Global ETD Search

21	Impact d'une lésion sérotoninergique sur la symptomatologie parkinsonienne : approches multiples chez le singe MPTP-MDMA / Impact of a serotonergic lesion on parkinsonian symptomatology : multiple approaches in the MPTP-MDMA monkey Beaudoin, Maude 07 September 2015 (has links) La maladie de Parkinson (MP) est caractérisée par une dégénérescence progressive et irréversible des neurones dopaminergiques (DA) de la substance noire. Lorsque la perte DA atteint 60 à 80%, les patients vont développer des symptômes. Les traitements DA permettent de contrecarrer l'expression de ces symptômes mais induisent également à long terme l'apparition de complications invalidantes. De plus les patients développent également des symptômes non- moteurs pouvant émerger avant, pendant ou après l'apparition des symptômes moteurs. Parallèlement à la dégénérescence DA, les patients parkinsoniens présentent des altérations du système sérotoninergique (5-HT) qui ont été mises en évidence en post-mortem et plus récemment par imagerie par tomographie à émission de positons (TEP). Des corrélations ont également été démontrées entre l'altération du système 5-HT et la sévérité de certains symptômes parkinsoniens. Cependant, à ce jour, aucune étude n'a mis en évidence de lien causal direct entre l'altération 5-HT et l'expression des symptômes parkinsoniens. Il était donc crucial de clarifier le rôle exact de la 5-HT dans le développement des symptômes parkinsoniens ainsi que dans la réponse aux traitements dopaminergiques. Dans ce contexte, nous avons développé un nouveau modèle de la MP. Ce modèle nous a permis d'étudier l'impact de la lésion 5-HT sur la symptomatologie parkinsonienne. Ce travail a permis de démontrer l'implication du système sérotoninergique dans l'expression de la rigidité parkinsonienne. Par ailleurs, ce travail a également permis de démontrer le rôle causal des fibres 5-HT dans le développement de complications induites par un traitement chronique à la L- DOPA / Parkinson's disease (PD) is characterized by a progressive and irreversible degeneration of dopaminergic (DA) neurons localized in the substantia nigra, leading to the loss of dopamine within the target structures (mainly the striatum). When the DA loss reaches 60 to 80%, PD patients develop motor symptoms (rigidity, tremor, akinesia/bradykinesia). DA treatments allow counteracting symptoms expression but also induce after a certain time the appearance of disabling complications. Moreover, patients also develop non-motor symptoms that can emerge before, during or after the appearance of motor symptoms. ln addition to DA degeneration, PD patients present serotoninergic (5-HT) alteration evidenced in post-mortem and more recently by position emission tomography (PET) imaging. Correlations have been shown between the 5-HT alteration and the severity of some motor and non-motor symptoms as well as L-DOPA-induced dyskinesia. However, to date, none study evidenced a direct causal link between the 5-HT alteration and the expression of parkinsonian symptoms. lt was crucial to clarify the exact role of 5-HT in the development of parkinsonian symptoms. ln this context, we have developed a new model of PD. This model has allowed studying the impact of the 5-HT lesion on the parkinsonian symptomatology. We have evidenced the involvement of the 5-HT system in the expression of parkinsonian rigidity. Moreover, we have demonstrated the causal role of the 5-HT fibers in the development of complications induced by the L-DOPA treatment Maladie de Parkinson Primate non-humain MPTP MDMA Dyskinésie L-DOPA Dopamine Sérotonine Parkinson's disease Non-human primate MPTP MDMA Dyskinesia L-DOPA Dopamine Serotonin 612.8
