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A Cellular Mechanism for Dendritic Spine Loss Following Traumautic Brain Injury in RatLow, Brian 29 July 2009 (has links)
Traumatic brain injury is a leading cause of death and disability in the United States. The injury is often composed of two processes: the primary injury, which can involve irreversible loss of tissue, and the secondary injury, which involves a cascade of reactive processes such as excitotoxicity that occur in the hours and days after the initial insult. Excitotoxic stimulation of neuronal circuits can lead to cellular dysfunction and modulation of neuronal sensitivity. One mechanism of dysfunction involves the calcium-regulated phosphatase, calcineurin. Calcineurin has been shown to be involved in the modulation of the neuronal post-synaptic structures known as dendritic spines. One means by which CaN regulates spine structure is through the dephosphorylation of the down-stream effector proteins such as, cofilin. This study tracks the changes in CaN activity levels as well as the phosphorylation state of cofilin in the cortex and hippocampus in each hemisphere of the laterally injured brain. We report that the lateral brain injury causes an increase in CaN activity in the hippocampus with a corresponding dephosphorylation of cofilin. Trauma-induced changes in CaN follow a slightly different time course in cortical tissue, as there is a biphasic modulation of cofilin that begins with an increased phosphorylation which is followed by an extended dephosphorylation. This dephosphorylation is partially prevented by a single post-injury injection of FK506, a calcineurin inhibitor. Since dephosphorylation of cofilin is a rate-limiting step in dendritic spine collapse, the results of this study demonstrate a potential cellular mechanism through which traumatic brain injury results in altered neuronal function.
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DISRUPTIONS IN THE REGULATION OF EXTRACELLULAR GLUTAMATE IN THE RAT CENTRAL NERVOUS SYSTEM AFTER DIFFUSE BRAIN INJURYHinzman, Jason Michael 01 January 2012 (has links)
Glutamate, the predominant excitatory neurotransmitter in the central nervous system, is involved in almost all aspects of neurological function including cognition, motor function, memory, learning, decision making, and neuronal plasticity. For normal neurological function, glutamate signaling must be properly regulated. Disrupted glutamate regulation plays a pivotal role in the acute pathophysiology of traumatic brain injury (TBI), disrupting neuronal signaling, initiating secondary injury cascades, and producing excitotoxicity. Increases in extracellular glutamate have been correlated with unfavorable outcomes in TBI survivors, emphasizing the importance of glutamate regulation.
The aim of this thesis was to examine disruptions in the regulation of extracellular glutamate after experimental TBI. In these studies, we used glutamate-sensitive microelectrode arrays (MEAs) to examine the regulation of extracellular glutamate two days after diffuse brain injury. First, we examined which brain regions were vulnerable to post-traumatic increases in extracellular glutamate. We detected significant increases in extracellular glutamate in the dentate gyrus and striatum, which correlated to the severity of brain injury. Second, we examined the regulation of extracellular glutamate by neurons and glia to determine the mechanisms responsible for post-traumatic increases in extracellular glutamate. In the striatum of brain-injured rats, we detected significant disruptions in release of glutamate by neurons and significant decreases in the removal of glutamate from the extracellular space by glia. Third, we examined if a novel therapeutic strategy, a viral-vector mediated gene delivery approach, could improve the regulation of extracellular glutamate. Infusion of an adeno-associated virus expressing a glutamate transporter into the rat striatum produced significant improvements in glutamate clearance, identifying a novel strategy to reduce excitotoxicity. Lastly, we examined the translational potential of MEAs as novel neuromonitoring device for clinical TBI research. Overall, these studies have demonstrated the translational potential of MEAs to aid in the diagnosis and treatment of TBI survivors.
