Global ETD Search

191	Cholesterol metabolism in the Niemann-Pick Type C brain Peake, Kyle 06 1900 (has links) Niemann-Pick Type C (NPC) disease is an autosomal recessive disorder that results in accumulation of unesterified cholesterol in late endosomes/lysosomes (LE/Ls), leading to progressive neurodegeneration and premature death. Microglia are resident immune cells of the central nervous system, which upon activation can secrete potentially neurotoxic molecules such as tumor necrosis factor-alpha (TNFα). Inappropriate activation of microglia has been implicated in NPC disease. Primary microglia cultures from the cerebral cortex of Npc1-/- mice have an altered cholesterol distribution characteristic of NPC-deficient cells. Immunocytochemical analysis revealed increased TNFα staining in Npc1-/- microglia. However, Npc1-/- and Npc1+/+ microglia showed similar mRNA levels of pro-inflammatory cytokines and similar levels of TNFα secretion. To determine whether Npc1-/- microglia contribute to neuron death in NPC disease, microglia were co-cultured with cerebellar granule cells. Surprisingly, the extent of neuronal death was the same in neurons cultured with Npc1+/+ or Npc1-/- microglia. Thus, Npc1-/- microglia have an altered phenotype compared to Npc1+/+ microglia, but this does not lead to neuron death in an in vitro co-culture system. Treatment options for NPC disease remain limited. A consequence of cholesterol sequestration in the LE/Ls, is that cholesterol movement to the endoplasmic reticulum, where cholesterol metabolism is regulated, is impaired. Cyclodextrin (CD), a compound that binds cholesterol, has recently been found to delay the onset of neurological symptoms and prolong life of Npc1-/- mice. Since the brain consists of both neurons and glia, it remains unclear if CD acts directly on neurons and/or other cells in the brain. Neurons cultured from the cerebellum and astrocytes cultured from the cortex of Npc1-/- mice were treated with a low dose (0.1mM) of CD. This treatment decreased cholesterol sequestration and decreased the rate of cholesterol synthesis in Npc1-/- neurons and astrocytes. CD also decreased mRNAs encoding proteins involved in cholesterol synthesis in Npc1-/- neurons and increased genes involved in cholesterol efflux in Npc1-/- astrocytes. Moreover, CD increased cholesterol esterification in Npc1-/- astrocytes. These results suggest that cholesterol trapped in LE/Ls in Npc1-/- neurons and astrocytes was released by CD treatment and reached the ER, thereby regulating cholesterol homeostasis. / Experimental Medicine Niemann Pick Type C cyclodextrin microglia inflammation tumor necrosis factor neurodegeneration NPC cholesterol neurons astrocytes
192	PET and the Multitracer Concept: An Approach to Neuroimaging Pathology Engler, Henry January 2008 (has links) Patients suffering from different forms of neurodegenerative diseases, such as: Creutzfeldt Jacob Disease (CJD), Alzheimer disease (AD), mild cognitive impairment (MCI), frontotemporal dementia and Parkinson’s disease (PD) were examined with Positron Emission Tomography (PET) and the combination of different radiotracers: 15O-water, N-[11C-methyl]-L-deuterodeprenyl (DED), [18F] 2-fluorodeoxyglucose: (FDG), N-methyl-[11C]2-(4-methylaminophenyl)-6-hydroxybenzothiazole (PIB) and L-[11C]-3,4-dihydroxiphenyl-alanine (DOPA). The radiotracers and the combinations of different radiotracers were selected with the intention to detect, in the brain, patterns of neuronal dysfunction, astrocytosis, axon degeneration or protein aggregation (amyloid), in the brain which are pathognomonic for specific diseases and may contribute to improve clinical differential diagnoses. Examinations in healthy volunteers were performed to allow comparisons with patients. In addition, animal studies were conducted to complement the information. In some cases, the PET findings could be compared with the results of autopsies. In contrast to the micropathology, in which only a limited part of a tissue (obtained post-mortem or by biopsy) is inspected, one PET acquisition provides an image of the whole system (e.g.: the brain and the cerebellum). This form of imaging pathology is “in vivo”, where the examination is innocuous for the patient. This thesis is an attempt to stimulate the development of new tracers, new