22	Implication de la sérotonine dans l'expression de troubles moteurs et neuropsycho-comportementaux dans la maladie de Parkison / Impact of a serotonergic lesion on the expression of motor and neuropsychiatric symptoms Millot, Mathilde 01 July 2019 (has links) La maladie de Parkinson (MP) se caractérise par une dégénérescence progressive et irréversible des neurones dopaminergiques de la substance noire induisant une perte de dopamine (DA) dans les structures cibles. Lorsque cette perte DA se situe entre 60 % et 80 %, les patients présentent des symptômes moteurs (rigidité, tremblement, akinésie) et non-moteurs très variés (dépression, anxiété, apathie). Ces derniers apparaissent avant et/ou en même temps que les symptômes moteurs. La dopathérapie permet de contrecarrer certains symptômes, mais tous ne sont pas sensibles à cette médication. Parallèlement à la dégénérescence DA, le système sérotoninergique (5-HT) serait aussi altéré de façon précoce dans la maladie. Cette dégénérescence est liée par l’expression de symptômes moteurs et non-moteurs. Néanmoins, aucun lien causal n’a été mis en évidence entre cette lésion 5-HT et la symptomatologie parkinsonienne. Ainsi, il était primordial de déterminer le rôle de la 5-HT dans 1) l’expression des troubles moteurs et non-moteurs 2) dans la réponse au traitement sérotoninergique et dopaminergique. Nous avons utilisé un nouveau modèle animal primate ayant une lésion 5-HT (via la MDMA) puis une lésion DA (via le MPTP). Ce modèle nous permet de mettre en évidence l’impact d’une lésion 5-HT précoce dans la symptomatologie. Des approches comportementales, pharmacologiques, d’imagerie et de neuroanatomie ont été utilisées. La lésion 5-HT a induit un trouble anxieux chez les animaux lésés à la MDMA, qui ne sont pas contrecarrer avec un traitement sérotoninergique (antidépresseur). Cette lésion a également induit une sévérité et une progression plus rapide des symptômes moteurs induits par la lésion DA / Parkinson’s disease (PD) is characterized by a progressive and irreversible degeneration of dopaminergic (DA) neurons localized in the substantia nigra, leading to a loss of dopamine within the target structures. When the loss of DA reaches 60 to 80 %, PD patients develop a wide range of motor (rigidity, tremor, akinesia fro example) and non-motor (depression, anxiety, apathy for example) symptoms. Dopatherapy allows the reduction of symptoms expression. But some motor and non-motor symptoms are not counteracted by those DA drugs. In addition to DA degeneration, patients present an early serotonergic (5-HT) lesion. This lesion is linked to the severity of some motor and non-motor symptoms. However, there is no causal link established between 5-HT lesion and parkinsonian symptoms. Therefore, it was essential to determine the role of 5-HT 1) in the expression of motor and non-motor symptoms 2) and in the response of DA and 5-HT treatments. For that, we used a new monkey model of PD, exhibiting a 5-HT lesion (with MDMA ‘”ecstasy”)) followed by a DA lesion (with MPTP). This model allowed us to evaluate the impact of an early 5-HT lesion on parkinsonian symptoms. We used different approaches: PET imaging, pharmacology, behavioral and neuroanatomy. The MDMA-driven early 5-HT lesion induced an anxious-like behavior on MDMA treatedmonkeys. This behavioral modification was not counteracted by 5-HT drugs (antidepressant). This MDMA lesion has also increased the severity and the progression of parkinsonian symptoms induced by DA lesion with MPTP Maladie de Parkinson Dopamine Sérotonine MPTP MDMA Fluoxétine Pramipexole Symptômes moteurs et non-moteurs Parkinson’s disease Dopamine Serotonin MPTP MDMA Fluoxetine Pramipexole Motor and non-motor symptoms 570
23	alpha-Synuclein: Synaptische Funktion und Rolle bei der Pathogenese der Parkinson-Syndrome / alpha-Synuclein: Synaptic Function and role in the pathogenesis of Parkinson Schlüter, Oliver Marcus 14 June 2002 (has links) No description available. 610 Medizin, Gesundheit Medicine a-Synuclein MPTP Parkinson-Symdrom Maus-Nullmutanten a-Synuclein MPTP Parkinson syndrome targeted deletion in mice 44.30 MED 283: Molekularbiologie {Medizin}
24	Einfluss des GDNF-Rezeptors Ret auf die Erholung des nigrostriatalen Systems im MPTP-Mausmodell der Parkinsonerkrankung / Influence of GDNF receptor Ret on the recovery of the nigrostriatal system in an MPTP mouse model of Parkinson's disease Pöppelmeyer, Charlotte 02 May 2011 (has links) No description available. 610 Medizin, Gesundheit Medicine GDNF Ret Parkinson MPTP Sprouting GDNF Ret Parkinon´s Disease MPTP Sprouting 44.90
