Global ETD Search

11	Optimizing the efficacy of transcranial direct current stimulation on cortical neuroplasticity based on a neurovascular coupling model Jamil, Asif 24 January 2017 (has links) No description available. 570 transcranial direct current stimulation neurovascular coupling motor cortex inter-individual variability bimanual motor learning Biologie (PPN619462639)
12	Oxid dusnatý a jeho neurofyziologická role / Nitric oxide and its role in neurophysiology Dobrovodská, Gabriela January 2012 (has links) Title: Nitric oxide and its neurophysiologic role Objectives: The main aim of my diploma work is to evaluate the role of nitric oxide and its effects during epileptic seizure in rats. I summarize the present knowledge about nitric oxide and its effects on human organism in the theoretical section of this paper and I will suppose the positive effect of nitric oxide inhibitor in epileptic seizures in rats by the realization of my experiment. Methods: The experiment will be performed in the laboratory of Academy of Science of Czech Republic. Implementation will come through examining a set of ten rats. The first six will be given v (L-NPA) in an amount of 0,5mg to one side, which will take place by applying bilaterally to coele. Then after ten minutes 0,5µl of 4-aminopyridine (4-AP) will be applied bilaterally to coele. The control group, consisting of four rats will be given saline instead of L-NPA. The experiment will run for two days. Results: The course of epileptic seizure with application of L-NPA to examined group was compared with the control group. The experiment confirmed the positive effect of L-NPA in terms of delay and reduction of seizure. Keywords: nitric oxide, Nω -propyl-l-arginine, neurovascular coupling, 4-anopyridine, epilepsy
13	Mechanismen und Mediatoren der neurovaskulären Kopplung im Gehirn Lindauer, Ute 02 October 2001 (has links) Zwischen neuronaler und glialer Aktivierung, dem Energiemetabolismus und dem zerebralen Gefäßbett besteht eine enge Beziehung - als Phänomen der neurometabolischen und neurovaskulären Kopplung bekannt. Diese Korrelation von elektrischer und metabolischer Aktivität sowie dem regionalen zerebralen Blutfluß besteht räumliche und zeitliche fokussiert und ist charakteristisch für das Gehirn. Das Verständnis um die Mechanismen und Mediatoren der neurovaskulären Kopplung ist von grundlegender Bedeutung für die korrekte Interpretation moderner bildgebender Verfahren im klinischen Einsatz. Ein Schwerpunkt der Untersuchungen lag in der Überprüfung der Hypothese eines frühen Sauerstoff-oder Glukose-Mangels im Gewebe unter funktioneller Stimulation als mögliches primäres Signal für eine nachfolgende vaskuläre Antwort. Anhand der Befunde kann jedoch ausgeschlossen werden, daß ein möglicherweise kurzzeitig auftretender Substratmangel im Gewebe registriert wird, und auf diesem Wege die Blutflußantwort auf funktionelle Stimulation initiiert wird. Die Frage nach dem eigentlichen Signal für die Blutflußantwort und dem primären Ort der Regulation (Arteriole, Kapillare, Venole) bleibt weiterhin ungeklärt. Die qualitative wie auch quantitative Charakterisierung des Verlaufs der Blutfluß- und Blutoxygenierungsveränderungen unter somatosensorischer Stimulation bildet die Grundlage für die Untersuchung von Veränderungen dieses Musters unter pathophyiologischen Bedingungen als sogenannter Fingerabdruck spezifischer zerebraler Schädigungen. Im Rahmen des zweiten Schwerpunkts beschäftigt sich vorliegende Arbeit mit der Rolle des Bioradikals Stickstoffmonoxid (NO) bei der neurovaskulären Kopplung. Ein im kortikalen Gewebe physiologisch vorhandener basaler NO Spiegel moduliert über die Bereitstellung einer basalen cyclischen Guanosin-3',5'-Monophosphat (cGMP) Konzentration vornehmlich in glatten Gefäßmuskelzellen die Reaktivtät zerebraler Gefäße sowohl auf globale vasodilatatorische Stimuli wie die Hyperkapnie als auch auf funktionelle Aktivität wie die Whisker-Stimulation der Ratte. Da die Bereitstellung des basalen NO / cGMP Spiegels im zerebralen Gewebe für physiologische vaskuläre Antworten von grundlegender Bedeutung ist, ist zu erwarten, daß eine Störung desselben durch pathophysiologische Vorgänge weitreichende Folgen für die adequate Versorgung aktivierter Hirnareale haben dürfte. / A tight relation exists between neuronal and glial cell activation, cerebral energy metabolism, and cerebral vasculature - a phenomenon