Equivalent Circuit Implementation of Demyelinated Human Neuron in Spice

Angel, Nathan A

01 August 2011

This work focuses on modeling a demyelinated Hodgkin and Huxley (HH) neuron with Simulated Program with Integrated Circuit Emphasis (SPICE) platform. Demyelinating disorders affect over 350,000 people in the U.S and understanding the demyelination process at the cellular level is necessary to find safe ways to treat the diseases [9]. Utilizing a previous SPICE model of an electrically small cell neuron developed by Szlavik [32], an extended core conductor myelinated neuron was produced in this work. The myelinated neuron developed has seven active Nodes of Ranvier (nodes) separated by a myelin sheath. The myelin sheath can be successfully modeled with a resistive and capacitive network known as internodes. Both the Nodes of Ranvier and internode equivalent circuits were implemented in P-SPICE sub-circuit library files. Properties of the neuron can be changed in the library files to simulate neurons of different electrical or geometric properties. Using the P-SPICE code developed in this work, a myelinated neuron’s action potential was simulated and the action potential at each node was recorded. The action potential at each node was uniform in amplitude and pulse width. The conduction velocity of the action potential was calculated to be 57.15 m/s. Demyelination can be modeled by decreasing the capacitance and increasing the resistance of the myelin [34]. Two demyelinated neuron models were simulated in this work. The first model had one internode segment demyelinated, and the second model was of three consecutive internode segments. The resulting conduction velocity was calculated for both simulations. For one and three internode segment demyelinated the conduction velocity was slowed to 44.15 m/s, and 27.15 m/s respectively. This model successfully showed that an HH neuron implemented in SPICE could show the effects of demyelination on conduction velocity The goal of this work is to develop a demyelinated neuron so that treatments for Multiple Sclerosis (MS) and other demyelinated neurons could be simulated to test various treatments’ effectiveness. A current treatment for MS is ion channel blockers. Future work would be to use this model to test current ion channel blocker therapy and to validate if such therapies alleviate conduction slowing.

Myelinated neuron model

Demyelination simulation

Equivalent circuit neuron model

Bioelectrical and Neuroengineering

Utilizing the Visual System to Evaluate the Role of Demyelination and Axonal Injury in Neurodegeneration during Multiple Sclerosis

Mey, Gabrielle M.

27 January 2023

No description available.

Neurosciences

Molecular Biology

Neurology

Ophthalmology

multiple sclerosis

visual

demyelination

neurodegeneration

neuroinflammation

EAE

Role Of PPAR Family Of Transcription Factors In Spinal Cord Injury

Almad, Akshata A.

10 January 2011

No description available.

