Global ETD Search

11	Roles of voltage-gated ion channels in regulating the responses of principal neurons of the medial superior olive Khurana, Sukant 22 February 2011 (has links) The principal neurons of the medial superior olive (MSO) are considered to be responsible for transforming the temporal information present in the binaural acoustic stimulus into an output encoding sound location along the horizontal axis. Spatial resolution of sound localization depends critically on the time resolution with which MSO neurons can detect microsecond differences in the timing of inputs from the two ears. This fast temporal processing is contingent on voltage gated ion channels. The work presented in this thesis demonstrates that two currents, namely a hyperpolarization activated cationic current and low voltage activated potassium current dynamically interact to regulate the intrinsic time resolution of MSO neurons. We observe that the ability of MSO neurons to perform sub-millisecond temporal processing matures after birth, especially around the time of the clearing of the auditory canal. Hyperpolarization activated cationic current was found to be one of the underlying mechanisms transforming slow immature MSO neurons into temporally precise adult MSO neurons. / text Medial superior olive Low voltage activated potassium current Temporal processing
12	Maintenance of Neuron Activity by Homeostatic Alterations in Receptors and Ion Channels in a Rett Syndrome Mouse Model Oginsky, Max 18 December 2014 (has links) Rett Syndrome (RTT) is a developmental disorder that affects numerous neuronal systems that underlie problems with breathing, movement, cognition and sleep. RTT is caused by mutations in the methyl-CpG-binding protein 2 (Mecp2) gene. MeCP2 is a ubiquitous protein that is found in all mature neurons and binds to methylated DNA to repress transcription; thus regulating protein expression levels in neurons. The mutations in Mecp2 affect a large number of proteins that are crucial for regulating neuronal activity. Despite the abnormal expression of many of these proteins, mice with a total loss of MeCP2 can live to adulthood and some people with RTT can live to a very late age as well. It is possible that mutations in the Mecp2 gene not only cause widespread defects, but also elicit neuroadaptive processes that may limit the impact of the MeCP2 dysfunction. To test this hypothesis we performed these studies in which we focused on how synaptic and membrane currents were altered to maintain normal neuronal activity in Mecp2-null mice. We show two examples from different neurons where neuroadaptations of ion channel expression allowed the neuron to remain viable. First, the properties of the nicotinic acetylcholine receptor (nAChR) current were altered in LC neurons in Mecp2-null mice. This was caused by changes in the nicotinic receptor subunit expression. Despite the changes in the nAChR current, the cholinergic modulation of LC neuron activity in WT and Mecp2-null mice were similar. Secondly, we show that the fast Na+ voltage-gated and the hyperpolarization-activated currents were altered in mesencephalic trigeminal V (Me5) propriosensory neurons. The changes in the hyperpolarization-activated current caused a smaller sag and post-inhibitory rebound. Opposite to what we expected, these cells were hyperexcitable. The hyperexcitability was due to changes in the fast Na+ voltage-gated current causing a decreased action potential threshold. Alterations in the ionic currents in Me5 neurons seem to be due to changes in subunit expression patterns. These results indicate that despite the complications caused by defects in the Mecp2 gene, neurons respond by rearranging receptor / ion channel expression. This reorganization allows neurons to remain viable despite the MeCP2 deficiency. Rett syndrome Homeostasis Nicotinic receptor Hyperpolarization-activated current Voltage-gated sodium current Mecp2
13	Enhancement Strategies in NMR Spectroscopy Dücker, Eibe Behrend 05 May 2018 (has links) No description available. 540 SABRE PHIP NMR Parahydrogen Hyperpolarization Spectroscopy Field Dependence Chemie (PPN62138352X)