tracer combinations and methods that directly or indirectly describe the anatomo-physiopathological changes produced in the brain in neurodegenerative diseases. A better description of different diseases can be obtained, confirming or questioning the clinical diagnoses and widening our understanding of the mechanisms underlying neurodegeneration. Different pathologies can produce similar symptoms and thus causing confusion regarding clinical diagnosis. The used PET combinations improved the accuracy of the diagnoses. The incipient knowledge emerging from a new neuroimaging pathology in combination with other disciplines may open the way to new classifications of dementias and neurodegenerative diseases based on an “in vivo” pathology. Neurosciences PET (Positron Emission Tomography) multitracer neuroimaging pathology astrocytes microglia neurodegeneration amyloid AD CJD PD Neurovetenskap
193	On dopamine neurons : nerve fiber outgrowth and L-DOPA effects af Bjerkén, Sara January 2008 (has links) Parkinson’s disease is a disorder mainly characterized by progressive degeneration of dopamine producing neurons in the substantia nigra of the midbrain. The most commonly used treatment strategy is to pharmacologically restore the lost function by the administration of the dopaminergic precursor L-DOPA. Another treatment strategy is to replace the degenerated neurons with immature fetal ventral mesencephalic tissue, or ultimately stem cell-derived tissue. Grafting trials have, however, revealed poor reinnervation capacity of the grafts, leaving much of the striata dopamine-denervated. An additional drawback is the upcoming of dyskinesia (involuntary movements), a phenomenon also observed during L-DOPA treatment of Parkinson’s disease patients. Attempts to characterize nerve fiber formation from dopamine neurons have demonstrated that the nerve fibers are formed in two morphologically diverse outgrowth patterns, one early outgrowth seen in the absence of astrocytes and one later appearing outgrowth seen in co-existence with astrocytes. The overall objective of this thesis has been to study the dopaminergic outgrowth including guidance of nerve fiber formation, and to look into the mechanisms of L-DOPA-induced dyskinesia. The first paper in this thesis characterizes the different outgrowth patterns described above and their relation to different glial cells. The study demonstrated the two different outgrowth patterns to be a general phenomenon, applying not only to dopamine neurons. Attempts of characterization revealed no difference of origin in terms of dopaminergic subpopulations, i.e. A9 or A10, between the outgrowth patterns. Furthermore, the “roller-drum” technique was found optimal for studying the dual outgrowth sequences. The second and the third paper also utilized the “roller-drum” technique in order to promote both patterns of neuronal fiber formation. The effects of glial cell line-derived neurotrophic factor (GDNF) on the formation of dopamine nerve fibers, was investigated. Cultures prepared from gdnf knockout mice revealed that dopaminergic neurons survive and form nerve fiber outgrowth in the absence of GDNF. The dopaminergic nerve fibers exhibited an outgrowth pattern consistent with that previous observed in rat. GDNF was found to exert effect on the glial-associated outgrowth whereas the non-glial-associated was not affected. Astrocytic proliferation was inhibited using cytosine β-D-arabinofuranoside, resulting in reduced glial-associated outgrowth. The non-glial-associated dopaminergic outgrowth was on the other hand promoted, and was retained over longer time in culture. Furthermore, the non-glial-associated nerve fibers were found to target the fetal frontal cortex. Different developmental stages were shown to promote and affect the outgrowths differently. Taken together, these data indicate and state the importance of astrocytes and growth factors for neuronal nerve fiber formation and guidance. It also stresses the importance of fetal donor age at the time for transplantation. The fourth and fifth studies focus on L-DOPA dynamics and utilize in vivo chronoamperometry. In study four, 6-OHDA dopamine-depleted rats were exposed to chronic L-DOPA treatment and then rated as dyskinetic or non-dyskinetic. The electrochemical recordings demonstrated reduced