisms of injury have been clearly identified, the heterogeneous and intertwined pathophysiology of TBI is not fully understood. Primary injury results from the impact itself and causes immediate damage. However, secondary mechanisms of injury in TBI, such as oxidative stress and inflammation, are points at which intervention may reduce neuropathology. Trials taking advantage of the antioxidant and anti-inflammatory properties of several agents have had little clinical success, while the use of targeted therapeutics in TBI is relatively unexplored. Evidence suggests that reactive oxygen species (ROS) propagate blood-brain barrier (BBB) hyperpermeability and exacerbate inflammation following TBI. In the studies presented herein, we tested the hypothesis that targeted detoxification of ROS may improve the pathological outcomes using the controlled cortical impact mouse model of TBI. Following TBI, endothelial activation results in a time dependent increase in vascular expression of ICAM-1, an endothelial activation and cell adhesion molecule, as was observed by immunohistochemistry and immunofluorescence staining of isolated cortical microvessels. We conjugated catalase, an antioxidant enzyme, to anti-ICAM-1 antibodies and administered the conjugate intravenously to 8-week-old C57BL/6J mice at 30 minutes after moderate controlled cortical impact TBI. Results indicate that catalase targeted to ICAM-1 reduces markers of oxidative stress including levels of hydrogen peroxide and 3-nitrotyrosine detected in the cortex ipsilateral to the area of injury. Anti-ICAM-1/catalase also preserved BBB permeability based on two assays of barrier permeability to the plasma protein fibrinogen and small fluorescent tracer sodium fluorescein. Following TBI, mice receiving the conjugate exhibited attenuated neuropathological indices for astrocyte and microglia activation as well as cortical neuronal loss compared to controls. For each of these endpoints, anti-ICAM-1/catalase was found to be more effective than anti-ICAM-1 antibodies or catalase administered alone. An extensive study of microglia by two-photon microscopy of ex vivo brain segments from CX3CR1-GFP mice revealed that anti-ICAM-1/catalase prevented the transition of microglia to an activated phenotype after TBI. Finally, anti-ICAM-1/catalase offered functional improvement in Rotarod and elevated zero maze performance compared to controls at acute and chronic time points, respectively. Collectively, these findings demonstrate the use of a targeted antioxidant enzyme to interfere with oxidative stress mechanisms acutely in TBI. The results demonstrate histological and functional benefit of anti-ICAM-1/catalase administration and provide a proof-of-concept approach to improve acute TBI management that may also be applicable to other neuroinflammatory conditions. / Biomedical Sciences Neurosciences Blood-brain Barrier Neuroinflammation Oxidative Stress Targeted Therapy Traumatic Brain Injury
213	EFFECTS OF CANNABINOID 2 RECEPTOR ACTIVATION IN BRAIN MICROVASCULAR ENDOTHELIAL CELLS Bullock, Trent Allen 05 1900 (has links) Across almost all types of neurological pathophysiology, inflammation and corresponding breakdown of the Blood Brain Barrier (BBB) are hallmarks of injury/disease progression. In fact, BBB disruption can occur early during neuropathophysiological development, in many cases even before neurological and cognitive impairments become apparent. Whether as an early causative factor, a side effect, or both as it pertains to neurological injury/disease, BBB breakdown and dysfunction represents a novel and under investigated target for therapeutic development, especially for neurological pathologies with unmet therapeutic needs. Toward this goal, the endocannabinoid system (ECS) has emerged as a promising biological target for drug discovery efforts. Particularly, the Cannabinoid 2 Receptor (CB2R) has been proposed as a druggable target due to its anti-inflammatory effects and since it is not associated with the neurological side effect profile representative of Cannabinoid 1 Receptor (CB1R) drugs. Interestingly, neuroinflammatory conditions promote upregulation of CB2R on brain microvascular endothelial cells (BMVECs) suggesting a possible role toward resolution of inflammation in this cell type. Moreover, previous research has shown promising effects of CB2R agonists on cerebrovascular function, although these effects cannot be directly attributed to endothelial CB2R. The central hypothesis of this research is that endothelial CB2R activation confers effects which are vascular protective and that promote BBB repair, (irrespective of the effects of CB2R in other central