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21	Characterization of moving neurofilaments in cultured neurons Yan, Yanping 06 January 2006 (has links) No description available. Biology, Neuroscience neurofilament axonal transport live cell imaging immunofluorescence microscopy electron microscopy
22	Remodelage neuronal de la cicatrice cardiaque suite à un infarctus du myocarde El-Helou, Viviane 09 1900 (has links) Suite à un infarctus du myocarde, la formation d’une cicatrice, nommée fibrose de réparation, représente un processus adaptatif et essentiel empêchant la rupture du myocarde. La cicatrice est constituée de myofibroblastes, de cellules vasculaires, de fibres sympathiques ainsi que de cellules souches neuronales cardiaques exprimant la nestine. Une perturbation au niveau de ces constituants cellulaires résulte en une formation maladaptative de la cicatrice et éventuellement, une diminution de la fonction cardiaque. La compréhension des événements cellulaires ainsi que les mécanismes sous-jacents participant à cette fibrose est alors d’une importance primordiale. Cette thèse est axée sur l’identification du rôle du système sympathique et des cellules souches neuronales cardiaques exprimant la nestine dans la formation de la cicatrice ainsi que leur interaction potentielle. Nos travaux examinent l’hypothèse que les cellules souches neuronales exprimant la nestine sont endogènes au cœur et que suite à un dommage ischémique, elles contribuent à la réponse angiogénique et à la réinnervation sympathique du tissu lésé. Les cellules souches neuronales exprimant la nestine sont retrouvées dans les cœurs de différentes espèces incluant le cœur infarci humain. Elles sont résidentes dans le cœur, proviennent de la crête neurale lors du développement et sont intercalées entre les cardiomyocytes n’exprimant pas la nestine. Suite à leur isolation de cœurs infarcis de rats, les cellules souches neuronales cardiaques prolifèrent sous forme de neurosphères et, dans des conditions appropriées in vitro, se différencient en neurones exprimant le neurofilament-M. Suite à un infarctus du myocarde, les niveaux de l’ARNm de nestine sont significativement augmentés au niveau de la région infarcie et non-infarcie. Nos résultats suggèrent que cette augmentation de l’expression de nestine dans la cicatrice reflète en partie la migration des cellules souches neuronales cardiaques exprimant la nestine de la région non-infarcie vers la région infarcie. Lors de la fibrose de réparation, ces cellules représentent un substrat cellulaire pour la formation de nouveaux vaisseaux et contribuent aussi à la croissance des fibres sympathiques dans la région infarcie. Finalement, nous démontrons que la formation de la cicatrice est associée à une innervation sympathique de la région infarcie et péri-infarcie. De plus, les fibres sympathiques présentes dans la région infarcie sont observées à proximité de vaisseaux de petits calibres. Ces données suggèrent indirectement que l’innervation de la cicatrice par les fibres sympathiques peut jouer un rôle dans la réponse angiogénique suite à un infarctus du myocarde. Suite à l’administration du corticostéroïde dexaméthasone, nous détectons un amincissement de la cicatrice, associé à une réduction significative des fibres sympathiques exprimant le neurofilament-M dans la région infarcie et péri-infarcie. La diminution de la densité de ces fibres par le dexaméthasone peut être reliée à une diminution de la prolifération des myofibroblastes et de la production de l’ARNm du facteur neurotrophique nerve growth factor. / GENERAL ABSTRACT Following myocardial infarction, scar formation represents an adaptive response required to heal the damaged myocardium and prevent cardiac rupture. Infarct healing requires the coordinated action of scar myofibroblasts, angiogenic cells, sympathetic fibres and nestin positive cardiac neural stem cells. A perturbation of one or more of the aforementioned events could lead to inadequate scar healing and further worsening of ventricular function. A better understanding of the cellular events and the underlying mechanisms involved in scar formation is of a primordial importance. The focus of the following studies consists of elucidating the role of the sympathetic system and cardiac neural stem cells during scar healing and their potential interaction. We tested the hypothesis that nestin positive neural stem cells are endogenous to the heart, contribute to angiogenesis and sympathetic innervation of the infarcted myocardium