KCl-evoked release in the intact striatum after chronic L-DOPA treatment. Time for maximal dopamine concentration after L-DOPA administration was found to be shorter in dyskinetic animals than in non-dyskinetic animals. The serotonergic nerve fiber content in the striatum was evaluated and brains from dyskinetic animals were found to exhibit significantly higher nerve fiber density compared to non-dyskinetic animals. Furthermore, the mechanisms behind the conversion of L-DOPA to dopamine in 6-OHDA dopamine-depleted rats were studied. Local administration of L-DOPA in the striatum increased the KCl-evoked dopamine release in the intact striatum. Acute application of L-DOPA resulted sometimes in a rapid conversion to dopamine, probably without vesicle packaging. This type of direct conversion is presumably occurring in non-neuronal tissue. Furthermore, KCl-evoked dopamine releases were present upon local application of L-DOPA in the dopamine-depleted striatum, suggesting that the conversion to dopamine took place elsewhere, than in dopaminergic nerve fibers. In conclusion, these studies state the importance of astrocytes for neuronal nerve fiber formation and elucidate the complexity of L-DOPA conversion in the brain. dopamine nerve fiber outgrowth astrocytes ventral mesencephalon GDNF L-DOPA L-DOPA induced dyskinesia Neurobiology Neurobiologi
194	The Impact of Enriched environment on Lipid metaboilsm after Experimental Stroke Kuric, Enida January 2009 (has links) Stroke is the major cause of serious long-term disability with a sufficient acute treatment for only a very limited number of patients. Limited recovery of neurological functions occurs and can be elevated by a permissive post-stroke milieu. Housing animals in an enriched environment modulates regenerative mechanisms in the nonischemic peri-infarct area which might be an attractive target for pharmacological treatments to promote recovery. Upon ischemia, cellular lipids are released due to massive cell damage and free lipids significantly contribute to the progression of acute and delayed cell death. The aim of this study was to evalute the effect of enriched environment on lipid metabolism. In particular we characterize the activation of the transcription factor liver X receptor (LXR) in glial scar formation and regulation of cholesterol balance of relevance for functional recovery following stroke. Brain tissues from animals subjected to permanent occlusion of middle cerebral artery (pMCAo) were analysed for LXRα and β protein expression. We found an upregulation and an increased transcriptional activity of LXRβ in the peri-infarct area of rats housing in an enriched environment following pMCAO. Our data anticipate that enriched environment may have positive effects on lipid recycling in the ischemic hemisphere following experimental stroke. lipid metabolism liver X receptor recovery enriched environment astrocytes apoE cerebral ischemia stroke
195	Acides gras polyinsaturés n-3 (AGPI n-3) e prévention des dommages cérébraux induits par un stress chronique Hennebelle, Marie 06 April 2012 (has links) (PDF) L'équilibre alimentaire entre les AGPI n-6 et les AGPI n-3 joue probablement un rôle important dans le fonctionnement du système nerveux central et notamment dans la régulation de la neurotransmission. Des études suggèrent qu'une déficience en AGPI n-3 renforcerait la sensibilité des individus à des agressions de type chronique, tel que le stress ou le vieillissement. Notre objectif était de caractériser l'impact des apports alimentaires en AGPI n-3 sur la réponse à un stress chronique. Pour cela, la régulation de paramètres biochimiques, comportementaux et électrophysiologiques par un stress chronique de contention a été évaluée chez le rat recevant différents apports alimentaires en AGPI n-3 (déficients en AGPI n-3 ; équilibrés ; enrichis en AGPI-LC n-3). L'influence des glucocorticoïdes (hormones impliquées dans la réponse au stress) et des AGPI sur des fonctions cellulaires participant à la transmission synaptique a été analysée in vitro par des mesures de libération de neurotransmetteurs sur la lignée neuroblastique SH_SY5Y et par l'analyse des propriétés régulatrices astrocytaires en culture primaire.Nos résultats montrent que, chez le rat, la réponse au stress est modulée par les apports