25	探討厚朴對神經毒素引起的神經傷害及行為異常之保護與治療效用 / Evaluation of the protective and therapeutic effects of cortex Magnoliae on neuronal damage and abnormal behavior induced by neurotoxins 廖筱玉 Unknown Date (has links) 中文摘要厚朴，採用厚朴植物之樹皮，是ㄧ種已知可應用於治療精神疾病的傳統天然藥物，例如：憂鬱症等。厚朴主要的有效多酚環成分已被證實具有抗氧化、抗發炎及抗興奮性毒殺等神經保護作用，因此，推測厚朴可作為一種潛在治療像是帕金森氏症這累神經退化性疾病之藥物。本研究之目的為探討厚朴是否可以預防與治療因百草枯及MPTP所誘導的毒害及學習、記憶和運動功能缺失等行為異常現象。本研究監測Oregon-R品系之果蠅(年齡：1-2, 20天或30天)之壽命在長期暴露於百草枯(5-20 mM)並先給予厚朴(100, 300或600 mg/L)治療之變化。其結果顯示，厚朴無法延長暴露在百草枯環境下之果蠅壽命。另外，我們給予雄性ICR小鼠(30-35 g)，連續五天，每日一劑MPTP(25 mg/kg, i.p.)，誘導神經毒性及行為異常現象。在共同投藥組別，在給予MPTP注射前一小時，先以灌餵方式給予小鼠厚朴(100或300 mg/kg)預防，連續五天後，只單獨給予厚朴治療連續十四天。後投藥組別，在給予最後一劑MPTP後，連續十四天給予厚朴(100或300 mg/kg).治療。在控制組別中，給予生理食鹽水(0.9%, i.p.)及灌餵玉米油。結果顯示，MPTP與厚朴並不影響小鼠之運動協調功能，然而，可利用新位置辨識能力測試及新物體辨識認知行為測試，檢測因MPTP所引起之認知功能障礙現象，由我們結果中顯示，不論是與MPTP共同給予厚朴治療抑或是後處理厚朴皆可恢復因MPTP所造成的認知功能障礙現象，此外，厚朴也可恢復因MPTP所造成多巴胺神經元及多巴胺轉運子受損之情形，另外，我們也初步發現，厚朴可在海馬迴中使Nrf2表現量提升。因此，初步結果表明，厚朴將可成為未來治療帕金森氏症之天然藥物。 / Cortex Magnoliae, the bark of Magnolia officinalis, has been prescribed in the traditional herbal medicine to treat a variety of mental disorders including depression. The main constituents of cortex Magnoliae contain the biphenyl compounds such as honokiol and magnolol. Both biphenyl compounds were shown to have the neuronal protective effect which is related to the anti-oxidation, anti-inflammation, and anti-excitatory toxicity. Thus, it was proposed that cortex Magnoliae may act as the potential therapeutic agent for the treatment of neurodegenerative disorders such as Parkinson’s disease (PD). The aim of the present study was to examine whether cortex Magnoliae exhibits the neuroprotective and therapeutic action against the neuronal toxicity and behavioral deficits in learning, memory, and motor function induced by neurotoxin paraquat and 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) in PD-like models. The lifespan of flies from Oregon-R strain of Drosophila melanogaster (age: 1-2, 20 or 30 days) chronically exposed to paraquat (5-20 mM) with pre-treatment of Cortex Magnoliae (100, 300 or 600 mg/L) were measured. Results showed that pre-treatment of Cortex Magnoliae could not extend the lifespan of the flies reduced by paraquat. On the other hand, male ICR mice (30-35g) were administered with MPTP (25 mg/kg, i.p.) once daily for 5 consecutive days to induce neurotoxicity and behavioral impairment. In co-treatment group, male mice were orally administrated with cortex Magnoliae (100 or 300 mg/kg) 1 hour before MPTP injection for 5 days and then followed by oral administration of cortex Magnoliae alone for consecutive 14 days. Mice in post-treatment group were orally administered with cortex Magnoliae (100 or 300 mg/kg) for consecutive 14 days after the final injection of MPTP. Mice in control group were injected with saline (0.9%, i.p.) and orally administrated with vehicle (corn oil). Our results showed that MPTP and cortex Magnoliae did not affect mouse coordination and balance in beam walking test. However, cortex Magnoliae improved the cognitive impairments determined by novel-location recognition task (NLRT) and novel-object recognition task (NORT) in MPTP-induced PD mouse. Additionally, cortex Magnoliae restored MPTP-induced loss of dopaminergic neurons and recovered MPTP-induced loss of dopamine transporters in striatum. Cortex Magnoliae also activated Nrf2 in hippocampus. Therefore, the preliminary results suggest that cortex Magnoliae may be a novel candidate for the treatment of Parkinson's disease in the future. The pharmacological mechanism of cortex Magnoliae in PD treatment needs further study. 厚朴百草枯 MPTP 認知功能障礙神經保護 Cortex Magnoliae paraquat MPTP cognitive impairment neuroprotection
26	Définir le rôle de chimiokines comme médiateurs pathologiques de la neuroinflammation dans le modèle MPTP de la Maladie de Parkinson / Defining the role of chemokines as pathological mediator of neuroinflammation in the MPTP model of Parkinson Disease Parillaud, Romain 25 June 2015 (has links) La maladie de Parkinson (MP) est marquée par la présence d'une inflammation, pouvant être bénéfique ou délétère à la neurodégénérescence dopaminergique (DAgique). Nous avons adressé la nature des interactions pathologiques entre neurones DAgiques, cellules gliales et leucocytes infiltrant, nécessaire à la mise en place de cette inflammation. Dans un modèle MPTP murin de la MP, les objectifs de ma thèse ont été 1) d'identifier des signaux inflammatoires neuronaux