following ischemic injury. Nestin positive cardiac neural stem cells are found in a number of species including the infarcted human heart. Nestin positive cardiac neural stem cells represent a resident population in the heart, are derived from the neural crest and detected intercalated between nestin negative cardiac myocytes. Following their isolation from the infarcted rat heart, neural stem cells proliferate as a neurosphere and under appropriate in vitro conditions differentiate to a neurofilament-M immunoreactive neuron. Following myocardial infarction, nestin mRNA levels are significantly elevated in the viable left ventricle and infarct region. Our data further suggests that the increased expression of nestin in the infarct region reflects in part the migration of these neural stem cells from the viable myocardium. During cardiac wound healing, neural stem cells may represent a novel substrate for de novo blood vessel formation and further contribute to sympathetic fibre growth and innervation of the infarct region. Lastly, we demonstrate that scar formation and healing is associated with sympathetic fibre sprouting of the peri-infarct/infarct region. In addition, sympathetic fibres in the infarct region were detected in close proximity to small calibre blood vessels. These latter data indirectly suggest that innervating sympathetic fibres may play a role in angiogenesis during cardiac wound healing. Following the administration of the corticosteroid dexamethasone inadequate scar healing was observed and associated with a significant reduction of neurofilament-M immunoreactive fibres in the peri-infarct/infarct region. The loss of sympathetic fibre sprouting in the scar may be related to a dexamethasone-mediated suppression of myofibroblast growth and the concomitant reduction of nerve growth factor mRNA expression. Coeur Infarctus du myocarde Cellule souche neuronale Nestine Neurofilament Fibre sympathique Angiogenèse Fibrose Crête neurale Myofibroblaste Heart Myocardial infarction Neural stem cell Nestin Neurofilament Sympathetic fibre Angiogenesis Fibrosis Neural crest Myofibroblast
23	Local Protein Turnover As a Regulatory Mechanism of Growth and Collapse of Neuronal Growth Cones / Lokale Kontrolle der Proteinstabilität in neuronalen Wachstumskegeln Ganesan, Sundar 26 April 2005 (has links) No description available. 570 Biowissenschaften, Biologie Mathematics and Computer Science Wachstumskegel Anleitung Signal transduction Biosensors FRET FLIM FRAP Neurofilament-M proteasome Chaperone Axonal Transport Growth cone Guidance Signal transduction Biosensors FRET FLIM FRAP Neurofilament-M proteasome Chaperone Axonal Transport 42 W
24	Remodelage neuronal de la cicatrice cardiaque suite à un infarctus du myocarde El-Helou, Viviane 09 1900 (has links) RÉSUMÉ GÉNÉRAL Suite à un infarctus du myocarde, la formation d’une cicatrice, nommée fibrose de réparation, représente un processus adaptatif et essentiel empêchant la rupture du myocarde. La cicatrice est constituée de myofibroblastes, de cellules vasculaires, de fibres sympathiques ainsi que de cellules souches neuronales cardiaques exprimant la nestine. Une perturbation au niveau de ces constituants cellulaires résulte en une formation maladaptative de la cicatrice et éventuellement, une diminution de la fonction cardiaque. La compréhension des événements cellulaires ainsi que les mécanismes sous-jacents participant à cette fibrose est alors d’une importance primordiale. Cette thèse est axée sur l’identification du rôle du système sympathique et des cellules souches neuronales cardiaques exprimant la nestine dans la formation de la cicatrice ainsi que leur interaction potentielle. Nos travaux examinent l’hypothèse que les cellules souches neuronales exprimant la nestine sont endogènes au cœur et que suite à un dommage ischémique, elles contribuent à la réponse angiogénique et à la réinnervation sympathique du tissu lésé. Les cellules souches neuronales exprimant la nestine sont retrouvées dans les cœurs de différentes espèces incluant le cœur infarci humain. Elles sont résidentes dans le cœur, proviennent de la crête neurale lors du développement et sont intercalées entre les cardiomyocytes n’exprimant pas la nestine. Suite à leur isolation de cœurs infarcis de rats, les cellules souches neuronales cardiaques prolifèrent sous forme de neurosphères et, dans des conditions appropriées in vitro, se différencient en neurones exprimant le neurofilament-M. Suite à un infarctus du myocarde, les niveaux de l’ARNm de nestine sont