alimentaires en AGPI n-3 : la déficience en AGPI n-3 accentue la sensibilité au stress, notamment la réduction de l'activité locomotrice et la sensibilité aux environnements anxiogènes ; à l'inverse, l'enrichissement en AGPI-LC n-3 atténue la réponse au stress chronique, en réduisant la perte de poids, le pic de corticostérone plasmatique et la réponse émotionnelle. Comme le suggèrent les résultats obtenus in vitro, ces effets sont liés à des régulations complexes par les AGPI et les glucocorticoïdes des paramètres de libération de neurotransmetteur, de la plasticité morphologique astrocytaire et de la capacité de capture du glutamate par les astrocytes. AGPI n-3 Stress chronique Cerveau Comportement Électrophysiologie Neurones Astrocytes
196	Die Rolle und Funktionsweise der Chemokinrezeptoren CXCR4 und CXCR7 in Mikroglia und Astrozyten Lipfert, Jana 19 July 2013 (has links) (PDF) Das Chemokin SDF-1 spielt eine wichtige Rolle bei der Hämatopoese, bei Immunreaktionen sowie bei der Entwicklung des Herzens, der Extremitätenmuskulatur und des zentralen und peripheren Nervensystems. Lange Zeit galt CXCR4 als der einzige Chemokinrezeptor für SDF-1, bis vor wenigen Jahren CXCR7 als ein alternativer Rezeptor für SDF-1 identifiziert wurde. Da alle Zelltypen des zentralen Nervensystems (ZNS) sensitiv für SDF-1 sind, sollte in dieser Arbeit die Funktion der beiden Rezeptoren in primärer Mikroglia und primären Astrozyten untersucht werden. Bisher konnte CXCR7 nur als Scavenger-Rezeptor für SDF-1 oder als atypischer Chemokinrezeptor nachgewiesen werden. Die Untersuchungen ergaben einen mitogenen und chemotaktischen Effekt von SDF-1 auf primäre Mikroglia, wobei sowohl CXCR4 als auch CXCR7 für das SDF-1-Signalverhalten essentiell sind. Nach Aktivierung von Mikroglia in vitro und in vivo wurden beide Rezeptoren verstärkt expremiert. In primären Astrozyten ergab sich ein ligandenabhängiges Signalverhalten von CXCR7. So führte die Bindung von SDF-1 an CXCR7 zu einer Aktivierung von G-Proteinen, während die Kopplung von interferon-inducible T cell alpha chemoattractant (I-TAC), als zweiten Liganden von CXCR7, eine Signalweiterleitung über ß-Arrestin2 zur Folge hatte. Zudem konnte die G-Protein-gekoppelte Rezeptorkinase (Grk)2 als ein positiver Regulator des SDF-1-CXCR7-Signalverhaltens in Astrozyten identifiziert werden. Chemokine Chemokinrezeptoren Mikroglia Astrozyten Ischämie chemokines stroke microglia astrocytes ddc:610
197	Distribution of Nitric Oxide Synthase Isoforms in Neurons and Glial Cells Under Physiological or Pathological Conditions in the Rostral Ventrolateral Medulla of the Rat Tsai, Po-chuan 15 August 2005 (has links) The rostral ventrolateral medulla (RVLM) regulates vasomotor activity via sympathoexcitation and sympathoinhibition to maintain blood pressure. Nitric oxide synthesized by nitric oxide synthase (NOS) I and NOS II within RVLM is responsible for sympathoexcitation and sympathoinhibition respectively. In our previously study, under physiological condition RVLM neurons contain both NOS I and NOS II protein, and NOS III protein is expressed mainly on blood vessels. Under Mevinphos (Mev) intoxication, our previously study demonstrates that the expression of RVLM NOS I and II mRNA or protein are both increased under Mev intoxication phase I, and NOSII mRNA or protein are further increased under Mev intoxication phase II. On the other hand, in rat central nervous system, about 65% of total cells are glial cells, including astrocytes, microglia and oligodendrocytes. However, the expressions of NOS isoforms in RVLM glial cells still need to be determined. We used double immunofluorescence staining and confocal microscopy to investigate the distributions of NOS isoforms protein in RVLM neurons and glial cells under physiological condition and under pathological condition using Mev intoxication as our model. We further compared the distributions of NOS isoforms in RVLM neurons and glial cells under physiological or pathological conditions. The confocal images indicate that NOS I protein reactivity co-localized with neurons and microglia in the RVLM. NOS II protein reactivity co-localized with neurons, astrocytes and microglia. NOS III protein reactivity co-localized with blood vessels and microglia. The distributions of NOS isoforms protein reactivity in RVLM