known as neurometabolic and neurovascular coupling. The correlation of electrical and metabolic activity, and regional cerebral blood flow occurs at high temporal and spatial resolution, and is characteristic for the brain. We need to understand the physiology of neurometabolic and neurovascular coupling to fully exploit the potential of modern functional brain imaging, which utilizes vascular responses to map brain activity. Therefore, understanding the signalling cascade of regional vasodilation due to functional activation is of great importance. In the present work, we have shown that there is no evidence neither for an early deoxygenation nor for an early decrease in glucose concentration in the tissue at the onset of increased neuronal activity. The first event inducing regional cerebral blood flow increase as well as the vascular compartment, at which vasodilation starts (arteriole, capillary, venule), is still not known so far and has to be further investigated. In disease neurovascular coupling may be disturbed, while this disturbance may itself further contribute to tissue damage. Therefore a thorough elucidation of the physiology and pathophysiology of neurometabolic and neurovascular coupling may contribute to the development of treatment strategies in acute and chronic CNS disorders. Beside the mechanisms, little is known concerning the mediators of neurovascular coupling. The involvement of the highly diffusible vasodilator bioradical nitric oxide (NO) in the regulation of regional cerebral blood flow is widely accepted. In the present work, it has been shown that NO acts as a modulator rather than a mediator of vascular relaxation due to functional activation or systemic hypercapnia in the cerebral cortex, permitting vasodilation mediated by other agents. This modulation mainly occurs via a basal cyclic guanosin-3',5'-monophosphate (cGMP) production within the vascular smooth muscle cell. The basal modulatory concentration of NO / cyclic GMP may be disturbed during cerebrovascular disease, leading to a mismatch of regional cerebral blood flow and metabolic demand. Stickstoffmonoxid Neurovaskuläre Kopplung Funktionelle Aktivierung Zerebrale Blutoxygenierung Neurovascular coupling Functional activation Cerebral blood oxygenation Nitric oxide 610 Medizin 33 Medizin WW 1620 ddc:610
14	Nahinfrarotspektroskopie des Gehirns Obrig, Hellmuth 03 December 2002 (has links) Die Arbeit stellt die optische Methode der Nahinfraotspektroskopie (NIRS) in der Anwendung zur Messung von Oxygenierungsänderungen am Kopf des Erwachsenen dar. Dabei werden zunächst methodische Aspekte behandelt. Dies schließt (i) die Frage ein ob Änderungen des Redox-Status der Cytochromoxidase mit der NIRS bestimmt werden können; (ii) diskutiert die Ergebnisse zur Darstellbarkeit schneller optischer Signale, wie sie in invasiven Studien als Korrelat der elektrophysiologisch messbaren neuronalen Prozesse bekannt sind und (iii) richtet sich auf die bessere Definition des Messvolumens, sowohl im Sinne einer zweidimensionalen Bildgebung der Oxygenierungs-änderungen an der Hirnoberfläche als auch die Möglichkeiten zu einer Tiefenauflösung. Bezüglich der grundlegenden physiologischen Fragestellungen thematisiert die Arbeit im zweiten Teil Fragestellungen der neuro-vaskulären Kopplung. Dies ist die Frage, wie sich die neuronale, elektrophysiologisch meßbare Aktivität von Neuronen in eine hämodynamische Antwort übersetzt. Hier sind die Einordnung der NIRS-Befunde in ein Modell der vaskulären Antwort aber auch gleichzeitige Messungen mit elektrophysiologischen Methoden und weiteren vaskulär-basierten Methoden, insbesondere der funktionellen Kernspintomographie, Fokus. Schließlich stellt die Arbeit die klinischen Perspektiven in der Neurologie dar, wie sie sich besonders für die vaskulären Erkrankungen des Gehirns aber auch für Fragestellungen bei Epilepsie und Migräne ergeben. / We here present a optical method, near-infrared spectroscopy (NIRS), and its application for non-invasive measurement of oxygenation changes in the adult head. The first part deals with methodological aspects of NIRS. This includes (i) the question whether changes of cytochrome-oxidase redox state can be monitored by NIRS; (ii) the discussion of study results investigating the non-invasive detectability of fast optical signals , known to reflect electrophysiological changes in invasive animal preparations; (iii) and