Neurosciences

PPAR

spinal cord injury

oligodendrocyte

NG2

demyelination

cell cycle

Hes5

Cocaine-Mediated Disruption of RXR-gamma Signaling: The Role of TNF-alpha

Kovalevich, Jane

January 2014

Cocaine abuse poses a substantial health and economic burden for which no effective treatment currently exists. Exposure to cocaine results in altered signaling in a number of central nervous system (CNS) pathways. Previous studies have primarily focused on neurotransmitter systems, such as the dopaminergic and glutamatergic systems, as well as on drug-induced neuroplasticity within the mesolimbic system, which is believed to contribute to reward, addiction, and relapse following withdrawal. Furthermore, cocaine exerts a number of effects on gene regulation that contribute to many pathological conditions commonly afflicting users such as mood disturbances, psychotic symptoms, and long-term cognitive dysfunction. While some mechanisms by which cocaine regulates gene expression have been well-characterized, a large gap in our understanding regarding its downstream actions still exists and must be elucidated in order to develop effective treatment strategies. One pathway we have discovered to be disrupted in an animal model of chronic cocaine abuse is the retinoid X receptor (RXR) signaling pathway. Retinoid X receptors serve as obligate heterodimer partners for a number of nuclear receptor transcription factors, including the thyroid hormone receptor (TR), retinoic acid receptor, vitamin D receptor, and peroxisome proliferator activated receptor. Heterodimeric complexes bind to specific recognition sequences in or around the promoter of target genes to activate, or in some cases, repress, transcriptional activity. Therefore, alterations in the levels and function of RXRs can potentially disrupt numerous signaling cascades. In this context, we observed a significant down-regulation in mRNA and protein levels of RXR-y, an isoform predominantly expressed in the CNS that is involved in dopaminergic signaling, in brains of cocaine-administered mice. Additionally, we observed significantly decreased levels of the neuroplasticity protein, neurogranin, which is regulated transcriptionally by TR/RXR heterodimers. Mechanisms underlying regulation of RXR levels in cells of the CNS are vastly unexplored. Studies in other organ systems, including liver and cardiac systems, demonstrate pro-inflammatory cytokines and cellular stress pathways exert repressive effects on RXR signaling, although these studies solely investigated regulation of the RXR-a isoform. Recently, studies have highlighted the role of the immune system during chronic drug abuse, and demonstrate that significant amounts of proinflammatory factors are produced in the brains of chronic cocaine abusers. Therefore, we hypothesized that cocaine-mediated induction of inflammatory cytokines, such as tumor necrosis factor (TNF)-a may contribute to decreased RXR-y expression within the CNS. Utilizing in vitro neuronal systems, we have demonstrated that cocaine exposure induces neuronal expression of TNF-a and that this contributes to decreased levels of RXR-y, as inhibition of TNF-a or its downstream effector c-Jun-NH2-terminal kinase (JNK) prevents cocaine-mediated reductions in RXR-y protein levels. Furthermore, treatment of neurons with TNF-a alone mimics the effects on RXR-y levels observed in cocaine-treated cells. Additionally, we show that proteasome-dependent protein degradation likely plays a role, as inhibition of the 26 S proteasome with Bortezomib during cocaine or TNF-a exposure blocks the down-regulation of RXR-y levels. Degradation of RXR-y in response to cocaine and TNF-a may involve nuclear export, as our results show an increased level of RXR-y in the cytoplasmic compartment shortly after treatment, and inhibiting nuclear export during treatment with Leptomycin B prevents decreases in whole cell protein levels of RXR-y. In addition to the effects of chronic cocaine abuse on neurons, other CNS cell types such as oligodendrocytes may be negatively impacted by exposure to cocaine. Imaging studies and post-mortem microarray data from human cocaine abuse patients reveal loss of myelin and down-regulated expression of myelin-related genes in the nucleus accumbens and frontal cortex. Altered myelin integrity likely contributes to cognitive deficits that present in many chronic cocaine abuse patients and may also exacerbate damage to neurons. However, limited investigation has been performed to evaluate the effects of cocaine on oligodendrocyte health and function. We have employed an in vivo murine model of chronic cocaine administration to evaluate the impact of cocaine on white matter protein levels. Our data reveal that cocaine induces a significant decrease in white matter protein levels, even following an extended period of withdrawal, in the nucleus accumbens. One potential mechanism for cocaine-mediated white matter damage involves perturbations of glutamate homeostasis, as glutamatergic signaling can induce excitotoxicity in CNS cells, including oligodendrocytes. In this context, we found that administration of the B-lactam antibiotic, ceftriaxone, during cocaine withdrawal ameliorates loss of white matter proteins. Ceftriaxone has previously been shown to upregulate expression and activity of the glial glutamate transporter GLT-1, lending support to the theory that cocaine-mediated myelin loss may be due, in part, to disruption of glutamatergic signaling. Ceftriaxone treatment also decreased expression of cleaved caspase-3, a pro-apoptotic signaling molecule activated during excitotoxic cell death, in cocaine-administered mice. Taken together, our studies characterize two novel consequences of cocaine exposure: (1) decreased neuronal RXR-y expression and down-regulation of RXR-target genes, such as neurogranin, and (2) loss of myelin proteins in the nucleus accumbens which can be attenuated by administration of ceftriaxone. These findings yield insight into mechanisms underlying cocaine-mediated CNS cell death, and highlight potential treatment avenues for restoring brain health. Additionally, as inflammatory processes were identified as key mediators in some of these observations, our findings likely extend to a number of neurodegenerative diseases which are characterized by a neuroinflammatory component. / Biomedical Neuroscience

Neurosciences

Cellular Biology

Biology, Molecular

Cocaine

Demyelination

Jnk

Retinoid X Receptor

Tnf-alpha

Quantitative Untersuchung der subkortikalen Neurone im Multiple-Sklerose-Modell der experimentellen autoimmunen Enzephalomyelitis bei Callithrix-jacchus-Marmosetten / Quantitative analysis of white matter neurons in marmosets with experimental autoimmune encephalomyelitis

Berger, Susanne

15 January 2014

No description available.