14	Use of atomic and molecular probes in NMR studies of materials and construction of a xenon-129 hyperpolarizer Saunavaara, J. (Jani) 27 August 2009 (has links) Abstract Xenon atoms and sulfur hexafluoride (SF6) molecules can be dissolved in liquids and liquid crystals or adsorbed in porous materials. Nuclear magnetic resonance (NMR) spectra of 129Xe or 19F nuclei reveal information about their surroundings. This means that xenon atoms and SF6 molecules can be used as probes to indirectly study materials by NMR spectroscopy. The change in the spectra arises from a NMR interaction called shielding. Especially in the case of xenon, shielding reveals even the slightest changes, for example, in the density of a liquid it is dissolved in. Because a change in temperature leads to a change in the density of the liquid as well, temperature change is observed as a shift of the resonance line in the 129Xe NMR spectrum. This property can be utilized in the accurate determination of the sample temperature. Self-diffusion measurements of the gases provide additional information on a larger scale rather than just the immediate surroundings of atoms or molecules. Various liquid crystals were studied using xenon and SF6 as probes proving their applicability. It is often considered that the signal observed in NMR experiments is very weak and limits the full potential of the method. This is true especially with the samples in gaseous form. The Spin-Exchange Optical Pumping (SEOP) hyperpolarization method solves this problem in the case of xenon. A 129Xe NMR signal can be enhanced by a factor of 104–105 by SEOP and this opens access to techniques that are not otherwise possible. The remote detection technique, which separates the encoding and detection steps of the typical NMR experiment both temporally and spatially, is one of these techniques. The potential of the combination of SEOP and remote detection techniques was shown in studies of thermally modified Pinus Sylvestris. diffusion hyperpolarization liquid crystal nuclear magnetic resonance spectroscopy remote detection shielding sulfur hexafluoride xenon
15	Investigation of room temperature multispin-assisted bulk diamond 13C hyperpolarization at low magnetic fields Wunderlich, Ralf, Kohlrautz, Jonas, Abel, Bernd, Haase, Jürgen, Meijer, Jan 25 April 2023 (has links) In this work we investigated the time behavior of the polarization of bulk 13C nuclei in diamond above the thermal equilibrium. This nonthermal nuclear hyperpolarization is achieved by cross relaxation between two nitrogen related paramagnetic defect species in diamond in combination with optical pumping. The decay of the hyperpolarization at four different magnetic fields is measured. Furthermore, we use the comparison with conventional nuclear resonance measurements to identify the involved distances of the nuclear spin with respect to the defects and therefore the coupling strengths. Also, a careful look at the linewidth of the signal give valuable information to piece together the puzzle of the hyperpolarization mechanism. info:eu-repo/classification/ddc/530 ddc:530
16	Dynamics of nuclear spins in unexplored arenas / 未踏領域の原子核スピンダイナミクス Wang, Yu 25 September 2023 (has links) 京都大学 / 新制・課程博士 / 博士(理学) / 甲第24871号 / 理博第4981号 / 新制\|\|理\|\|1711(附属図書館) / 京都大学大学院理学研究科化学専攻 / (主査)准教授武田和行, 教授堀毛悟史, 教授北川宏 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM nuclear spin diffusion nuclear hyperpolarization Lowe-Gade theory double nutation cross polarization frequency mixing 400
17	Ultrafast diffusion-ordered NMR analysis of mixtures / Analyse de mélanges par RMN diffusionnelle ultrarapide Guduff, Ludmilla 11 September 2018 (has links) La spectroscopie de résonance magnétique nucléaire (RMN) est un outil puissant qui permet l’étude directe de mélanges de manière non destructive. Les spectres RMN de petites molécules en solution peuvent être différenciés grâce à la stratégie DOSY (diffusion-ordered spectroscopy), une méthode de ‘chromatographie virtuelle’ qui s’appuie sur la mesure de coefficients de diffusion translationnelle. Les principaux obstacles à l’utilisation de la DOSY sont liés à la piètre sensibilité de la RMN de manière générale mais aussi à la nécessité d’introduire une dimension temporelle supplémentaire d’acquisition, ce qui va augmenter de manière significative la durée de