significativement augmentés au niveau de la région infarcie et non-infarcie. Nos résultats suggèrent que cette augmentation de l’expression de nestine dans la cicatrice reflète en partie la migration des cellules souches neuronales cardiaques exprimant la nestine de la région non-infarcie vers la région infarcie. Lors de la fibrose de réparation, ces cellules représentent un substrat cellulaire pour la formation de nouveaux vaisseaux et contribuent aussi à la croissance des fibres sympathiques dans la région infarcie. Finalement, nous démontrons que la formation de la cicatrice est associée à une innervation sympathique de la région infarcie et péri-infarcie. De plus, les fibres sympathiques présentes dans la région infarcie sont observées à proximité de vaisseaux de petits calibres. Ces données suggèrent indirectement que l’innervation de la cicatrice par les fibres sympathiques peut jouer un rôle dans la réponse angiogénique suite à un infarctus du myocarde. Suite à l’administration du corticostéroïde dexaméthasone, nous détectons un amincissement de la cicatrice, associé à une réduction significative des fibres sympathiques exprimant le neurofilament-M dans la région infarcie et péri-infarcie. La diminution de la densité de ces fibres par le dexaméthasone peut être reliée à une diminution de la prolifération des myofibroblastes et de la production de l’ARNm du facteur neurotrophique nerve growth factor. / GENERAL ABSTRACT Following myocardial infarction, scar formation represents an adaptive response required to heal the damaged myocardium and prevent cardiac rupture. Infarct healing requires the coordinated action of scar myofibroblasts, angiogenic cells, sympathetic fibres and nestin positive cardiac neural stem cells. A perturbation of one or more of the aforementioned events could lead to inadequate scar healing and further worsening of ventricular function. A better understanding of the cellular events and the underlying mechanisms involved in scar formation is of a primordial importance. The focus of the following studies consists of elucidating the role of the sympathetic system and cardiac neural stem cells during scar healing and their potential interaction. We tested the hypothesis that nestin positive neural stem cells are endogenous to the heart, contribute to angiogenesis and sympathetic innervation of the infarcted myocardium following ischemic injury. Nestin positive cardiac neural stem cells are found in a number of species including the infarcted human heart. Nestin positive cardiac neural stem cells represent a resident population in the heart, are derived from the neural crest and detected intercalated between nestin negative cardiac myocytes. Following their isolation from the infarcted rat heart, neural stem cells proliferate as a neurosphere and under appropriate in vitro conditions differentiate to a neurofilament-M immunoreactive neuron. Following myocardial infarction, nestin mRNA levels are significantly elevated in the viable left ventricle and infarct region. Our data further suggests that the increased expression of nestin in the infarct region reflects in part the migration of these neural stem cells from the viable myocardium. During cardiac wound healing, neural stem cells may represent a novel substrate for de novo blood vessel formation and further contribute to sympathetic fibre growth and innervation of the infarct region. Lastly, we demonstrate that scar formation and healing is associated with sympathetic fibre sprouting of the peri-infarct/infarct region. In addition, sympathetic fibres in the infarct region were detected in close proximity to small calibre blood vessels. These latter data indirectly suggest that innervating sympathetic fibres may play a role in angiogenesis during cardiac wound healing. Following the administration of the corticosteroid dexamethasone inadequate scar healing was observed and associated with a significant reduction of neurofilament-M immunoreactive fibres in the peri-infarct/infarct region. The loss of sympathetic fibre sprouting in the scar may be related to a dexamethasone-mediated suppression of myofibroblast growth and the concomitant reduction of nerve growth factor mRNA expression. Coeur Infarctus du myocarde Cellule souche neuronale Nestine Neurofilament Fibre sympathique Angiogenèse Fibrose Crête neurale Myofibroblaste Heart Myocardial infarction Neural stem cell Nestin Neurofilament Sympathetic fibre Angiogenesis Fibrosis Neural crest Myofibroblast
