Global ETD Search

71	Biodistribution and biological impact of nanoparticles using multimodality imaging techniques : (Magnetic resonance imaging) Faraj, Achraf Al 30 June 2009 (has links) (PDF) As novel engineered nanoparticles such as single-walled carbon nanotubes (SWCNT) are extensively used in nanotechnology due to their superior properties, it becomes critical to fully understand their biodistribution and effect when accidently inhaled. There fore, development of animaging technique which allow longitudinal in vivo follow-up of SWCNT effect based on their intrinsic properties is highly desirable. Non invasive free-breathing hyperpolarized 3He lung MRI protocol was developed complementary to proton systemic MR protocol to allow monitoring SWCNT based on their intrinsic iron impurities after intrapulmonary exposition. Combined toproton lung MRI and ex vivo optical and electron microscopy at different time points, this protocol represents a powerful multimodality imaging techniques which allows a full characterization of the biodistribution and biological impacts of iron containing SWCNT. SWCNT was found to produce granulomatous and inflammatory reactions in a time and dose dependent manner with their bio persistenc eafter intrapulmonary exposition.From biological impact evaluations after intrapulmonary exposition towards biomedical applications, SWCNT hold promise for applications in nanomedicine field with their distinct architecture and their novel physicochemical properties. The biodistribution and pharmacological profile of various well-dispersed pristine and functionalized SWCNT were assessed in blood and target tissues after their intra venous administration by longitudinal in vivo susceptibility weighted MRI and their potential effect on liver metabolism by ex vivo HRMAS 1H NMR. No presence ofacute toxicological effect (variation in liver metabolism) was observed confirmed by the absence of clustering in NMR spectra using Principal Component Analysis (specific biomarkers of toxicity). HP-3He MRI Proton systemic MRI Lung imaging Nanoparticles Single-walled carbon nanotubes Biodistribution and biological impact Optical and electron microscopy Raman spectroscopy
72	Investigation of Electro-thermal and Thermoelectric Properties of Carbon Nanomaterials Verma, Rekha January 2013 (has links) (PDF) Due to the aggressive downscaling of the CMOS technology, power and current densities are increasing inside the chip. The limiting current conduction capacity(106 Acm−2)and thermal conductivity(201Wm−1K−1 for Al and 400 Wm−1K−1 for Cu) of the existing interconnects materials has given rise to different electro-thermal issues such a shot-spot formation, electromigration, etc. Exploration of new materials with high thermal conductivity and current conduction has thus attracted much attention for future integrated circuit technology. Among all the elemental materials, carbon nanomaterials (graphene and carbon nanotube) possess exceptionally high thermal (600-7000 Wm−1K−1) and current( ~108 -109 Acm−2)conduction properties at room temperature, which makes them potential candidate for interconnect materials. At the same time development of efficient energy harvesting techniques are also becoming important for future wireless autonomous devices. The excess heat generated at the hot-spot location could be used to drive an electronic circuit through a suitable thermoelectric generator. As the See beck coefficient of graphene is reported to be the highest among all elementary semiconductors, exploration of thermoelectric properties of graphene is very important. This thesis investigates the electrothermal and thermoelectric properties of metallic single walled carbon nanotube (SWCNT) and single layer graphene (SLG) for their possible applications in thermal management in next generation integrated circuits. A closed form analytical solution of Joule-heating equation in metallic SWCNTs is thus proposed by considering a temperature dependent lattice thermal conductivity (κ) on the basis of three-phonon Umklapp, mass-diﬀerence and boundary scattering phenomena. The solution of which gives the temperature profile over the SWCNT length and hence the location of hot-spot(created due to the self-heating inside the chip) can be predicted. This self-heating phenomenon is further extended to estimate the electromigration performance and mean-time-to-failure of metallic SWCNTs. It is shown that metallic SWCNTs are less prone to electromigration. To analyze the electro-thermal effects in a suspended SLG, a physics-based flexural phonon dominated thermal conductivity model is developed, which