finally the issue how the sampling volume can be better defined, and with respect to a two-dimensional imaging approach of cortical oxygenation changes and the methodological options to achieve a depth resolution. In a second chapter we then focus on the underlying physiological issues mainly raising questions concerning neuro-vascular coupling. Neuro-vascular coupling means the translation of neuronal activity, as can be measured by electrophysiological methods, into the haemodynamic response. Here the focus is on how the results of functional NIRS studies can be interpreted in the light of a model of the vascular response. Also the simultaneous assessment of electrophysiological parameters or the parameters of other methods based on the vascular response, especially fMRI, are dealt with in this chapter. Finally the here presented work gives perspectives of potential clinical applications of the method. This primarily means the application in stroke and other vascularly diseases in neurology, but also includes questions in the clinical fields of epilepsy and migraine. funktionelle Bildgebung cerebrale Oxgenierung neurovaskuläre Kopplung Nahinfrarotspektroscopie functional imaging cerebral oxygenation neurovascular coupling near-infrared spectroscopy 610 Medizin 33 Medizin YG 1800 ddc:610
15	Altération du couplage neurovasculaire par l'angiotensine II : évaluation du rôle de la signalisation calcique astrocytaire Boily, Michaël 07 1900 (has links) No description available. Angiotensine II Astrocyte Récepteurs AT1 Calcium Récepteurs métabotropes du glutamate Couplage neurovasculaire Angiotensin II AT1 receptor Metabotropic glutamate receptor Neurovascular coupling
16	Étude du rôle de l’angiotensine II sur les fonctions cérébrales Duchemin, Sonia 08 1900 (has links) No description available. Angiotensine II Mémoire Lymphocyte T Couplage neurovasculaire Endothélium Angiotensin II Memory T lymphocyte Neurovascular coupling
17	Desenvolvimento de métodos ópticos para o estudo do acoplamento neuro-vascular-metabólico intrínseco à dinâmica cerebral / Development of optical methods to the study of neuro-metabolic-vascular coupling underlying cerebral dynamics Mesquita, Rickson Coelho, 1982- 02 September 2009 (has links) Orientador: Roberto Jose Maria Covolan / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Fisica Gleb Wataghin / Made available in DSpace on 2018-08-12T12:47:40Z (GMT). No. of bitstreams: 1 Mesquita_RicksonCoelho_D.pdf: 22300712 bytes, checksum: 11bd3fc16a125afc1c2cd8b4d18bc2e2 (MD5) Previous issue date: 2009 / Resumo: A atividade neuronal relacionada a um determinado estímulo ou tarefa induz uma cadeia de complexos eventos biológicos no cérebro. O aumento no consumo de energia induz um acréscimo na demanda por glicose e oxigênio no tecido extravascular. Fatores bioquímicos e neuronais induzem variações nos vasos sanguíneos que resultam em alterações de uxo sanguíneo, volume e oxigenação. Embora extensivamente investigada, esta cascata de eventos ainda é pouco compreendida. Neste projeto, procuramos descrever o acoplamento entre os níveis celular, metabólico e vascular associado à ativação funcional do cérebro. Usando medidas eletro fisiológicas, modelamos os sistemas neuro-vascular e neuro-metabólico para descrever a hemodinâmica cerebral medida através de técnicas ópticas. Resultados obtidos em ratos durante a estimulação de um fio de bigode mostraram que a determinação de uma função resposta para cada sistema, assumido como linear, descreve bem o comportamento hemodinâmico e possibilita o estudo dos estados vascular e metabólico caracterizados pelos parâmetros medidos. A partir de experimentos multimodais de NIRS e fMRI, desenvolvemos metodologias inovadoras para a determinação de imagens metabólicas, capazes de prever variações do consumo de oxigênio com boa resolução espacial e temporal. Por fim, analisamos a in u^encia de parâmetros fisiológicos no sinal óptico, mostrando a contribuição importante da pressão sanguínea na composição deste. Medidas de correlação temporal foram projetadas para gerar mapas de correlação vascular que podem ser aplicados ao estudo da conectividade vascular cerebral, tanto em indivíduos normais como em pacientes com patologias cerebrais. / Abstract: Task-associated neuronal activity leads to a complex chain of biological events within the brain. The increased energetics gives rise to elevated glucose and oxygen