l’expérience. Ce travail de thèse a pour objectif de mettre au point des outils inédits de RMN plus rapides et plus adaptés à la caractérisation de mélanges peu concentrés de petites molécules. Dans un premier temps, le concept de codage spatial de la diffusion dans l’expérience DOSY a été généralisé. Mis à profit dans les méthodes RMN dites ‘ultrarapides’, l’utilisation d’une dimension spatiale plutôt que temporelle pour encoder le phénomène de diffusion permet une accélération des expériences de RMN multidimensionnelles de plusieurs ordres de grandeur. L’acquisition séquentielle de spectres est remplacée par une acquisition parallèle de ces spectres dans différentes parties de l’échantillon. L’étude poussée des méthodes de DOSY rapides s’est appuyée sur des outils de simulation numérique dans le but d’améliorer la résolution des spectres et la précision des résultats. Les problèmes de sensibilité ont été abordés via le couplage des méthodes DOSY rapides avec des méthodes d’hyperpolarisation qui permettent d’augmenter l’intensité du signal. La combinaison des méthodes de diffusion conventionnelles avec les méthodes avancées de RMN ultrarapide et d’hyperpolarisation permettront des avancées significatives pour l’analyse de mélanges, en particulier les mélanges dynamiques. / NMR spectroscopy is a powerful tool that allows a direct study of mixtures in a non-invasive manner. The NMR spectra of molecular species in mixtures can be separated with diffusion-ordered spectroscopy (DOSY), a ‘virtual chromatography’ approach based on the measurement of translational diffusion coefficients. Major limitation of DOSY comes from the time-dependent diffusion dimension, which results in long experiment durations, and also from the low sensitivity of NMR. The present work aims to build an innovative tool for mixtures characterization that will be faster and more efficient for low concentrated samples. We first generalized the concept of nD spatially encoded (SPEN) DOSY experiments for the analysis of complex mixtures. As bring forward by the so-called “ultrafast NMR” (UF NMR), the use of a spatial dimension to encode diffusion can accelerate experiments by several orders of magnitude since it replaces the sequential acquisition of sub-experiments by a parallel acquisition in different slices of the sample. More advanced exploration of SPENDOSY were carried out using numerical simulations for purpose of resolution and accuracy improvement. To address sensitivity issues, we then demonstrated that SPENDOSY data can be collected for hyperpolarized substrates. This particular coupling between conventional diffusion-based method with advanced techniques such as ultrafast NMR and hyperpolarization should mark a significant progress for complex mixtures analysis especially for time-evolving processes. RMN ultrarapide RMN diffusionnelle (DOSY) Simulations numériques Mélanges Hyperpolarisation Ultrafast NMR Diffusion-Ordered spectroscopy (DOSY) Numerical simulation Mixtures Hyperpolarization
18	Study of new porous materials by NMR / Etude de nouveaux matériaux poreux par Résonnace Magnétique Nucléaire (RMN) Kunjir, Shrikant 17 January 2018 (has links) Les zéolites sont des «tamis moléculaires» connus pour leurs nombreuses applications en adsorption, échange d'ions et catalyse. Dans cette thèse, nous nous sommes concentrés sur l'étude de quelques questions liées à la synthèse et à la post-synthèse de la zéolithe, qui ne sont pas encore résolues par d'autres techniques.La RMN a été l'outil principal dans ce travail, donnant accès à des informations structurales locales sur les nanocristaux même lorsque les techniques de diffraction trouvent leurs limites. Elle peut également être utilisée pour étudier la porosité en utilisant l'adsorption de molécules sondes, et en particulier, le xénon est connu comme une bonne molécule pour cet objectif. En effet, l'isotope 129Xe peut être hyperpolarisé pour augmenter la sensibilité de détection, et il présente une large plage de déplacement chimique en fonction du confinement et donc de la porosité du matériau étudié.