neurons and glial cells under Mev intoxication are the same as under physiological condition. Furthermore, the expressions of NOS I protein within neurons or microglia and NOS II in neurons, astrocytes or microglia are progressively increased under Mev intoxication. On the other hand, the expression of NOS III within microglia under Mev intoxication was similar to physiological condition. The population of NOS I-positive neurons or microglia, and NOS II-positive neurons, astrocytes or microglia increased under Mev intoxication. However the population of NOS III-positive microglia decreased under Mev intoxication. These results indicate that within RVLM, the distributions of NOS I are in neurons and microglia; NOS II are in neurons, astrocytes and microglia; NOS III are in blood vessels and microglia. We suggest that under Mev intoxication, the source of up-regulated NOS I protein includes neurons and microglia; and the up-regulated NOS II protein comes from neurons, astrocytes and microglia. Mevinphos glial cells astrocytes oligodendrocyte rostral ventrolateral medulla neurons microglia nitric oxide
198	The coordinated plasticity of astrocytes and synapses in learning and post-stroke recovery Kim, Soo Young, 1980- 09 June 2011 (has links) Stroke typically occurs in one hemisphere and often results in long-term disability in the contralateral body side (paretic side). Greater reliance on the non-paretic body side is used to compensate for this disability. Meanwhile, the brain undergoes degenerative and plastic changes in both hemispheres. Many previous studies have investigated post-stroke brain plasticity, and explored how it is shaped by behavioral experiences, to better understand the mechanisms of functional recovery. However, these studies have primarily focused on neurons and synapses. Given the abundant evidence that astrocytes actively control activity and plasticity of synapses, it seems reasonable to investigate how astrocytes are involved in behavior- and injury-driven brain plasticity. The central hypothesis of these studies is that synaptic plasticity underlying motor skill learning and post-stroke motor rehabilitation is coordinated with structural and functional plasticity of perisynaptic astrocytes. This was tested in a rat model of motor learning and "re-learning" after unilateral stroke-like damage to sensorimotor cortex. In the contralesional homotopic cortex, astrocytic volume varied with lesion size, as did the number of synapses. In the remaining motor cortex of the injured hemisphere, rehabilitative training with the paretic limb increased the proportion of astrocytic membrane apposed with synapses along with density of synapses. Furthermore, the percentage of synapses with astrocytic contacts was significantly correlated with functional outcome. Training with the non-paretic limb also induced greater synaptic density than controls in peri-infarct cortex, but functional outcome was negatively correlated with this and was not correlated with astrocytic contacts with synapses. These findings suggest that plasticity of, and association between, synapses and astrocytes vary with the type of experiences. Moreover, pharmacological upregulation of astrocytic glutamate uptake, which is one of the key ways that astrocytes modulate synaptic activity, interfered with functional recovery, supporting a critical role for astrocytic glutamate uptake in functional outcome following a stroke. Taken together, these studies contribute to better understanding of how lesions and experiences affect plasticity of astrocytes and synapses. These findings suggest that post-injury experiences alter astrocytic association with synapses, and that the coordinated plasticity of astrocytes and synapses is likely to be a critical mediator to functional outcome. / text Motor rehabilitation Forelimb behavior Stroke Perisynaptic astrocytes Stereology Motor cortex Cerebrovascular disease Neuroplasticity Motor ability