consumption in the tissue. Biochemical and neuronal factors induce changes in blood vessels and variations in blood ow, volume and oxygenation. Although it has been extensively investigated, this cascade of events is still poorly understood and highly debated. In this project, the aim was to describe the coupling among the cellular, metabolic and vascular levels associated to functional brain activation. Using electrophysiological measurements, we modeled the neuro-vascular and neuro-metabolic systems in order to describe cerebral hemodynamics as seen through optical techniques. Results obtained in rats during whisker-barrel stimulation showed that the determination of a response function for each system, assumed as linear, can describe the hemodynamic behavior and allow the study of the vascular and metabolic states characterized by the measurements. From multimodal experiments of NIRS and fMRI, we developed unique methods to the determination of metabolic images, which can predict changes in oxygen consumption with good temporal and spatial resolution. Finally, we analyzed the in uence of the physiology in the optical signal, and showed the importance of taking into account blood pressure oscillations into this signal. Measurements of temporal correlation were projected to generate vascular correlation maps that may be useful to the study of cerebral vascular connectivity, both in normal subjects and in patients with cerebral pathologies. / Doutorado / Metodos Oticos de Analise / Doutor em Ciências Espectroscopia no infravermelho próximo Acoplamento neurovascular Tomografia ótica de difusão Neuroimagem funcional Near-infrared spectroscopy Neurovascular coupling Diffuse optical tomography Functional neuroimaging
18	Imagerie biphotonique de la Po2 intracérébrale : une mesure de l’activité neuronale / Imaging Po2 transients in brain capillaries to monitor local neuronal activity Parpaleix, Alexandre 20 September 2013 (has links) L’imagerie fonctionnelle cérébrale détecte les changements hémodynamiques induits par un stimulus pour déterminer les zones d’activation neuronale. Plus particulièrement, l’imagerie BOLD en IRMf détecte les changements d’oxygénation du sang grâce aux propriétés paramagnétiques de la déoxyhémoglobine. L’oxygène n’est donc pas uniquement un substrat énergétique pour le tissu neuronal, il joue également un rôle majeur dans l’imagerie noninvasive du cerveau humain. Au cours de ma thèse, j’ai tout d’abord participé à la mise au point d’une nouvelle technique non-invasive d’imagerie de l’oxygène dans le cerveau d’animaux anesthésiés. Couplant un nouveau senseur phosphorescent de l’oxygène (Finikova et al., 2008) et la microscopie biphotonique, cette approche permet à la fois de cartographier l’oxygène en 3D avec une résolution spatiale et temporelle jusqu’alors inégalée, mais aussi de suivre simultanément l’oxygène et le flux sanguin dans les capillaires cérébraux au repos ou lors d’une activation neuronale (Lecoq et al., 2011). Tirant profit des nouvelles possibilités de cette technique, nous avons alors démontré: • la présence d’un shunt artério-veineux uniquement basé sur la diffusion de l’oxygène. Ce résultat, obtenu chez le rat dans la couche la plus superficielle du bulbe olfactif: la couche du nerf (ONL), confirme que l’oxygène ne diffuse pas uniquement à partir des capillaires et démontre que les artérioles contribuent significativement à l’oxygénation du tissu cérébral. Il démontre également qu’il n’est pas possible de déterminer ni la Po2 capillaire ni la Po2 tissulaire à partir de la Po2 veineuse. • l’existence de transitoires de Po2 associés à chaque globule rouge dans le compartiment capillaire, appelés EATs (erythrocyte-associated transients) (Hellums, 1977; Cabrales and Intaglietta, 2007). En bref, de part leur diamètre supérieur à celui de la lumière d’un capillaire, les globules rouges passent un à un dans la lumière des capillaires, laissant entre eux un espace de plasma. Cependant, la faible solubilité de l’oxygène dans le plasma crée une barrière à la diffusion, ce qui se traduit par une inhomogénéité de la Po2 capillaire: celle-ci est élevée au bord du globule rouge et décroit avec la distance pour atteindre un minimum à mi-distance entre deux globule rouges. Poursuivant l’étude des EATs (Parpaleix et al., 2013), nous avons observé les points suivants: • La Po2 tissulaire dans l’environnement immédiat d’un capillaire