shows that κ follows a T1.5 and T−2 law at lower(<300 K) and higher temperature respectively in the absence of isotopes(C13 atoms). However in the presence of isotopic impurity, the behavior of κ sharply deviates from T−2 at higher temperatures. The proposed model of κ is found to be in excellent match with the available experimental data over a wide range of temperatures and can be utilized for an efficient electro-thermal analysis of encased/supported graphene. By considering the interaction of electron with in-plane and flexural phonons in a doped SLG sheet, a physics-based electrical conductance(σ) model of SLG under self-heating effect is also discussed that particularly exhibits the variation of electrical resistance with temperature at different current levels and matches well with the available experimental data. To investigate the thermoelectric performance of a SLG sheet, analytical models for See beck effect coefficient (SB) and specific heat (Cph) are developed, which are found to be in good agreement with the experimental data. Using those analytical models, it is predicted that one can achieve a thermoelectric figure of merit(ZT) of ~ 0.62 at room temperature by adding isotopic impurities(C13 atoms) in a degenerate SLG. Such prediction shows the immense potential of graphene in waste-heat recovery applications. Those models for σ, κ, SB and Cph are further used to determine the time evolution of temperature distribution along suspended SLG sheet through a transient analysis of Joule-heating equation under the Thomson effect. The proposed methodology can be extended to analyze the graphene heat-spreader theory and interconnects and graphene based thermoelectrics. Carbon Nanomaterials Carbon Nanotubes Graphene Carbon Nanomaterials - Synthesis Carbon Nanomaterials - Electromigration Single Layer Graphene Carbon Materials - Thermal Management Metallic Single Walled Carbon Nanotubes Metallic SWCNT Single Layer Graphene (SLG) Nanotechnology
73	Propriétés magnéto-optiques de nanotubes de carbone individuels suspendus / Magneto-optical properties of individual suspended carbon nanotubes Gandil, Morgane 17 July 2017 (has links) Cette thèse est consacrée à l’étude expérimentale des propriétés magnéto-optiques intrinsèques des nanotubes de carbone mono-paroi par spectroscopie de photoluminescence résolue en temps.Un dispositif de microscopie optique confocale de grande ouverture numérique (NA = 0.95),incluant un cryostat magnétique, permet l’étude de nanotubes suspendus à l’échelle individuelle,à température cryogénique (jusqu’à 2 Kelvin) et sous champ magnétique (jusqu’à 7 Tesla). L’évolution des spectres et des déclins de photoluminescence avec le champ magnétique montre l’influence de l’effet Aharonov-Bohm sur les deux excitons singulets de plus basse énergie, c’est à-dire l’exciton fondamental qui est optiquement inactif (exciton noir) et un exciton d’énergie supérieure séparé de quelques milliélectronvolts qui est optiquement actif (exciton brillant). L’interprétation de ces résultats à partir d’un modèle d’équations de taux qui intègre le couplage Aharonov-Bohm entre ces deux excitons permet de déterminer séparément les durées de vie excitoniques et de fournir des informations quantitatives sur la relaxation de l’énergie depuis les niveaux supérieurs photo-excités. La relaxation de l’énergie suite à la photo-excitation de la transition S22 conduit à une efficacité de peuplement de l’état brillant quatre fois plus faible que celle de l’état noir, mais qui augmente significativement lorsque la relaxation se produit depuis les niveaux excitoniques KK’. D’autre part, le bon rapport signal à bruit obtenu dans les spectres de photoluminescence permet de révéler l’existence d’un couplage intrinsèque en champ nul entre l’exciton noir et l’exciton brillant ainsi que le maintien de la mobilité excitonique dans les nanotubes suspendus à la température de l’hélium liquide. / This thesis is dedicated to the experimental study of the intrinsic magneto-optical properties of single-walled carbon nanotubes through time-resolved photoluminescence spectroscopy. Measurements are performed on suspended nanotubes samples at the single-object level using a home-built confocal optical microscope with a large numerical aperture (NA = 0.95) operating at cryogenic temperature (down to 2K) and high magnetic field (up to 7T). The evolution of the photoluminescence spectra and decay signals with increasing magnetic fields shows the influence of the Aharonov-Bohm effect on the two lowest-energy singlet excitons, namely the ground exciton which is optically inactive (dark