et gliaux, par une approche transcriptomique associée à de la microdissection laser et 2) de déterminer leurs rôles dans la neuroinflammation ainsi que leurs effets sur la perte DAgique. Nous avons retenu parmi les candidats identifiés: les axes CXCL16-CXCR6 et CCL2-CCR2. Nous reportons dans le modèle MPTP, une expression microgliale de CXCL16 ainsi qu'une infiltration de population lymphocytaire CXCR6. Bien que la déplétion de CXCR6 permette de réduire cette infiltration, aucun effet n'est observé sur la perte DAgique. Nous décrivons une infiltration de monocyte CCR2 en concomitance avec une expression astrocytaire précoce de CCL2 dans le modèle MPTP murin, ainsi qu'une expression plus prolongée de CCL2 chez le primate non-humain MPTP, suggérant une relevance de l'axe CCL2-CCR2 dans la MP. En effet nous montrons que des souris surexprimant CCL2, intoxiquées au MPTP, ont non seulement une augmentation accrue de l'infiltrat monocytaire CCR2, mais également de la lésion DAgique. De manière inattendue, nous montrons que la neurotoxicité accrue observée chez des souris CX3CR1-/- MPTP passe indirectement par la voie CCL2-CCR2. Ainsi, nos données supportent l'hypothèse d'une neurotoxicité des monocytes CCR2 dans la MP. / Parkinson's disease (PD) presents signs of neuroinflammation, which can be beneficial or deleterious for dopaminergic (DA) neurodegeneration. We have analyzed the characteristics of such pathological interactions between DA neurons, glial cells and infiltrating immune cells. Using the neurotoxic MPTP mouse model of PD and focusing on chemokines, my thesis objectives were: 1) to identify using laser-microdissection and RNA profiling, the neuronal and glial inflammatory signals in the affected Substantia Nigra (SN) and 2) to assess the role of promising identified chemokine candidates during DA neurodegeneration. We have focused on the lymphocytic CXCL16-CXCR6 and the monocytic CCL2-CCR2 axes. We have found early microglial CXCL16 induction and parallel SN infiltration of CXCR6 lymphocyte subpopulations. CXCR6-deletion reduced infiltration of specific lymphocyte subpopulations, but did not affect the known deleterious infiltration of CD4 T-lymphocytes. For the CCL2-CCR2 axis, we found evidence for limited SN infiltration of CCR2 monocytes, which was preceded by transient astrocytic CCL2 induction in MPTP mice, but a prolonged CCL2 induction in MPTP monkeys, suggesting a potential relevance for human PD. While CCR2-gene deletion did not affect loss of DA neurons, astrocytic CCL2 overexpression increased MPTP induced DA neural loss, revealing the principally neurotoxic nature of infiltrating CCR2 monocytes in a PD-like environment. Unexpectedly, we also found that the known increased DA loss in CX3CR1-KO mice was mediated indirectly via over-induction of the CCL2-CCR2 axis. Combined, our results suggest a potential deleterious role of the CCL2-CCR2 axis in actual human PD. Parkinson MPTP Neuroinflammation Chimiokines Monocyte Microdissection-Laser Parkinson's disease Neurodegeneration Chemokines 616.8
27	Zebrafish as a Model for the Study of Parkinson’s Disease Xi, Yanwei 09 May 2011 (has links) Parkinson’s disease (PD) is a common neurodegenerative disorder that is characterized by the degeneration of dopaminergic (DA) neurons in the substantia nigra and motor deficits. Although the majority of PD cases are sporadic, several genetic defects in rare familial cases have been identified. Animal models of these genetic defects have been created and have provided unique insights into the molecular mechanisms of the pathogenesis of PD. However, the etiology of PD is still not well understood. Here, taking advantage of the unique features offered by zebrafish, I characterized the functions of PINK1 (PTEN-induced kinase 1) gene, which is associated with recessive familial PD, in the development and survival of DA neurons. In zebrafish, antisense morpholino knockdown of pink1 did not cause a large loss of DA neurons in the ventral diencephalon (vDC), but the patterning of these neurons and their projections were perturbed. The pink1 morphants also showed impaired response to touch stimuli and reduced swimming behaviour. Moreover, the pink1 knockdown caused a significant reduction in the number of