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Inhibition of injury-induced cell proliferation in the dentate gyrus impairs cognitive recovery following traumatic brain injuryDaniels, Teresa 27 April 2012 (has links)
Traumatic brain injury (TBI) induces a robust cellular proliferative response among neural stem/progenitor cells (NS/NPCs) in the dentate gyrus of the hippocampus. This proliferative effect is thought to contribute to the innate cognitive recovery observed following TBI. Inhibition of hippocampal neurogenesis impairs cognitive function. Furthermore, enhancement of injury-induced hippocampal neurogenesis via intraventricular administration of basic fibroblast growth factor (bFGF) improves cognitive function in animals following TBI. In this experiment, we investigated the direct association between injury-induced hippocampal neurogenesis and cognitive recovery utilizing an antimitotic agent, arabinofuranosyl cytidine (Ara-C). In this study, adult rats received a moderate lateral fluid percussion injury (LFPI). Immediately following injury, Ara-C with or without bFGF was infused into the lateral ventricle via an osmotic mini-pump for 7 days. To label dividing cells animals received daily single injections of 5-bromo-2'-deoxyuridine (BrdU) at 2-7 days post-injury. To examine the effect of Ara-C on cell proliferation, a group of animals was sacrificed at 1 week following injury. Brain sections were immunostained for BrdU and cell type specific markers, and the number of BrdU+ cells in the hippocampus was assessed by stereology. To examine the effect of inhibition of injury-induced cell proliferation on cognitive recovery, animals were assessed on Morris water maze tasks (MWM) either at 21 to 25 days or 56-60 days post-injury. We found that post-injury Ara-C treatment significantly reduces injury-induced cell proliferation in the DG and abolishes the innate cognitive recovery on MWM performance at 56-60 days post-injury. Additionally, Ara-C diminishes bFGF enhanced cell proliferation in the DG and cognitive recovery following TBI. These results support the causal relationship between injury-induced hippocampal neurogenesis and cognitive functional recovery. Our studies suggest that the post-TBI neurogenic response is an endogenous repair mechanism that contributes to the restoration of hippocampal function post-injury.
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Oligodendrocyte pathology following Traumatic Brain Injury : Experimental and clinical studiesFlygt, Johanna January 2017 (has links)
Traumatic brain injury (TBI) caused by traffic and fall accidents, sports-related injuries and violence commonly results in life-changing disabilities. Cognitive impairments following TBI may be due to disruption of axons, stretched by the acceleration/deceleration forces of the initial impact, and their surrounding myelin in neuronal networks. The primary injury, which also results in death to neuronal and glial cells, is followed by a cascade of secondary injury mechanisms including a complex inflammatory response that will exacerbate the white matter injury. Axons are supported and protected by the ensheathing myelin, ensuring fast conduction velocity. Myelin is produced by oligodendrocytes (OLs), a cell type vulnerable to many of the molecular processes, including several inflammatory mediators, elicited by TBI. Since one OL extends processes to several axons, the protection of OLs is an important therapeutic target post-TBI. During development, OLs mature from oligodendrocyte progenitor cells (OPCs), also present in the adult brain. The aim of this thesis was to investigate white matter pathology, with a specific focus on the OL population, in experimental and clinical TBI. Since the inflammatory response may contribute to OL cell death and OPC proliferation, neutralization of interleukin-1β (IL-1β) was investigated. The lateral and central fluid percussion injury models were used in mice and rats where memory, learning and complex behaviors were investigated by two functional tests. Brain tissue, surgically resected due to life-threatening brain swelling or hemorrhage, from TBI patients was also investigated. Axonal injury, myelin damage, microglia alterations and OPCs and OL cell death were investigated by immunohistochemical techniques. In focal and diffuse experimental TBI, OL cell death was observed in important white matter tracts. OL cell death was accompanied by myelin damage, axonal injury and presence of microglia as well as an increased number of OPCs in both the experimental and human setting. OPCs were found to proliferate in diffuse TBI in mice where both complex behavioral changes and impaired memory were observed. Neutralization of IL-1β normalized and improved these behavioral alterations and also lead to a preserved number of mature OLs although without influencing OPC proliferation. The results provided in this thesis indicate that white matter pathology is a key component of the pathophysiology of TBI. The OPC proliferation may influence regeneration post-injury and might be an important future therapeutic targets for TBI. The present studies also suggest that treatment strategies targeting neuroinflammation may positively influence behavioral outcome and OL cell death in TBI. / <p>(Faculty of Medicine)</p>