199	Effects of glial cell line-derived neurotrophic factor (GDNF) on mouse fetal ventral mesencephalic tissue Nevalainen, Nina January 2008 (has links) The symptoms of Parkinson's disease occur due to degeneration of dopamine neurons in substantia nigra. It has been demonstrated that glial cell line-derived neurotrophic factor (GDNF) is a potent neurotrophic factor when it comes to protect and enhance survival of dopamine neurons in animal models of Parkinson's disease. The aim of this study was to evaluate short- and long-term effects of GDNF on survival and nerve fiber outgrowth of dopamine cells and astrocytic migration in mouse fetal ventral mesencephalic (VM) tissue. Primary tissue cultures were made of mouse fetal VM tissue and evaluated at 7 and 21 days in vitro (DIV) in terms of dopaminergic nerve fiber outgrowth and astrocytic migration when developed with GDNF present, partially, or completely absent. The results revealed that VM tissue cultured in the absence of GDNF did not exhibit any significant differences in migration of astrocytes or dopaminergic nerve fiber outgrowth neither after 7 DIV nor after 21 DIV, when compared with tissue cultured with GDNF present. Migration of astrocytes and dopaminergic nerve fiber outgrowth reached longer distances when tissue was left to develop for 21 DIV in comparison with 7 DIV. In order to study the long-term effects of GDNF, mouse fetal dopaminergic tissue was transplanted into the ventricles of adult mice and evaluated after 6 months. No surviving dopamine neurons were present in the absence of GDNF. In contrast dopamine neurons developed with GDNF did survive, indicating that GDNF is an essential neurotrophic factor when it comes to long-term dopamine cell survival. More cases have to be assessed in the future in order to strengthen the findings. Thus, transplanted dopamine neurons will be assessed after 3 and 12 months in order to map out when dopamine neurons deprived of GDNF undergo degeneration. Parkinson's disease dopamine ventral mesencephalon astrocytes Chemical engineering Kemiteknik
200	Applications of Focused Ultrasound for Reducing Amyloid-β in a Mouse Model of Alzheimer's Disease Jordao, Jessica F. 10 January 2014 (has links) Focused ultrasound (FUS) can temporarily increase blood-brain barrier (BBB) permeability and locally deliver therapeutic agents to the brain. To date, applications of FUS for treatment of Alzheimer’s disease (AD) have not been explored. Here, I propose that FUS can facilitate a rapid reduction in amyloid-β peptide (Aβ) pathology in a mouse model of AD. Firstly, FUS was used to enhance delivery of an antibody directed against Aβ, which aggregates and forms extracellular plaques. FUS mediated the delivery of antibodies to the targeted right cortex by 4 hours post-treatment and antibodies remained bound to Aβ plaques for 4 days. At 4 days post-treatment, stereological quantification of plaque burden demonstrated a significant reduction of 23%. Secondly, FUS treatment alone resulted in a significant reduction in plaque load (13%). I then investigated effects of FUS that may contribute to Aβ plaque reduction, specifically the delivery of endogenous antibodies to the brain and, activation of microglia and astrocytes. Endogenous immunoglobulin was found bound to plaques within the treated cortex at 4 days post-FUS. Western blot analysis confirmed that immunoglobulin levels were increased significantly. Further, FUS led to a time-dependent increase in glial response. The expression of ionized calcium-binding adaptor molecule 1, a marker of phagocytic microglia, was increased at 4 hours and 4 days, and it was resolved by 15 days. Astrocytes had a slightly delayed response, with an increase in the expression of glial fibrillary acidic protein at 4 days, which declined by 15 days. After 4 days, microglia and astrocytes had significantly greater volumes and surface areas, signifying enhanced activation in the FUS-treated cortex, without an apparent increase in cell count. Co-localization of Aβ within activated glia revealed a significant increase in Aβ internalization following FUS. In conclusion, it was demonstrated that the delivery of exogenous antibodies by FUS, and FUS alone can lead to plaque reduction. Mechanisms by which FUS alone reduces plaque load may include entry of endogenous antibodies to the brain and the induction of a transient glial response. This work details acute effects of FUS that highlight the promise of this delivery method for AD treatment. Alzheimer's disease focused ultrasound immunotherapy astrocytes microglia immunoglobulin amyloid-β mouse models MRI 0317 0760

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