(I) Dans la première étude, les étapes initiales de la cristallisation de nano-faujasite (FAU) ont été étudiées en utilisant la RMN classique (principalement par 29Si et 23Na MAS RMN) et la RMN avancée (129Xe). RMN HP). Il a été montré que la cristallisation commence à des stades de synthèse bien antérieurs à ceux observés par d'autres techniques classiques (XRD, SEM, adsorption de N2 ...). La première SBU semble être les prismes hexagonaux, avant les cages sodalite, qui forment rapidement un environnement confiné puis des supercages. De plus, il a été démontré par RMN 129Xe HP et 2D EXSY que la zéolithe nano-faujasite présente des cages sodalite ouvertes et une structure plus souple que dans la zéolite de type micro-faujasite.(ii) La seconde étude est une recherche sur les phénomènes de recristallisation survenant au cours du processus de hiérarchisation de la zéolithe et qui pourrait expliquer la distribution homogène des tailles de mésopores. Comme résultat remarquable, il a été montré dans ce travail que lors de la hiérarchisation de la zéolithe bêta avec le TPAOH, la recristallisation conduisait à la formation de minuscules particules de MFI, formées à la surface des mésopores (RMN 1H MAS, RMN 129Xe HP et 2D EXSY). / The zeolites are ‘molecular sieves’ known for their numerous applications in adsorption, ion exchange, and catalysis. In this thesis, we focused on the study of some questions related to zeolite synthesis and post-synthesis, which are not yet resolved by other techniques. NMR was the primary tool in this work, as it gives access to local structural information on nanocrystals even when diffraction techniques found their limits. NMR can also be used to study porosity using probe molecules adsorption, and in particular, xenon is known as a good molecule for this purpose. Indeed, the isotope 129Xe can be hyperpolarized to increase the detection sensitivity, and interestingly it presents a wide chemical shift range depending on its confinement and thus the porosity of studied material. Two studies are reported in this manuscript: (i) In the first study, the initial steps during the crystallization of nano-faujasite (FAU) type materials were investigated using classical NMR (mainly by 29Si and 23Na MAS NMR) and advanced NMR (129Xe HP NMR). It was shown that crystallization starts at much earlier synthesis stages than those observed by other classical techniques (XRD, SEM, N2 adsorption…). The first SBU seems to be the hexagonal prisms, prior to the sodalite cages, which rapidly form confined environment and then supercages. Moreover, it has been proved by 129Xe HP NMR and 2D EXSY that nano-faujasite zeolite presents opened sodalite cages and a more flexible structure than in micro-faujasite zeolite. (ii) The second study is an investigation on the recrystallization phenomena occurring during hierarchization process of zeolite and which could explain the homogenous distribution of the mesopore sizes. As a remarkable result, it has been shown in this work that during the hierarchization of beta zeolite with TPAOH, the recrystallization lead to the formation of tiny MFI particles, formed at the surface of the mesopores (1H MAS NMR, 129Xe HP NMR and 2D EXSY). RMN à l’état solide RMN du 129Xe Hyperpolarisation Zeolite Porosity Structure Solid-state NMR 129Xe NMR Hyperpolarization 2D EXSY
19	The modified Synchronization Modulation technique revealed mechanisms of Na,K-ATPase Liang, Pengfei 03 April 2019 (has links) The Na/K pumps are essential for living system and widely expressed in all eukaryotic cell membranes. By actively transporting sodium ions out of and potassium ions into the plasma membrane, Na/K pumps creates both an electrical and a chemical gradient across the plasma membrane, which are crucial for maintaining membrane potential, cell volume, and secondary active transporting of other solutes, etc. Previously, oscillating electric field with a frequency close to the mean physiological turnover rate was used to synchronize and modulate the Na/K pump molecules. Results showed that the turnover rate of Na/K pumps can be accelerated by folds. However, this what we called first generation synchronization modulation (SM) technique can only synchronize sodium and potassium translocations into their corresponding half cycles. The detailed location of each sodium extrusion and potassium intrusion can not be determined. As a result, the synchronized