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The Role of Cyclooxygenase-2 in Models of Epilepsy and Traumatic Brain Injury : Effects of Selective Cyclooxygenase-2 InhibitorsKunz, Tina January 2002 (has links)
<p>Cyclooxygenase-2 (COX-2) catalyses prostaglandin synthesis from arachidonic acid during inflammation. COX-2 is expressed in the normal brain and is induced in neurological disorders. There is evidence that COX-2 is involved in secondary events leading to cell death in the brain. The first objective was to study the expression of COX-2 in the brain after kainate (KA)-induced limbic seizures and brain trauma caused by controlled cortical contusion (CCC) and fluid percussion injury (FPI). COX-2 mRNA and protein were strongly induced by limbic seizures in the hippocampus, amygdala and piriform cortex. CCC and FPI resulted in an upregulation of COX-2 mainly in the dentate gyrus and cortex, with differences in expression levels in these regions between the models. The second objective was to evaluate the effects of selective COX-2 inhibitors on delayed cell death. Limbic seizures induced cell death in parts of the hippocampus, amygdala and functionally connected regions. Treatment with the selective COX-2 inhibitor rofecoxib 8 h after KA injection significantly reduced hippocampal cell death. Pre-treatment with the COX-2 inhibitor nimesulide augmented acute seizures with increased mortality and thus the effect of nimesulide on delayed cell death could not be evaluated. Effects of rofecoxib on trauma-induced cell death were studied in the FPI model. FPI induced delayed cell death mainly in the ipsilateral cortex and bilaterally in the dentate gyrus. Rofecoxib treatment, starting directly after injury was caused, had no protective effect against cell death. </p><p>The results suggest that COX-2 inhibition may be both detrimental and beneficial and largely dependent on the time schedule of treatment. COX-2 inhibitors might thus be of value as a neuroprotective treatment approach, provided that the role of COX-2 and the time course of effects of its metabolites in the brain are elucidated.</p>
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The Role of Cyclooxygenase-2 in Models of Epilepsy and Traumatic Brain Injury : Effects of Selective Cyclooxygenase-2 InhibitorsKunz, Tina January 2002 (has links)
Cyclooxygenase-2 (COX-2) catalyses prostaglandin synthesis from arachidonic acid during inflammation. COX-2 is expressed in the normal brain and is induced in neurological disorders. There is evidence that COX-2 is involved in secondary events leading to cell death in the brain. The first objective was to study the expression of COX-2 in the brain after kainate (KA)-induced limbic seizures and brain trauma caused by controlled cortical contusion (CCC) and fluid percussion injury (FPI). COX-2 mRNA and protein were strongly induced by limbic seizures in the hippocampus, amygdala and piriform cortex. CCC and FPI resulted in an upregulation of COX-2 mainly in the dentate gyrus and cortex, with differences in expression levels in these regions between the models. The second objective was to evaluate the effects of selective COX-2 inhibitors on delayed cell death. Limbic seizures induced cell death in parts of the hippocampus, amygdala and functionally connected regions. Treatment with the selective COX-2 inhibitor rofecoxib 8 h after KA injection significantly reduced hippocampal cell death. Pre-treatment with the COX-2 inhibitor nimesulide augmented acute seizures with increased mortality and thus the effect of nimesulide on delayed cell death could not be evaluated. Effects of rofecoxib on trauma-induced cell death were studied in the FPI model. FPI induced delayed cell death mainly in the ipsilateral cortex and bilaterally in the dentate gyrus. Rofecoxib treatment, starting directly after injury was caused, had no protective effect against cell death. The results suggest that COX-2 inhibition may be both detrimental and beneficial and largely dependent on the time schedule of treatment. COX-2 inhibitors might thus be of value as a neuroprotective treatment approach, provided that the role of COX-2 and the time course of effects of its metabolites in the brain are elucidated.