exciton) and an exciton lying a few millielectron volts higher in energy which is optically active (bright exciton). A model of these results based on rate equations and including the Aharonov-Bohm coupling between these two excitons enables to determine separately the excitons lifetimes and to derive quantitative information on the energy relaxation from the photo-excited higher levels. The energy relaxation following the photo-excitation of the S22 transition leads to a bright state population efficiency four times lower than that of the dark state, but it significantly increases when energy relaxation occurs from the KK’ excitonic levels. Thanks to a good signal to noise ratio, the photoluminescence spectra also reveal the presence of an intrinsic zero-field coupling between the dark and the brightexcitons, as well as an excitonic mobility preserved at liquid helium temperature in suspended nanotubes. Nanotubes de carbone mono-paroi Photoluminescence Structure fine excitonique Effet Aharonov-Bohm Couplage exciton-phonon Single-walled carbon nanotubes Photoluminescence Excitonic fine structure Aharonov-Bohm effect Exciton-phonon coupling
74	Cage de résonance à base de films minces transparents et conducteurs de nanotubes de carbone Dionne, Éric R. January 2008 (has links) Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal. Cage de résonance Films minces Microscopie à force atomique Nanotubes de carbone mono-parois Plasmon de surface Atomic force microscopy Ellipsometric spectroscopy Resonance cavity Single-walled carbon nanotubes Surface plasmon resonance Thin films UV-vis-NR absorbance spectrocopy
75	Étude du potentiel cytotoxique des nanotubes de carbone simple-paroi chez les cellules épithéliales alvéolaires humaines A549 Ali Abbas, Zeinab 08 1900 (has links) No description available. A549 Nanotube de carbone simple-paroi Viabilité cellulaire Prolifération cellulaire Toxicité Dysfonction mitochondriale Cell proliferation Cell viability Single-walled carbon nanotubes Toxicity Mitochondrial dysfunction
76	Optical pH sensor based on carbon nanomaterials and metal redox chemistry Shoghi, Fatemeh(Natasha) 06 1900 (has links) Most pH sensors operate under potentiometric conditions using a simple two-electrode scheme. More generally, a conventional meter measures the electrical potential of the solution using a glass electrode (pH) against another electrode (reference), whose electrochemical potential is known and insensitive to pH. Modern pH sensors are robust, accurate and low cost, but they are limited by the macroscopic electrode size. They also require electrical contacts and they are often affected by errors associated with the contamination of the small electrode liquid junctions. This thesis targets pH measurements at nanoscale interfaces and explores the miniaturization of the pH sensor for local and remote (optical) measurements. By taking advantage of a non-destructive optical technique based on Raman spectroscopy and of the redox chemistry of metals, this work aims to develop a remote pH sensor based on carbon nanomaterials, namely the single walled carbon nanotube (SWCNT) and the graphene in the form of a single layer. By making use of the highly sensitive Raman response of metallic SWCNTs, we devised a pH responsive optical probe consisting of a SWCNT in direct contact with a platinum redox couple. When placed in a buffer solution, the Pt-SWCNT probe shows strong Raman shifts of the nanotube G-band as a function of pH, which is ascribed to charge transfer doping of the SWCNT reference electrode. Referenced potential measurements are demonstrated using a nanoscale version of the Pt-SWCNT electrode, along with the accurate monitoring of pH in solutions of different ionic strengths. Controlled experiments at a constant ionic strength show pH measurement across the full range between 1 to 12 with a best accuracy of ±500 mpH unit. This study also explores the influence of different transition metals (Pt, Ru and Pd), of semiconducting vs. metallic SWCNTs, and supporting substrates on pH sensing. A model based on electron transfer between the redox metal system and the SWCNT is proposed and tested using electrical conductance measurements. Due to the outstanding properties of graphene, such as a semi metallic behavior and its relatively inert surface, graphene was selected as a second nanomaterial to further investigate the Raman-pH sensing. From the study with SWCNTs, which determines optimal response with the Pt/PtO redox couple, we explore the Raman response of graphene coated with a thin layer of Pt in different buffer solutions of pH between 1 and 12. The