610

multiple sclerosis

EAE

marmoset

MAP2

NeuN

neuronal loss

neurogenesis

white matter neuron

inflammation

demyelination

Medizin (PPN619874732)

Identification de programmes d'activation macrophagique et microgliale dans les formes progressives de la sclérose en plaques / Identification of macrophagic and microglial activation programs in progressive forms of multiple sclerosis

Lhuillier, Alice

20 June 2014

La sclérose en plaques (SEP) est une maladie neuro-inflammatoire chronique, première cause de handicap chez le jeune adulte. Actuellement, aucun traitement ne freine l'aggravation des symptômes liée aux formes progressives. Bien que connue, l'implication des macrophages et de la microglie dans la démyélinisation et l'atteinte axonale doit être plus finement caractérisée. Ce d'autant plus que la plasticité fonctionnelle de ces cellules suggère une réponse spécifique selon la pathologie, la localisation des lésions et le stade évolutif de la maladie. Ce travail de thèse a consisté en une caractérisation moléculaire des programmes d'activation macrophagique/ microgliale dans deux types d'altérations tissulaires du système nerveux central des patients SEP : les zones partiellement démyélinisées bordant les plaques de la moelle épinière et les lésions corticales. Cette étude a été réalisée sur des tissus post-mortem de patients atteints de formes progressives, formes dans lesquelles les lésions médullaires et corticales sont nombreuses et impliquées dans le handicap progressif et irréversible. Nous avons identifié des spécificités moléculaires caractérisant l'activation macrophagique/microgliale au cours de la SEP en comparant, par une approche in silico, les profils caractérisés à ceux observés dans des pathologies neuro-dégénératives à composantes inflammatoires, la maladie d'Alzheimer et de Parkinson notamment. Dans l'ensemble, ces résultats suggèrent que l'activation chronique des macrophages/cellules microgliales contribue à l'extension à bas bruit des lésions médullaires et corticales pendant la phase progressive de la SEP et proposent de nouvelles cibles thérapeutiques / Multiple sclerosis (MS) is a chronic neuro-inflammatory disease and the most common cause of chronic neurological disability in young adults. No treatment is currently available to prevent the aggravation of symptoms in the progressive forms of the disease. The involvement of macrophages and microglia in demyelination and axonal injury is well known but need to be further characterized. Especially, the high level of functional plasticity harboured by macrophages/ microglia suggests that these cells engage specific activation programs depending on the disease, its evolution stage and the localization of lesions. In this context, this phD thesis was essentially aimed to characterize macrophage/microglia activation programs in two categories of tissue alterations observed in the post-mortem central nervous system from MS patients: 1) partially demyelinated areas at the border of spinal cord plaques and 2) cortical lesions. These two particular types of lesions are both highly frequent in progressive forms of MS and suspected to be involved in chronic and irreversible neurological disability. Using an in silico approach, the macrophage/microglia activation programs identified in MS were then compared to those observed in neurodegenerative and inflammatory disorders such as Alzheimer's disease and Parkinson's disease. Overall, our results suggest that the chronic activation of macrophages and microglia largely contributes to the slow and chronic expansion of MS lesions in progressive forms of the disease. Our work also proposes new therapeutic targets

Sclérose en plaques

Neuro-inflammation

Macrophages

Cellules microgliales

Astrocytes

Démyélinisation

Neuro-dégénérescence

Multiple sclerosis

Neuroinflammation

Macrophages

Microglia

Astrocyte

Demyelination

Neurodegeneration

616.834

Etude in vivo de l'impact de la surexpression du gène BIN1 dans un modèle murin de la maladie d'Alzheimer / In vivo study of BIN1 impact on late onset Alzheimer disease