nervous system (CNS) cell types). To address this hypothesis, endothelial CB2R expression dynamics were assessed following experimental Traumatic Brain Injury (TBI) followed by a series of assays to assess the therapeutic potential of a novel chromenopyrazole based CB2R agonist, PM289. Results of these experiments demonstrated upregulation of CNR2, the gene which encodes CB2R, following in vivo experimental TBI and in vitro cytokine induced inflammation. Moreover, PM289 exhibited robust CB2R-dependent therapeutic potential by partially restoring TNFa-induced physical barrier disruption, attenuating TNFa-induced ICAM1 upregulation, and promoting rapid monolayer repair following electrolytic wound. Mechanistically, these effects may be explained via CB2R-dependent inhibition of NFkB/P65 signaling. Overall, these results are supportive of the notion that CB2R in BMVECs could aid in vascular protection and promote BBB function in the context of neuroinflammation. Future studies are warranted to understand the in vivo therapeutic efficacy of PM289 in a variety of injury/disease models. Additionally, alternative cell signaling mechanisms should be considered including a comprehensive examination of potential interplay between ECS components and candidates that fall under the umbrella of the endocannabionoidome (ECBome). / Biomedical Sciences Neurosciences Blood brain barrier Cannabinoid 2 receptor CB2R agonist Endothelial cells Neuroinflammation Traumatic brain injury
214	The effect of adolescent binge-like alcohol consumption on cognition-related behaviors and neuroinflammation in adult crossed high alcohol-preferring mice Alisha S Aroor (11191332) 09 September 2024 (has links) <p dir="ltr">Alcohol is the most frequently used drug among adolescents and is commonly consumed through binge drinking. This pattern involves repeated rapid and heavy consumption of alcohol followed by abstinence. Continued binge drinking can result in increased susceptibility to drink during adulthood and a higher risk of adverse health issues, including cognitive impairment. The prefrontal cortex (PFC) and hippocampus (HIPP) are two of the main regions affected by binge drinking, which may lead to individuals experiencing impairment in cognitive processes such as sensorimotor gating and object recognition memory. However, the mechanisms underlying these processes can be complex. Extensive research needs to be conducted to examine the effects adolescent alcohol consumption can have on cognitive processing. A critical note is using an appropriate model to effectively study this relationship. The purpose of this work was to investigate the association between adolescent binge-like alcohol consumption, cognition-related behaviors, and neuroinflammatory responses in crossed high alcohol-preferring (cHAP) mice, a unique selectively bred mouse model for binge alcohol drinking and its consequences in humans.</p><p dir="ltr">Results showed alcohol history mice increased alcohol intake from adolescence to early adulthood, with females displaying faster escalation. Sensorimotor gating was impaired in the alcohol history group at the 112dB pulse intensity one week after alcohol consumption. Alcohol history male mice exhibited impairment in object recognition memory while females did not. IL-1β and TNF-α in the PFC and HIPP did not vary based on alcohol history or sex. These data provide information on the validity of cHAPs as a model of adolescent to early adulthood binge drinking. Our findings allow a foundation for future research to delineate the effect adolescent binge drinking has on various cognitive processes that are modulated by overlapping brain regions. This will aid in not only educating the public to facilitate more conscious actions but also provide potential therapeutic targets and interventions for those with alcohol use disorder (AUD).</p> Behavioural neuroscience Adolescent alcohol Binge drinking Cognition-related behaviors Neuroinflammation Crossed high alcohol-preferring mice
215	Immunologisches Profil und PrPC-Expression von Patienten mit subkortikaler vaskulärer Enzephalopathie und vaskulärem kognitivem Impairment / Immunological profile and PrPC expression of patients with subcortical vascular encephalopathy and vascular cognitive impairment Oikonomou, Panteleimon 21 March 2017 (has links) No description available. 610 Vaskuläre enzephalopathie Vaskuläre kognitive Beeinträchtigung Vaskuläre Demenz Neuroinflammation Zytokine Chemokine Zelluläres Prion-Protein Vascular encephalopathy Vascular cognitive impairment Vascular dementia Neuroinflammation Cytokines Chemokines Cellular prion protein