pumps were uniformly distributed, generating steady-state macroscopic currents. Based on these studies, Dr.Chen developed a new generation synchronization modulation technique. The waveform of original SM by adding an overshoot pulse at the end of each half cycle. This overshoot pulse has a function of energy barrier which will force all of the Na/K pumps into the same state in the pumping cycle until the membrane polarity change. As a result, Na/K pump molecules are not only synchronized into half cycles of oscillating electric field, but individual steps of the pumping cycle. Accordingly, transient pump currents or so called 'pre-steady state' pump currents are generated, from which some detailed information abut the mechanism of Na/K pumps can be dissected. In this dissertation, we firstly characterized the synchronized pump currents by modified SM. The results showed that transient currents were induced at the beginning of each half cycle as expected. The ratio between positive and negative transient currents was close to 3:2, stoichiometric number of Na/K pump. Moreover, the transient currents were significantly reduced in the presence of ouabain in a time dependent manner. In addition, by gradually increasing the frequency of SM electric field in a step-wise fashion, the synchronized pump current can be modulated to the corresponding level. Next,we utilized this technique to study some detailed mechanisms of Na/K pump, including single channel configuration in transmembrane domain and extracellular D2O effect on the turnover rate. Lastly, we extended our study to applications of this new technique and found that the modified Synchronization Modulation technique can significantly hyperpolarize the membrane potential of skeletal muscle fiber in both physiological and high potasssium conditions. During intensive exercise, the interstitial potassium ions are accumulated and temporarily reach a high level, which will attenuate the contraction force and induce muscle fatigue. Na/K pumps are crucial in the maintenance of skeletal muscle excitability and contractility by restoring the Na and K concentration gradients. By accelerating the turnover rate of Na/K pumps, SM can efficiently re-establish the membrane potential and enhance skeletal muscle contractivity, which unleashes its potential in improving certain pathological conditions, such as exercise-induced hyperkalemia. Hyperpolarization of Membrane Potential Na,K-ATPase Oscillating Electric Field Synchronization and Modulation Transient Pump Current Biophysics Other Education
20	Nukleare Hyperpolarisation im Diamanten mittels Stickstoff-Fehlstellen-Zentren und komplexer Vier-Spin-Kopplung Wunderlich, Ralf 28 February 2018 (has links) In der vorliegenden Arbeit ist es in Kombination von Simulation und Experiment gelungen 13-C-Spins mithilfe von Stickstoff-Fehlstellen-(NV)-Zentren im Diamanten weit über das thermische Gleichgewicht hinaus zu polarisieren. Zu diesem Zweck wurde ein neues Mess-Setup entwickelt, welches eine optische Bestrahlung der Probe in einem niedrigen Magnetfeld und einen anschließenden Transfer der Probe innerhalb eines spuraleitenden Solenoiden ermöglicht. Somit ist bereits etwa eine Sekunde nach der optischen Bestrahlung eine NMR-Messung durchführbar. Auf diese Weise konnte erstmals der grundlegende Mechanismus für Hyperpolarisation einer Kreuz-Relaxation zwischen NV- und substitutionellen Stickstoff-(P1)-Zentren zugeordnet werden. Dabei ist die P1-intrinsische Hyperfeinaufspaltung der elektronischen Spin-Energie-Niveaus durch die Wechselwirkung mit dem nuklearen Stickstoffspin zu berücksichtigen und die aus einem statischen Jahn-Teller-Effekt resultierende Anisotrope dieser Hyperfeinwechselwirkung. Neben Hyperpolarisation durch 'erlaubte' Quantenübergänge im P1-Zentrum, konnten auch durch 'verbotene' Übergänge verursachte Hyperpolarisationen nachgewiesen werden. Der Vergleich der hyperpolarisierten NMR-Spektren und denen im thermischen Gleichgewicht weist eine fast drei Mal schmalere 13-C-Linie für den ersteren Fall auf. Dies deutet auf unterschiedliche Spin-Umgebung der gemessenen 13-C-Spins in beiden Fällen hin. info:eu-repo/classification/ddc/530 ddc:530

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