mitochondria, as well as mitochondrial morphological defects such as smaller size or loss of cristae, thus affecting mitochondrial function. These results suggest that zebrafish pink1 plays conserved important roles in the development of DA neurons and in the mitochondrial morphology and function. To better follow DA neurons after injury or administration of toxins, I generated a transgenic zebrafish line, Tg(dat:EGFP), in which the green fluorescent protein (GFP) is expressed under the control of cis-regulatory elements of dopamine transporter (dat). In Tg(dat:EGFP) fish, all major groups of DA neurons are correctly labeled with GFP, especially the ones in the vDC, which are analogous to the ascending midbrain DA neurons in mammals. In addition, we observed that the DA neurons in the vDC could partially be replaced after severe laser cell ablation. This suggests that zebrafish may have the unique capacity of regenerating DA neurons after injury. Taken together, my studies suggested that zebrafish could be a useful alternative animal model for the study of the molecular mechanisms underlying PD and for the screening of potential therapeutic compounds for PD. Zebrafish Parkinson's disease PINK1 dopaminergic neuron dopamine transporter morpholino tyrosine hydroxylase MPTP regeneration
28	Zebrafish as a Model for the Study of Parkinson’s Disease Xi, Yanwei 09 May 2011 (has links) Parkinson’s disease (PD) is a common neurodegenerative disorder that is characterized by the degeneration of dopaminergic (DA) neurons in the substantia nigra and motor deficits. Although the majority of PD cases are sporadic, several genetic defects in rare familial cases have been identified. Animal models of these genetic defects have been created and have provided unique insights into the molecular mechanisms of the pathogenesis of PD. However, the etiology of PD is still not well understood. Here, taking advantage of the unique features offered by zebrafish, I characterized the functions of PINK1 (PTEN-induced kinase 1) gene, which is associated with recessive familial PD, in the development and survival of DA neurons. In zebrafish, antisense morpholino knockdown of pink1 did not cause a large loss of DA neurons in the ventral diencephalon (vDC), but the patterning of these neurons and their projections were perturbed. The pink1 morphants also showed impaired response to touch stimuli and reduced swimming behaviour. Moreover, the pink1 knockdown caused a significant reduction in the number of mitochondria, as well as mitochondrial morphological defects such as smaller size or loss of cristae, thus affecting mitochondrial function. These results suggest that zebrafish pink1 plays conserved important roles in the development of DA neurons and in the mitochondrial morphology and function. To better follow DA neurons after injury or administration of toxins, I generated a transgenic zebrafish line, Tg(dat:EGFP), in which the green fluorescent protein (GFP) is expressed under the control of cis-regulatory elements of dopamine transporter (dat). In Tg(dat:EGFP) fish, all major groups of DA neurons are correctly labeled with GFP, especially the ones in the vDC, which are analogous to the ascending midbrain DA neurons in mammals. In addition, we observed that the DA neurons in the vDC could partially be replaced after severe laser cell ablation. This suggests that zebrafish may have the unique capacity of regenerating DA neurons after injury. Taken together, my studies suggested that zebrafish could be a useful alternative animal model for the study of the molecular mechanisms underlying PD and for the screening of potential therapeutic compounds for PD. Zebrafish Parkinson's disease PINK1 dopaminergic neuron dopamine transporter morpholino tyrosine hydroxylase MPTP regeneration