216	Synthèse de nouvelles sondes moléculaires marquées au fluor-18 pour l’imagerie de la neuroinflammation par Tomographie par Emission de Positons / Synthesis of new molecular probes radiolabelled with fluorine-18 for imaging neuroinflammation with Positon Emission Tomography Médran-Navarrete, Vincent 11 June 2014 (has links) Les travaux présentés dans ce manuscrit ont pour objectifs la synthèse chimique de nouveaux ligands de la protéine de translocation 18 kDa (TSPO), leur évaluation in vitro et le radiomarquage isotopique des candidats les plus prometteurs par l’émetteur de positons à vie brève fluor-18 (t1/2 : 109,8 minutes). Ce travail a pour finalité le développement de nouvelles sondes moléculaires ou biomarqueurs pour l’imagerie non-invasive et atraumatique par Tomographie par Emission de Positons (TEP) de la neuroinflammation, processus reconnu dans les maladies neurodégénératives telles la maladie d’Alzheimer, de Parkinson, la sclérose en plaque et certaines maladies psychiatriques.Le radioligand de choix pour l’imagerie de la TSPO est actuellement le [18F]DPA-714, une pyrazolo[1,5-a]pyrimidine marquée au fluor-18 récemment développée au laboratoire. Cependant, cette molécule subit in vivo la perte rapide de l’atome de fluor radioactif par rupture du motif fluoroalkoxy comme démontrée lors de l’étude de son métabolisme. Mon projet de thèse a donc visé à concevoir et développer de nouveaux dérivés structurellement proches de DPA-714 (analogues) pour lesquelles la liaison entre le squelette principal et le fluor-18 serait renforcée. C’est dans ce cadre que dix-neuf composés ont été préparés et évalués pour leur affinité pour la TSPO, et que deux candidats prometteurs, DPA-C5yne et CfO-DPA-714, ont été radiomarqués au fluor-18 avec de bons rendements radiochimiques (20-30 %) et de hautes radioactivités spécifiques (50-90 GBq/µmol). Ces radioligands ont également été évalués in vivo par imagerie TEP et présentent, chez l’animal, des performances équivalentes voire légèrement supérieures à [18F]DPA-714. / The work presented in this manuscript aims to describe the synthesis of new ligands of the translocation protein 18 kDa (TSPO), their in vitro evaluation and, for the most promising candidates, their isotopic radiolabelling with the short-lived positron emitter fluorine-18 (t1/2 : 109.8 minutes). The ultimate goal of this work consists in developing new molecular probes, or biomarkers, for imaging neuroinflammation in a non-invasive and atraumatic manor using Positron Emission Tomography (PET). Neuroinflammatory processes have been identified in Alzheimer and Parkinson diseases, MS and various psychiatric pathologies.The radioligand of choice for imaging TSPO is currently [18F]DPA-714, a pyrazolo[1,5-a]pyrimidine radiolabelled with fluorine-18 which has been recently prepared in our laboratories. However, [18F]DPA-714 undergoes a rapid in vivo loss of the radioactive fluorine by cleavage of the fluoroalkoxy chain as demonstrated in metabolic studies. Therefore, my PhD project aimed to design and develop new structurally related analogues of DPA-714 where the linkage between the main backbone and the fluorine-18 would be reinforced. To this extent, nineteen compounds were prepared and their affinity towards the TSPO was evaluated. Two promising candidates, coded DPA-C5yne and CfO-DPA-714, were radiolabelled with fluorine-18 with good radiochemical yields (20-30 %) and high specific radioactivities (50-90 GBq/µmol). These radioligands were also evaluated by PET imaging at the preclinical stage and displayed equivalent or slightly improved results when compared to [18F]DPA-714. Chimie médicinale Radiochimie Fluor-18 Imagerie moléculaire Tomographie par Emission de Positons Neuroinflammation TSPO 18 kDa Medicinal chemistry Radiochemistry Fluorine-18 Molecular Imaging Positron Emission Tomography Neuroinflammation TSPO 18 kDa
217	PET molecular imaging of peripheral and central inflammatory processes targeting the TSPO 18 kDa / Imagerie Moléculaire du processus inflammatoire périphérique et central par TEP des en ciblant le TSPO 18kDa Bernards, Nicholas 01 October 2014 (has links) L’objectif de la thèse: À ce jour, il est admis que la TSPO joue un rôle important dans le processus inflammatoire, et qu’il est possible de suivre sa présence à l’aide d’une variété de radiotraceurs adaptés. Les impacts de l’inflammation touchent un grand nombre de personnes à travers le monde pour diverses raisons ; c’est pourquoi, quoique le [ ¹ ⁸F]DPA-714 est très prometteur, il est nécessaire d’aller plus loin pour explorer ses capacités et ses applications possibles. L’inflammation a une forte incidence sur différentes maladies, par conséquent, à impact social