spectra show clear evidence of charge transfer and doping of graphene in contact with the platinum redox couple. Significant Raman shift with pH is noted in the region of the G-band and also in D-band, which are consistent with the behavior found with the metallic Pt-SWCNT system. An analysis of the Raman shift provides a better understanding of the doping behavior observed for different pH. The analysis provides an estimate of the potential and confirms the Nernstian behavior of the pH sensor. Redox pH sensing at the nanoscale using carbon nanomaterials solves the main limitations highlighted above, namely coverage of the full pH range and a clear miniaturization of the sensor down to the nanometer scale. Although the accuracy requires further improvement, this work demonstrates for the first time an optical pH sensing scheme that is analogous to a conventional pH sensor equipped with a built-in internal reference. / La plupart des capteurs de pH fonctionnent dans des conditions potentiométriques en utilisant un schéma simple à deux électrodes. Plus généralement, un pH mètre classique mesure le potentiel électrique de la solution à l'aide d'une électrode en verre (pH) contre une autre électrode (référence), dont le potentiel électrochimique est connu et insensible au pH. Les capteurs de pH modernes sont robustes, précis et peu coûteux, mais ils sont limités par les tailles macroscopiques des électrodes. Ils nécessitent également des contacts électriques et sont souvent affectés par des erreurs liées à la contamination des petites jonctions liquides des électrodes. Cette thèse concerne l'amélioration des mesures de pH aux interfaces nanométriques et explore la miniaturisation du capteur de pH pour des mesures (optiques) locales et à distance. En tirant parti d'une technique optique non destructive basée sur la spectroscopie Raman et de la chimie redox des métaux, ce travail vise à développer un capteur de pH à distance à base de nanomatériaux de carbone, à savoir le nanotube de carbone à simple paroi (SWCNT) et le graphène monofeuillet. En utilisant la réponse Raman très sensible des SWCNT métalliques, nous avons conçu une sonde optique sensible au pH constituée d'un SWCNT en contact direct avec un couple redox platine. Lorsqu'elle est placée dans une solution tampon, la sonde Pt-SWCNT montre un fort décalage Raman de la bande G du nanotube en fonction du pH, qui est attribué au dopage par transfert de charge de l'électrode de référence SWCNT. La mesure du potentiel référencé est démontrée à l'aide d'une version nanométrique de l'électrode Pt-SWCNT, ainsi que par la surveillance précise du pH dans des solutions de différentes forces ioniques. Des expériences contrôlées à force ionique constante montrent des mesures de pH sur toute la gamme entre 1 et 12 avec une précision allant jusqu'à ± 500 mpH. Cette étude explore également l'influence de différents métaux de transition (Pt, Ru et Pd), du caractère électronique des SWCNTs et des substrats de soutien sur les détection de pH. Un modèle basé sur le transfert d'électrons entre le système métallique redox et le SWCNT est proposé et testé à l'aide de mesures de conductance électrique. En raison des propriétés exceptionnelles du graphène, telles qu'un comportement semi-métallique et une surface relativement inerte, le graphène a été sélectionné comme deuxième nanomatériau pour approfondir la détection Raman-pH. À partir de l'étude avec les SWCNT, qui détermine qu'une réponse optimale est obtenue avec le couple redox Pt / PtO, nous explorons la réponse Raman du graphène recouvert d'une fine couche de Pt dans différentes solutions tampons avec pH iv entre 1 et 12. Les spectres montrent des preuves claires de transfert de charge et dopage du graphène en contact avec le couple redox platine. Un décalage Raman significatif avec le pH est noté dans la région de la bande G et également dans la bande D, ce qui est cohérent avec le comportement trouvé avec le système Pt-SWCNT métallique. Une analyse du décalage Raman permet de mieux comprendre le comportement de dopage observé à différents pH. L'analyse fournit une estimation du potentiel et confirme le comportement Nerstien du capteur de pH. La détection de pH redox à l'échelle nanométrique avec des nanomatériaux de carbone permet de résoudre les principales limitations mises en évidence ci-dessus, à savoir la couverture de toute la gamme de pH et une miniaturisation claire du capteur jusqu'à l'échelle nanométrique. Bien que la précision nécessite une amélioration supplémentaire, ce travail démontre pour la première fois un schéma de détection optique du pH qui est analogue à un capteur de pH conventionnel équipé d'une référence interne intégrée. capteur de pH nanotubes de carbone à paroi simple graphène couple redox Pt spectroscopie Raman pH sensor Single-Walled Carbon Nanotubes graphene Pt redox couple Raman spectroscopy