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The Role of Calcineurin in Dendritic Remodeling and Epileptogenesis in a Rat Model of Traumatic Brain InjuryCampbell, John 14 February 2012 (has links)
Traumatic brain injury (TBI), a leading cause of death and disability in the United States, causes potentially preventable damage in part through the dysregulation of neural calcium levels. This dysregulation likely affects the activity of the calcium-sensitive phosphatase, calcineurin, with serious implications for neural function. To test this possibility, the present study characterized the role of calcineurin in a rat model of brain trauma, the lateral fluid percussion injury model. Golgi-Cox histochemistry revealed an acute post-TBI loss and delayed overgrowth of dendritic spines on principal cortical cells. The spine loss appeared to require calcineurin activity, since administering a calcineurin inhibitor, FK506, 1 hour after TBI prevented the spine loss. Additional experiments showed how calcineurin activity might be related to the spine loss. Specifically, Western blots and enzyme activity assays revealed an acute increase in the cortical activity of calcineurin and its downstream effector, the actin-depolymerizing protein, cofilin. The cofilin activation was blocked by the same FK506 treatment that prevented spine loss, suggesting a relationship between cofilin activation and spine loss. To investigate long-term consequences of calcineurin activation after TBI, rats were administered FK506 (Tacrolimus) 1 hour after TBI and then monitored for spontaneous seizure activity months later. Acute post-TBI treatment with FK506 reduced the frequency of late non-convulsive seizures but did not prevent late convulsive seizures, cortical atrophy, or thalamic damage. The results of the present study implicate calcineurin in the acute dendritic remodeling and late non-convulsive seizures that occur after TBI. Importantly, these findings reveal calcineurin as a potential therapeutic target in the treatment of TBI and its sequalae.
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Delayed Cell Death after Traumatic Brain Injury : Role of Reactive Oxygen SpeciesClausen, Fredrik January 2004 (has links)
<p>Traumatic brain injury (TBI) is a leading cause of death and disability TBI survivors often suffer from severe disturbances of cognition, memory and emotions. Improving the treatment is of great importance, but as of yet no specific neuroprotective treatment has been found. After TBI there are changes in ion homeostasis and protein regulation, causing generation of reactive oxygen species (ROS). Overproduction of ROS can lead to damage cellmembranes, proteins and DNA and secondary cell death. In the present thesis experimental TBI in rats were used to study the effects of the ROS scavengers α-phenyl-N-tert-butyl-nitrone (PBN) and 2-sulfophenyl-N-tert-butyl-nitrone (S-PBN) on morphology, function, intracellular signalling and apoptosis. </p><p>Posttreatment with PBN and S-PBN resulted in attenuation of tissue loss after TBI and S-PBN improved cognitive function evaluated in the Morris water maze (MWM). Pretreatment with PBN protected hippocampal morphology, which correlated to better MWM-performance after TBI.</p><p>To detect ROS-generation in vivo, a method using 4-hydroxybenzoic acid (4-HBA) microdialysis in the injured cortex was refined. 4-HBA reacts with ROS to form 3,4-DHBA, which can be quantified using HPLC, revealing that ROS-formation was increased for 90 minutes after TBI. It was possible to attenuate the formation significantly with PBN and S-PBN treatment. </p><p>The activation of extracellular signal-regulated kinase (ERK) is generally considered beneficial for cell survival. However, persistent ERK activation was found in the injured cortex after TBI, coinciding with apoptosis-like cell death 24 h after injury. Pretreatment with the MEK-inhibitor U0126 and S-PBN significantly decreased ERK activation and reduced apoptosis-like cell death. Posttreatment with U0126 or S-PBN showed robust protection of cortical tissue.</p><p>To conclude: ROS-mediated mechanisms play an important role in secondary cell death following TBI. The observed effects of ROS in intracellular signalling may be important for defining new targets for neuroprotective intervention.</p>
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Delayed Cell Death after Traumatic Brain Injury : Role of Reactive Oxygen SpeciesClausen, Fredrik January 2004 (has links)