25	Serum neurofilament indicates that DBS surgery can cause neuronal damage whereas stimulation itself does not Frank, Anika, Bendig, Jonas, Schniewind, Iñaki, Polanski, Witold H., Sobottka, Stephan B., Reichmann, Heinz, Akgün, Katja, Ziemssen, Tjalf, Klingelhoefer, Lisa, Falkenburger, Björn H. 04 April 2024 (has links) Deep brain stimulation (DBS) is a potent symptomatic therapy for Parkinson’s disease, but it is debated whether it causes or prevents neurodegeneration. We used serum neurofilament light chain (NFL) as a reporter for neuronal damage and found no difference between 92 patients with chronic STN-DBS and 57 patients on best medical treatment. Serum NFL transiently increased after DBS surgery whereas the initiation of STN stimulation did not affect NFL levels, suggesting that DBS surgery can be associated with neuronal damage whereas stimulation itself is not. info:eu-repo/classification/ddc/500 ddc:500 info:eu-repo/classification/ddc/600 ddc:600
26	A functional study on novel genes involved in regulating aldosterone secretion in normal human zona glomerulosa and in aldosterone-producing adenomas Maniero, Carmela January 2017 (has links) Primary aldosteronism is the most common secondary cause of hypertension with a prevalence of about 10%. About half of PA cases are caused by aldosterone-producing adenomas (APA). Two APA subtypes, ZG-like and ZF-like APAs, have been described, according to the histological resemblance to normal zona glomerulosa (ZG) and zona fasciculata (ZF), underlying somatic mutations (KCNJ5 commonly found in ZF-like, CACN1AD, ATP1A1, ATP2B3, CTNNB1 in ZG-like APAs), and transcriptome profile. It is unknown if the process of tumorigenesis differs between ZG- and ZF-like APAs. In order to define ZG specific genes, we have compared the transcriptome of APAs and their adjacent adrenal glands by microarray assay. RNA was isolated by laser capture microdissection (LCM) from adjacent ZG, ZF and APAs from 14 patients with Conn’s and 7 patients with phaeocromocytoma. Two top hit genes from the comparison of ZG vs ZF were functionally studied, ANO4 and NEFM. NEFM, encoding neurofilament medium, was the fourth most up-regulated gene in ZG vs ZF, showing 14.8-fold-fold higher expression levels (p=9.16-12) in ZG than ZF. NEFM was also one of the most down-regulated genes in ZF-like vs ZG-like APAs. Immunohistochemistry (IHC) confirmed selective high expression of NEFM in ZG and ZG-like APAs. Silencing NEFM in H295R cells increased aldosterone secretion and cell proliferation. In addition, it increased stimulation and inhibition, respectively, of aldosterone secretion from H295R cells by the dopamine receptor D1R agonist fenoldopam and antagonist SCH23390. IHC showed predominantly intracellular staining for D1R in NEFM-rich ZG-like APAs, but membranous staining in NEFM-poor ZF-like APAs. Aldosterone secretion in response to fenoldopam in primary cells from ZG-like APAs was lower than in cells from ZF-like APAs. NEFM expression levels directly correlate with KCNJ5 phenotype: KCNJ5 mutations down-regulate NEFM mRNA and protein levels in H295R cells and in primary cells from ZG-like APAs. ANO4,encoding a Ca2+-activated chloride channel family member, was the third most upregulated gene, showing 19.9-fold higher expression levels (p=6.6x10-24) in ZG than ZF. IHC confirmed ZG selectivity of ANO4 protein in the adrenal cortex. The staining was mainly cytoplasmic. Unlike NEFM, there was no difference in expression of ANO4 between ZG- and ZF-like APAs, the levels being mid-way between those of ZF and ZG. Overexpression of ANO4 in H295R cells caused an increase in CYP11B2 and NR4A2 gene expression levels but basal aldosterone secretion was unchanged. In the presence of calcium agonists, ANO4 reduced aldosterone secretion. ANO4 subcellular localisation was confirmed as cytoplasmic by immunofluorescence microscopy of transfected cells. When exposed to calcium ionophores, ANO4 generated small chloride currents as detected by YFP assay. In summary, the comparison of transcriptome of ZG with paired ZF found unexpected up-regulated genes. Most of the highly up regulated genes in human ZG, including NEFM and ANO4, inhibit either basal or stimulated aldosterone secretion, and this may reflect an adaptive response to high salt intake. No clear-cut correspondence was found between transcriptome of APAs and their resembling zone of adrenal cortex. The down-regulation of NEFM following transfection of mutant KCNJ5 suggests that ZF-like properties may be a consequence of mutation, rather than tissue of origin.