élevé (comme la maladie inflammatoire de l’intestin (IBD), la neuroinflammation, et le choc septique). Dans ces modèles nous analyserons et quantifierons les niveaux de d’expression de TSPO 18kDa par imagerie TEP que nous comparerons au niveau exprimé trouvés chez des sujets contrôles. L’objectif étant de déterminer si la TSPO peut constituer une cible biologique d’intérêt pour l’évaluation et la quantification d’un état inflammatoire chez l’individu en utilisant l’imagerie TEP avec le radioligand [ ¹ ⁸F]DPA-714.Aperçu sur le travail de recherche : L’étude entreprise dans cette thèse a fourni des informations conduisant à la conclusion suivante : la TSPO 18kDa peut en effet être utile comme biomarqueur pour l’évaluation d’un état inflammatoire dans plusieurs maladies. Nous avons pu illustrer par l’intermédiaire de deux modèles de la maladie inflammatoire de l’intestin, un modèle de la neuroinflammation et un modèle de choc septique, que la TSPO est un indicateur du niveau de l’inflammation dans la zone affectée. De plus, nous avons pu suivre, mesurer et quantifier l’évolution d’une zone inflammée en fonction du temps.Bien que le [ ¹ ⁸F]DPA-714 est le traceur utilisé pour déterminer la présence et le niveau de l’inflammation, d’autres traceurs sont constamment en cours de développement. Cela est démontré par le travail de collaboration effectuée avec l’équipe de radiochimie, dans lequel nous avons illustré le potentiel d’un nouveau radioligand de TSPO, le [ ¹ ⁸F]DPA-C5yne. / Purpose : The purpose of this study was to determine the in vivo potential of the TSPO 18 kDa as a biomarker of inflammation, with the use of its radioligand [ ¹ ⁸F]DPA-714, to non-invasively quantify the inflammatory state within the scope of various pathologies. Procedure : Multiple animal models of various inflammatory diseases, to include : inflammatory bowel disease, neuroinflammation, and septic shock, were developed and put in place by adapted measures. The animals well-being and the subsequent inflammation was evaluated. The inflammatory state was measured using quantitative PET imaging with the TSPO radioligand [ ¹ ⁸F]DPA-714 and correlated to the expression of conventional inflammatory markers using microscopy. Results : Based on the observed data, we were able to distinguish control groups from treated groups when using [ ¹ ⁸F]DPA-714. This TSPO radioligand permitted us to quantify the inflammatory level and to observe evolutionary changes in the inflammatory state of the disease in multiple models. The PET results, using the [ ¹ ⁸F]DPA-714 signal was correlated with an increased TSPO expression at cellular level. Conclusion : Results indicate that [ ¹ ⁸F]DPA-714 is a suitable tracer for studying inflammation of multiple diseases.[ ¹ ⁸F]DPA-714 could be a good molecular probe to non-invasively evaluate the level and localization of inflammation. Moreover, in vivo imaging using this TSPO ligand is potentially a powerful tool to stage and certainly to follow the evolution and therapeutic efficiency at molecular level in inflammatory diseases. Inflammation TSPO 18 kDa Imagerie TEP [¹⁸F]DPA-714 Maladies inflammatoires de l’intestin Neuroinflammation Choc septique Inflammation TSPO 18 kDa PET imaging [¹⁸F]DPA-714 Inflammatory Bowel Diseases Neuroinflammation Septic Shock
218	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. Gm-Csf Neuroinflammation Neuroplasticité Microglie Mastocytes Cicatrice gliale Lésion spinale Récupérations fonctionnelles Réorganisations corticales Rat adulte Gm-Csf Neuroinflammation Neuroplasticity Microglia Mast cells Glial scar Spinal cord injury Functional recovery Cortical reorganization Adult rat
219	Neuroprotection in the Injured Spinal Cord : Novel Strategies using Immunomodulation, Stem cell Transplantation and Hyaluronic acid Hydrogel carriers Schizas, Nikos January 2015 (has links) The overall aim of this thesis was to establish strategies to minimize secondary damage to the injured spinal cord. Secondary damage that follows spinal cord injury (SCI) involves inflammatory and excitotoxic pathways. Regulation of these pathways using immunomodulatory and neuroprotective substances potentially protects the injured spinal cord from further damage. We also developed and studied resorbable biomaterials to be used as carriers for potential neuroprotectants to the injured spinal cord. We used transversal spinal cord slice cultures (SCSCs) derived from postnatal mice as a model. SCSCs were maintained on different biomaterials and were studied after treatment with immunomodulatory and/or neurotrophic factors. They were further excitotoxically injured and subsequently treated with interleukin-1 receptor antagonist (IL1RA) or by neural crest stem cell (NCSC)-transplantation. The results show that biocompatible and resorbable hydrogels based on hyaluronic acid (HA) preserved neurons in SCSCs to a much higher extent than a conventional collagen-based biomaterial or standard polyethylene terephthalate (PET) membrane inserts. Glial activation was limited in the cultures maintained on HA-based hydrogel. The anti-inflammatory factor IL1RA protected SCSCs from degenerative mechanisms that occur during in vitro incubation, and IL1RA also protected SCSCs from excitotoxic injury induced by N-Methyl-d-Aspartate (NMDA). IL1RA specifically protected neurons that resided in the ventral horn, while other neuronal populations such as dorsal horn neurons and Renshaw cells did not respond to treatment. Finally, transplantation of NCSCs onto excitotoxically injured SCSCs protected from neuronal loss, apoptosis and glial activation, while NCSCs remained undifferentiated. The results presented in this thesis indicate that carriers based on HA seem to be more suitable than conventional collagen-based biomaterials since they enhance neuronal survival per se. The observed neuroprotection is likely due to biomechanical properties of HA. IL1RA protects SCSCs from spontaneous degeneration and from NMDA-induced injury, suggesting that excitotoxic mechanisms can be modulated through anti-inflammatory pathways. Different neuronal populations are affected by IL1RA to various degrees, suggesting that a combination of different neuroprotectants should be used in treatment strategies after SCI. Finally, NCSCs seem to protect SCSCs from excitotoxic injury through paracrine actions, since they remain undifferentiated and do not migrate into the tissue during in vitro incubation. It seems that combinations of neuroprotectants and carrier substances should be considered rather than one single strategy when designing future treatments for SCI. Incorporation of neuroprotectants such as IL1RA combined with stem cells in injectable biocompatible carriers based on HA is the final goal of our group in the treatment of SCI. Hyaluronic Acid-based hydrogel motorneurons microglial cells Interleukin-1 Receptor Antagonist Renshaw cells excitotoxicity neuroinflammation Neural Crest Stem Cells
220	Implications of Heparan Sulfate and Heparanase in Inflammatory Diseases Digre, Andreas January 2017 (has links) Heparan sulfate (HS), an unbranched sulfated carbohydrate chain, and the HS-degrading enzyme heparanase play important roles in physiological and pathological processes during all stages of life, from early embryogenesis to ageing. Accumulated information shows that HS and heparanase are involved in inflammatory processes and associated diseases, e.g. rheumatoid arthritis (RA) and Alzheimer’s disease. In this thesis I have investigated the role of HS and heparanase (Hpa) in inflammatory-related pathologies. In the first project, Hpa overexpressing mice (Hpa-tg) were induced with a murine model of RA. We found a pro-inflammatory role of Hpa through enhancing the activity of T-cells and innate immune cells, which contributed to an augmented severity of clinical symptoms in the Hpa-tg mice. In my second project, we revealed co-current interaction of heparin with both ApoA1 and SAA of HDL isolated from plasma of inflamed mouse. Mass spectrometry analysis indicated close proximity of ApoA1 and SAA on the HDL surface, providing a molecular and structural mechanism for the simultaneous binding of heparin to apoA1 and SAA. In my third project, we investigated the role of Hpa in AA amyloid formation and resolution in mice in a model of AA-amyloidosis. We found a similar degree of amyloid formation in Hpa-KO mice compared to the wildtype control mice, but the resolution process was faster in Hpa-KO mice. The rapid clearance of deposited SAA in Hpa-KO mice was associated with upregulated expression of matrix metalloproteases. The results suggest an associated function of ECM proteases with heparanase in the process of AA amyloid resolution. In my fourth project, we found that overexpression of heparanase impaired inflammation associated beta amyloid (Aβ) clearance in the brain of an Alzheimer’s disease mouse model. Examination of the cytokine profile of brain lysates revealed an overall lower inflammatory reaction in the double transgenic (tgHpa*Swe) mice compared to single APP-tg (tg-Swe) mice in response to LPS-induced inflammation. Heparanase Heparan sulfate Inflammation Inflammatory diseases Autoimmune diseases Amyloidosis Reumathoid arthritis SAA APP A beta Neuroinflammation Basic Medicine Medicinska grundvetenskaper

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