Sartori, Maxime Steno

18 December 2018

La maladie d’Alzheimer à forme tardive, exempte de mutations, représente près de 99% des 850 000 cas répertoriés en France. Hormis l’âge, des facteurs génétiques comme BIN1 apparaissent déterminant dans l’établissement de l’amyloïdopathie et de la tauopathie, marqueurs constitutifs de cette maladie. Le travail de thèse est basé sur l’étude d’une surexpression du gène humain de BIN1 et de son impact dans un contexte murin de tauopathie. La surexpression seule de BIN1 entraine des défauts mnésiques à court terme associés à des anomalies cellulaires et moléculaires au niveau de la voie temporo-hippocampique. Ces altérations sont exacerbées par la combinaison de la souris TgBIN1 avec le modèle de tauopathie, à la fois chez les mâles et les femelles. Pour autant il apparait que la surexpression de BIN1 préserve la mémoire spatiale dépendamment de l’âge et du sexe. L’hippocampe apparait en grande partie préservé des inclusions intracellulaires de Tau et la myéline des fibres axonales est retrouvé intacte. Ces éléments mettent en évidence que BIN1 est un acteur important dans l’établissement de la tauopathie et que son activité neuro-protectrice peut être médiée par un complexe moléculaire direct impliquant à la fois Tau et RNT4-A/Nogo-A. / Late Onset Alzheimer Disease represents more than 99% of total Alzheimer cases and it is not caused by genetic mutations. Among risk factors such as age, genetic compounds as BIN1 appear to be determinant for the pathological process establishment. This study aims to determine the BIN1 overexpression effect in mice and in a tauopathy context. In this study, BIN1 overexpression alone caused short term memory impairments linked with the cellular and molecular abnormalities. These disorders are exacerbated by a combination of TgBIN1 mice with a tauopathy model, both in males and females. Surprisingly, BIN1 overexpression rescued long term and spatial memory regarding the age and sex. Hippocampus appeared to be preserved from intracellular Tau inclusions. Moreover, fornix myelin is found intact. These elements highlighted BIN1 which is a key gene in tauopathie establishment. BIN1 neuroprotective activity is mediated by direct molecular interactions both with Tau and RTN4-A/Nogo-A.

BIN1

Tau

RTN4-A/Nogo-A

Mémoire

Neurodégénerescence

Démyélinisation

Reticulum

BIN1

Tau

RTN4-A/Nogo-A

Memory

Neurodegeneration

Demyelination

Reticulum

572.8

616.83

Evaluation of the cuprizone model / Einschätzung des Cuprizone-Modells

Awn, Najmy

25 March 2010

No description available.

610 Medizin, Gesundheit

M

Medicine

Multiple Sklerose

Demyelinisierung

Remyelinisierung

Oligodendrozyte

mikroglia

Mikrophage

Multiple sclerosis

demyelination

remyelination

oligodendrocyte

microglia

macrophage

44

The effect of dopamine and its agonist pramipexole on oligodendrocytes in culture and in the cuprizone mouse model

Richter, Johann Sebastian

18 February 2014

No description available.

610

Dopamine

Cuprizone

Demyelination

Remyelination

Pramipexole

Dopamine agonists

Dopamine receptors

GOK-MEDIZIN

Avaliação da atividade de nucleotidases e parâmetros de estresse oxidativo em pacientes com esclerose múltipla e em modelo experimental de desmielinização em ratos