peut être déterminée à partir de la Po2 vasculaire à mi-distance entre deux érythrocytes. Ce résultat est intéressant en ce qu’il permettra d’effectuer des mesures non invasives de Po2 tissulaire, utile notamment chez l’animal éveillé. • L’amplitude des EATs est si large (35 mmHg en moyenne) que la Po2 capillaire moyenne ne reflète en rien la saturation en oxygène de l’hémoglobine. • Une empreinte filtrée des EATs vasculaires est détectable dans le tissu (_5 mmHg d’amplitude). • Au cours d’une stimulation neuronale, une diminution de la Po2 capillaire moyenne peut être détectée avant l’hyperémie fonctionnelle, un résultat jusqu’à présent controversé dans le domaine de l’imagerie BOLD en IRMf, mais important en ce que ce dip pourrait être un rapporteur très résolutif de l’activation neuronale. Parmi les questions restant en suspens et pouvant être étudiées finement avec notre approche, j’en citerai une principale: quel est le poids des différents facteurs (métaboliques, présynaptiques ou post-synaptiques) et du flux sanguin dans l’établissement de la Po2 cérébrale au repos? / In humans, functional mapping of brain activity mainly relies on the increase of cerebral blood flow (CBF) triggered by neuronal activation. This neurovascular coupling provides energy substrates such as oxygen and glucose to the activated area. The steady state concentration of oxygen, as well as its dynamics upon neuronal activation, have been investigated with numerous methods, however, none of them provided highly resolute measurements in depth. During my PhD, we combined a phosphorescence quenching approach with two-photon microscopy to detect, in depth and with a micrometer spatial resolution scale, the emission of phosphorescence by PtP-C343, a new oxygen nano-sensor designed for two-photon excitation. We first characterized the technique and then reported two biological results, using the olfactory bulb (OB) glomerulus as a model to study oxygen concentration, at rest and upon odor stimulation. We found an arterio-venous shunt, purely based on diffusion, in the superficial nerve layer of the OB, confirming the role of arterioles in brain oxygenation. Simultaneous measurements of Po2 and blood flow allowed us to reveal the presence of erythrocyte-associated transients (EATs), i.e. Po2 fluctuations that are associated with individual erythrocytes. Pursuing the investigation of EAT characteristics, we found that in capillaries, Po2 at mid-distance between two erythrocytes is at equilibrium with, and thus reports Po2 in the nearby neuropil. Finally, we could observe that even in capillaries, a small oxygen initial dip can be detected prior to functional hyperemia, upon odor activation. Oxygène Microcirculation Initial dip EAT Oxygen Po2 In vivo Two-photon Phosphorescence quenching Cerebral blood flow Diffusion Shunt Capillaries Microcirculation Olfaction Brain metabolism Neurovascular coupling 612.823 3
19	Autoregulation of the Human Cerebrovasculature by Neurovascular Coupling Farr, Hannah Abigail January 2013 (has links) Functional hyperaemia is an important mechanism by which increased neuronal activity is matched by a rapid and regional increase in blood supply. This mechanism is facilitated by a process known as “neurovascular coupling” – the orchestrated communication system involving the cells that comprise the neurovascular unit (neurons, astrocytes and the smooth muscle and endothelial cells lining arterioles). Blood flow regulation and neurovascular coupling are altered in several pathological states including hypertension, diabetes, Alzheimer’s disease, cortical spreading depression and stroke. By adapting and extending other models found in the literature, we create, for the first time, a mathematical model of the entire neurovascular unit that is capable of simulating two separate neurovascular coupling mechanisms: a potassium- and EET-based and a NO-based mechanism. These models successfully account for several observations seen in experiment. The potassium/EET-based mechanism can achieve arteriolar dilations similar in magnitude (3%) to those observed during a 60-second neuronal activation (modelled as a release of potassium and glutamate into the synaptic cleft). This model also successfully emulates the paradoxical experimental finding that vasoconstriction follows vasodilation when the astrocytic calcium concentration (or perivascular potassium concentration) is