29	Zebrafish as a Model for the Study of Parkinson’s Disease Xi, Yanwei 09 May 2011 (has links) Parkinson’s disease (PD) is a common neurodegenerative disorder that is characterized by the degeneration of dopaminergic (DA) neurons in the substantia nigra and motor deficits. Although the majority of PD cases are sporadic, several genetic defects in rare familial cases have been identified. Animal models of these genetic defects have been created and have provided unique insights into the molecular mechanisms of the pathogenesis of PD. However, the etiology of PD is still not well understood. Here, taking advantage of the unique features offered by zebrafish, I characterized the functions of PINK1 (PTEN-induced kinase 1) gene, which is associated with recessive familial PD, in the development and survival of DA neurons. In zebrafish, antisense morpholino knockdown of pink1 did not cause a large loss of DA neurons in the ventral diencephalon (vDC), but the patterning of these neurons and their projections were perturbed. The pink1 morphants also showed impaired response to touch stimuli and reduced swimming behaviour. Moreover, the pink1 knockdown caused a significant reduction in the number of mitochondria, as well as mitochondrial morphological defects such as smaller size or loss of cristae, thus affecting mitochondrial function. These results suggest that zebrafish pink1 plays conserved important roles in the development of DA neurons and in the mitochondrial morphology and function. To better follow DA neurons after injury or administration of toxins, I generated a transgenic zebrafish line, Tg(dat:EGFP), in which the green fluorescent protein (GFP) is expressed under the control of cis-regulatory elements of dopamine transporter (dat). In Tg(dat:EGFP) fish, all major groups of DA neurons are correctly labeled with GFP, especially the ones in the vDC, which are analogous to the ascending midbrain DA neurons in mammals. In addition, we observed that the DA neurons in the vDC could partially be replaced after severe laser cell ablation. This suggests that zebrafish may have the unique capacity of regenerating DA neurons after injury. Taken together, my studies suggested that zebrafish could be a useful alternative animal model for the study of the molecular mechanisms underlying PD and for the screening of potential therapeutic compounds for PD. Zebrafish Parkinson's disease PINK1 dopaminergic neuron dopamine transporter morpholino tyrosine hydroxylase MPTP regeneration
30	The Immune Response in Parkinson's Disease Lira, Arman 28 January 2014 (has links) Microglia activity has been detected in Parkinson’s disease (PD) post-mortem brains and experimental animal models; however the precise interplay between microglia and dopamine neurons of the SNpc is not well understood. In the blood plasma of PD patients, our laboratory found elevated levels of interferon-gamma (IFN-γ), a proinflammatory cytokine and potent activator of microglia. Given this, we sought to untangle the immune responses relevant to PD in mice, examining IFN-γ’s involvement and signaling mechanism using an inflammatory co-culture model of microglia and midbrain neurons treated with rotenone. By means of RT-PCR, we discovered IFN-γ mRNA transcripts are produced by microglia, and this expression increases upon exposure to rotenone. We delineated IFN-γ’s signaling mechanism in co-cultures using different IFN-γ receptor deficient cells, and showed it engages receptors in an autocrine (not paracrine) manner to further microgliosis and dopamine cell loss. After exploring the innate immune response in a model of PD, we subsequently shifted focus to an in vivo system to better investigate any involvement of the delayed humoral arm of the adaptive immune system. Needing a time appropriate death paradigm, we developed a protracted low dose regimen of MPTP, which elicits dopaminergic cell death after 2 weeks of treatment. Subjected to this paradigm, Rag 2 mutant mice (deficient in both T and B cells) exhibit resistance to dopamine cell loss, microglia activation and motor impairments. Further evidence in support of immune involvement came with the resensitization of Rag2 mice to MPTP after reconstitution with WT splenocytes. Additionally, mice deficient in Fcγ receptors exhibited neuroprotection in our protracted degeneration model. Taken together, these data indicate the innate and humoral arm can modulate the microglial response to dopaminergic degeneration and may participate in Parkinson's disease. Neuroinflammation Microgliosis Innate immunity Adaptive immune response Interferon-gamma Fc receptors Rotenone MPTP Parkinson's disease

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