27	Optimization of protocol for immunofluorescence stain to observe nerve infiltration and regeneration in cancer tissue Hanell, Malin January 2022 (has links) Background: Neuronal plasticity and regeneration in cancer are understudied aspects of cancer research. Studies have shown that neurogenesis and axonogenesis are associated with cancer progression and metastatic potential. Purpose: The purpose of this project was to optimize an immunofluorescence stain to observe nerve development and regeneration in cancer tissue, with the use of antibodies against neurofilament light chain (Nf-L), growth associated protein 43 (gap-43), and doublecortin X (DCX). Material and method: Staining optimization included evaluations of antigen retrieval, tissue permeabilization, antibody dilution, and duration of primary antibody incubation. The analyses were tested on colorectal- and lung cancer tissues. Results: The detection of Nf-L was not successful in any combination of the analyses or on ether tissue. The staining Gap-43 showed the best results using antigen retrieval with pepsin in HCl and primary antibody dilution 1:500 combined with incubation overnight at 4 °C. Staining for DCX needs more evaluation due to non-specific binding in lung cancer tissue. The stain showed the best results with antigen retrieval performed with pepsin in HCl, primary antibody dilution 1:250 combined with 1 hour incubation at room temperature of the primary antibody. Permeabilization has to some degree shown good results in combination with antigen retrieval with pepsin in HCl. Conclusion: A good protocol was established for Gap-43 detection, but the procedures for Nf-L and DCX detections need to be optimized. Neurogenesis axonogenesis neurofilament light chain growth associated protein 43 doublecortin X Biomedical Laboratory Science/Technology
28	Peripherin-28 as a Biomarker of ALS: A Methodological Study Findlater, Joseph 31 December 2010 (has links) Amyotrophic lateral sclerosis (ALS) is a progressive and fatal neurodegenerative disease which currently lacks rapid and definitive diagnostic tests. Recently identified neuron specific splice variant molecules, Per28 and NFL-60, have been shown to contain unique epitopes and to have altered levels of expression in ALS patients. It is believed that these factors make Per28 and NFL-60 excellent candidate biomarkers for the ALS disease state. In this study, we attempted to develop ELISA assays directed against Per28 and NFL-60, as well as a generalized guideline for splice variant ELISA development, which could be used in a clinical setting. Limitations in currently identified antibodies to the splice variants allowed only for the completion of a Per28 ELISA, which lacked the sensitivity for clinical relevance. This assay creation process, however, did produce a guideline for similar ELISA development, which should allow for the more expeditious creation future ELISA. Peripherin Neurofilament Light TDP-34 ELISA amyotrophic lateral sclerosis Per28 TDP-43 C-Splice NFL-60 cerebrospinal fluid biomarkers alternative splicing 0317 0307
29	Peripherin-28 as a Biomarker of ALS: A Methodological Study Findlater, Joseph 31 December 2010 (has links) Amyotrophic lateral sclerosis (ALS) is a progressive and fatal neurodegenerative disease which currently lacks rapid and definitive diagnostic tests. Recently identified neuron specific splice variant molecules, Per28 and NFL-60, have been shown to contain unique epitopes and to have altered levels of expression in ALS patients. It is believed that these factors make Per28 and NFL-60 excellent candidate biomarkers for the ALS disease state. In this study, we attempted to develop ELISA assays directed against Per28 and NFL-60, as well as a generalized guideline for splice variant ELISA development, which could be used in a clinical setting. Limitations in currently identified antibodies to the splice variants allowed only for the completion of a Per28 ELISA, which lacked the sensitivity for clinical relevance. This assay creation process, however, did produce a guideline for similar ELISA development, which should allow for the more expeditious creation future ELISA. Peripherin Neurofilament Light TDP-34 ELISA amyotrophic lateral sclerosis Per28 TDP-43 C-Splice NFL-60 cerebrospinal fluid biomarkers alternative splicing 0317 0307
30	Brain-Derived Neurotrophic Factor Mediates Recovery from Stress Urinary Incontinence Balog, Brian Michael January 2020 (has links) No description available. Biology Biomedical Research Neurobiology BDNF electrical stimulation regenerative electrical stimulation neuromuscular junction neurofilament leak point pressure pudendal nerve function external urethral sphincter

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