increased further. We suggest that the interaction of the changing smooth muscle cell membrane potential and the changing potassium-dependent resting potential of the inwardly rectifying potassium channel are responsible for this effect. Furthermore, our simulations demonstrate that the arteriolar behaviour is profoundly affected by depolarization of the astrocytic cell membrane, and by changes in the rate of perivascular potassium clearance or the volume ratio between the perivascular space and astrocyte. In the modelled NO-based neurovascular coupling mechanism, NO exerts its vasodilatory effects via neuronal and endothelial cell sources. With both sources included, the model achieves a 1% dilation due to a 60-second neuronal activation. When the endothelial contribution to NO production is omitted, the arteriole is more constricted at baseline. Without the endothelial NO contribution, the arteriolar change in diameter during neuronal activity is greater (6%). We hypothesize that NO has a dual purpose in neurovascular coupling: 1) it dixxxvi rectly mediates neurovascular coupling through release by neuronal sources, and 2) it indirectly modulates the size of the neurovascular coupling response by determining the baseline tone. Our physiological models of neurovascular coupling have allowed us to replicate, and explain, some of the phenomena seen in both neurovascular coupling-oriented and clinicallyoriented experimental research. This project highlights the fact that physiological modelling can be used as a tool to understand biological processes in a way that physical experiment cannot always do, and most importantly, can help to elucidate the cellular processes that induce or accompany our most debilitating diseases. blood flow regulation neurovascular coupling functional hyperaemia hyperemia vascular autoregulation neurons astrocytes arterioles smooth muscle cells endothelial cells astrocytes EET nitric oxide potassium inwardly rectifying physiological modelling computational modelling
20	Investigations into the effects of neuromodulations on the BOLD-fMRI signal Maczka, Melissa May January 2013 (has links) The blood oxygen level dependent functional MRI (BOLD-fMRI) signal is an indirect measure of the neuronal activity that most BOLD studies are interested in. This thesis uses generative embedding algorithms to investigate some of the challenges and opportunities that this presents for BOLD imaging. It is standard practice to analyse BOLD signals using general linear models (GLMs) that assume fixed neurovascular coupling. However, this assumption may cause false positive or negative neural activations to be detected if the biological manifestations of brain diseases, disorders and pharmaceutical drugs (termed "neuromodulations") alter this coupling. Generative embedding can help overcome this problem by identifying when a neuromodulation confounds the standard GLM. When applied to anaesthetic neuromodulations found in preclinical imaging data, Fentanyl has the smallest confounding effect and Pentobarbital has the largest, causing extremely significant neural activations to go undetected. Half of the anaesthetics tested caused overestimation of the neuronal activity but the other half caused underestimation. The variability in biological action between anaesthetic modulations in identical brain regions of genetically similar animals highlights the complexity required to comprehensively account for factors confounding neurovascular coupling in GLMs generally. Generative embedding has the potential to augment established algorithms used to compensate for these variations in GLMs without complicating the standard (ANOVA) way of reporting BOLD results. Neuromodulation of neurovascular coupling can also present opportunities, such as improved diagnosis, monitoring and understanding of brain diseases accompanied by neurovascular uncoupling. Information theory is used to show that the discriminabilities of neurodegenerative-diseased and healthy generative posterior parameter spaces make generative embedding a viable tool for these commercial applications, boasting sensitivity to neurovascular coupling nonlinearities and biological interpretability. The value of hybrid neuroimaging systems over separate neuroimaging technologies is found to be greatest for early-stage neurodegenerative disease. 616.8

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