Traumatic brain injury (TBI) is a leading cause of death and disability TBI survivors often suffer from severe disturbances of cognition, memory and emotions. Improving the treatment is of great importance, but as of yet no specific neuroprotective treatment has been found. After TBI there are changes in ion homeostasis and protein regulation, causing generation of reactive oxygen species (ROS). Overproduction of ROS can lead to damage cellmembranes, proteins and DNA and secondary cell death. In the present thesis experimental TBI in rats were used to study the effects of the ROS scavengers α-phenyl-N-tert-butyl-nitrone (PBN) and 2-sulfophenyl-N-tert-butyl-nitrone (S-PBN) on morphology, function, intracellular signalling and apoptosis. Posttreatment with PBN and S-PBN resulted in attenuation of tissue loss after TBI and S-PBN improved cognitive function evaluated in the Morris water maze (MWM). Pretreatment with PBN protected hippocampal morphology, which correlated to better MWM-performance after TBI. To detect ROS-generation in vivo, a method using 4-hydroxybenzoic acid (4-HBA) microdialysis in the injured cortex was refined. 4-HBA reacts with ROS to form 3,4-DHBA, which can be quantified using HPLC, revealing that ROS-formation was increased for 90 minutes after TBI. It was possible to attenuate the formation significantly with PBN and S-PBN treatment. The activation of extracellular signal-regulated kinase (ERK) is generally considered beneficial for cell survival. However, persistent ERK activation was found in the injured cortex after TBI, coinciding with apoptosis-like cell death 24 h after injury. Pretreatment with the MEK-inhibitor U0126 and S-PBN significantly decreased ERK activation and reduced apoptosis-like cell death. Posttreatment with U0126 or S-PBN showed robust protection of cortical tissue. To conclude: ROS-mediated mechanisms play an important role in secondary cell death following TBI. The observed effects of ROS in intracellular signalling may be important for defining new targets for neuroprotective intervention.
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The role of reactive oxygen species in traumatic brain injury : Experimental studies in the ratMarklund, Niklas January 2001 (has links)
Traumatic brain injury (TBI) is a major cause of mortality and disability. As common sequelae in survivors of TBI are disabling functional, emotional and cognitive disturbances, improved treatment of TBI patients is urgently needed. At present, no neuroprotective pharmacological treatment exists. The formation of oxygen-centered free radicals, reactive oxygen species (ROS), is considered an important event in the pathophysiology of TBI. In the present thesis, the fluid percussion (FPI) and controlled cortical contusion injury models of TBI in rats were used. Two nitrone radical scavengers, α-Phenyl-N-tert -butyl nitrone (PBN) and the sulfonated analogue of PBN, 2-sulfophenyl-N-tert-butyl nitrone (S-PBN), were used as tools to study the role of ROS in TBI. Pre-treatment with PBN (30 mg/kg) improved morphological and cognitive outcome after severe controlled cortical contusion injury. Treatment with equimolar doses of PBN and S-PBN administered 30 min after FPI followed by a 24 h intravenous infusion improved morphological outcome. Only S-PBN improved cognitive outcome as assessed in the Morris Water Maze. Surprisingly, pre-treatment with PBN increased the number of apoptotic neurons at 24 hours after injury despite a reduced lesion volume. FPI resulted in an early increase in glucose uptake and a reduction in regional cerebral blood flow (rCBF) assessed by fluoro-2-deoxyglucose (FDG) and hexamethylpropylene amine oxime (HMPAO) autoradiography. At 12 h, a marked reduction in glucose uptake and rCBF ensued. These TBI-induced changes were attenuated by PBN and S-PBN pre-treatment. A method for ROS detection using 4-hydroxybenzoate in conjunction with microdialysis was evaluated. The results showed a marked increase in ROS formation as assessed by an increase in the single adduct 3,4-DHBA, lasting 90 min after injury. In a separate study, PBN and S-PBN equally reduced 3,4-DHBA formation despite no detectable brain concentrations of S-PBN at 30 or 60 min post-injury. In conclusion, ROS play an important role in the injury process after TBI. We report a method for ROS detection with potential clinical utility. Nitrones increased ROS elimination and improved functional and morphological outcome. Nitrone treatment may have a clinical potential as a neuroprotective concept in TBI.
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