Spanevello, Roselia Maria

January 2009

A esclerose múltipla (EM) é a principal doença desmielinizante do sistema nervoso central (SNC), sendo considerada a principal causa de incapacidade neurológica em adultos jovens. Além das alterações imunes, neurológicas e vasculares que são encontradas na EM, tem sido postulado que o estresse oxidativo pode estar envolvido na patogênese desta doença. Os nucleotídeos ATP, ADP e o nucleosídeo adenosina são importantes moléculas capazes de modular vários processos biológicos incluindo tromboregulação, inflamação e neurotransmissão. O controle dos níveis extracelulares destas moléculas e a conseqüente sinalização purinérgica por elas induzida é realizada por uma variedade de enzimas como as NTPDases (Nucleotídeo Trifosfato Difosfoidrolase), E-NPPs (Ecto-Nucleotídeo Pirofosfatase/Fosfodiesterases), 5'- nucleotidase e a adenosina deaminase (ADA). Sendo assim, o objetivo deste trabalho foi avaliar a atividade destas ectoenzimas em linfócitos e plaquetas de pacientes com a forma surto remissão da EM (SREM) e o papel da NTPDase e 5'-nucleotidase em sinaptossomas e plaquetas bem como a avaliação de parâmetros de estresse oxidativo em ratos submetidos à desmielinização experimental pelo brometo de etídio (BE) e tratados com vitamina E. Os resultados obtidos demonstraram alterações na atividade das ectoenzimas em linfócitos e plaquetas de pacientes com SREM. Em linfócitos foi observado um aumento na atividade e expressão da NTPDase e uma diminuição na atividade da ADA em pacientes com SREM quando comparados com o grupo controle. Uma diminuição na atividade e expressão da NTPDase, bem como uma diminuição na atividade das enzimas E-NPP, 5'-nucleotidase e ADA foi observada em plaquetas de pacientes com SREM quando comparadas com indivíduos saudáveis. Em relação ao modelo experimental os resultados demonstraram que em ratos submetidos à desmielinização por BE ocorreu um aumento na atividade da NTPDase e 5'-nucleotidase tanto em sinaptossomas quanto em plaquetas. Quando ratos desmielinizados foram tratados com vitamina E este composto foi capaz de reverter o aumento da NTPDase, entretanto a atividade da 5'-nucleotidase permaneceu aumentada em sinaptossomas e plaquetas quando comparado com o grupo controle. Além disso, foi observado também que parâmetros de estresse oxidativo como o conteúdo de TBARS e tióis não protéicos foram encontrados aumentados e a atividade da catalase estava diminuída em ratos desmielinizados pelo BE, sendo que o tratamento com vitamina E foi capaz de reverter estas alterações ao nível do grupo controle. Os resultados descritos aqui sugerem que as ectoenzimas estão envolvidas na modulação de respostas imunes, vasculares e neurológicas possuindo assim um papel relevante tanto na EM quanto em modelos experimentais de desmielinização. Além disso, a vitamina E pode interferir com a hidrólise dos nucleotídeos de adenina bem como o estresse oxidativo durante um evento desmielinizante sugerindo assim, que este composto pode ser importante no tratamento de patologias desmielinizantes com a EM. / Multiple sclerosis (MS) is the main demyelinating disease of the central nervous system (CNS). It is the most common cause of neurological disability among young adults. Immune, neurological and vascular alterations are found in MS and it has been postulated that oxidative stress may be involved in the pathogenesis of this disease. The nucleotides ATP, ADP and nucleoside adenosine are important molecules that modulate several biological processes including thromboregulation, inflammation and neurotransmission. The control of extracellular levels of these molecules and consequent purinergic signaling induced by them is controlled by a variety of enzymes such as NTPDases (Nucleotide Triphosphates Diphosphohydrolase), E-NPPs (Ecto-Nucleotide Pyrophosphatase Phosphodiesterases), 5'-nucleotidase and adenosine deaminase (ADA). Therefore, the objective of this study was to evaluate the activity of these ectoenzymes in lymphocytes and platelets of patients with the relapsing - remitting form of MS (RRMS) as well as the role of NTPDase and 5'- nucleotidase in synaptosomes and platelets and oxidative stress parameters in rats subjected to experimental demyelination with ethidium bromide (EB) and treated with vitamin E. The results showed changes in ectoenzyme activities in lymphocytes and platelets of RRMS patients. In lymphocytes, an increase in NTPDase activity and expression along with a decrease in ADA activity was observed in patients with RRMS when compared with the control group. A decrease in NTPDase activity and expression and a decrease in E-NPP, 5'- nucleotidase and ADA activities was observed in platelets of RRMS patients when compared with healthy subjects. As for the experimental model, the results showed that rats subjected to demyelination by EB demonstrated increased NTPDase and 5'-nucleotidase activities in both synaptosomes and platelets. When demyelinated rats were treated with vitamin E this increase in NTPDase was reversed, however 5'-nucleotidase activity remained increased in synaptosomes and platelets when compared with the control group. Furthermore, we observed that oxidative stress parameters such as TBARS content and non-protein thiols were increased and catalase activity was decreased in demyelinated rats and that treatment with vitamin E reversed these changes in the control group. The results reported here suggest that ectoenzymes are involved in the modulation of immune, vascular and neurological responses, thus having an important role both in MS and in experimental models of demyelination. Moreover, vitamin E may interfere with the hydrolysis of adenine nucleotides and oxidative stress during a demyelinating event which suggests that this compound could be important in the treatment of demyelinating diseases such as MS.

Esclerose múltipla

Estresse oxidativo

Sistema purinérgico

Sistema nervoso central

Linfócitos

Vitamina E

Multiple sclerosis

Ectoenzymes

Lymphocytes

Platelets

Demyelination

Vitamin E