77	A Theoretical Study: The Connection between Stability of Single-Walled Carbon Nanotubes and Observed Products / En Teoretisk Studie: Sambandet mellan Stabiliteten for Enkelväggiga Kolnanorör och Observerade Produkter Hedman, Daniel January 2017 (has links) Over the past 20 years’ researchers have tried to utilize the remarkable properties of single-walled carbon nanotubes (SWCNTs) to create new high-tech materials and devices, such as strong light-weight composites, efficient electrical wires and super-fast transistors. But the mass production of these materials and devices are still hampered by the poor uniformity of the produced SWCNTs. These are hollow cylindrical tubes of carbon where the atomic structure of the tube wall consists of just a single atomic layer of carbon atoms arranged in a hexagonal grid. For a SWCNT the orientation of the hexagonal grid making up the tube wall is what determines its properties, this orientation is known as the chirality of a SWCNT. As an example, tubes with certain chiralities will be electrically conductive while others having different chiralities will be semiconducting. Today’s large scale methods for producing SWCNTs, commonly known as growth of SWCNTs, gives products with a large spread of different chiralities. A mixture of chiralities will give products with a mixture of different properties. This is one of the major problems holding back the use of SWCNTs in future materials and devices. The ultimate goal is to achieve growth where the resulting product is uniform, meaning that all of the SWCNTs have the same chirality, a process termed chirality-specific growth. To achieve chirality-specific growth of SWCNTs requires us to obtain a better fundamental understanding about how they grow, both from an experimental and a theoretical point of view. This work focuses on theoretical studies of SWCNT properties and how they relate to the growth process, thereby giving us vital new information about how SWCNTs grow and taking us ever closer to achieving the ultimate goal of chirality-specific growth. In this thesis, an introduction to the field is given and the current state of the art experiments focusing on chirality-specific growth of SWCNTs are presented. A brief review of the current theoretical works and computer simulations related to growth of SWCNTs is also presented. The results presented in this thesis are obtained using first principle density functional theory. The first study shows a correlation between the stability of SWCNT-fragments and the observed products from experiments. Calculations confirm that in 84% of the investigated cases the chirality of experimental products matches the chirality of the most stable SWCNT-fragments (within 0.2 eV). Further theoretical calculations also reveal a previously unknown link between the stability of SWCNT-fragments and their length. The calculations show that at specific SWCNT-fragment lengths the most stable chirality changes. Thus, introducing the concept of a switching length for SWCNT stability. How these new results link to the existing understanding of SWCNT growth is discussed at the end of the thesis. Single-walled carbon nanotubes density functional theory catalytic chemical vapor deposition chirality-specific growth stability length diameter edge chirality Condensed Matter Physics Den kondenserade materiens fysik Atom and Molecular Physics and Optics Atom- och molekylfysik och optik
78	Sondes à nanotubes de carbone mono-paroi pour la microscopie à force atomique : synthèse et imagerie à l'air et en milieu liquide / Single-walled carbon nanotube probes for atomic force microscopy : synthesis and imaging in air and in liquid Luu, Ngoc Mai 24 May 2019 (has links) La microscopie à force atomique (AFM) permet d’étudier à l’échelle nanométrique la surface d’échantillons. Elle offre de nombreux avantages par rapport aux microscopes optiques et aux microscopes électroniques, tout en évitant des étapes de préparation particulières : pas de nécessité de congeler, de métalliser ou de teinter l’échantillon ni de travailler sous vide. La résolution de l'imagerie AFM est principalement déterminée par la morphologie de la sonde utilisée et peut atteindre la résolution moléculaire. Toutefois, les sondes en silicium sont très fragiles. De plus, leur forme pyramidale ou conique génère des artefacts sur l’image résultante. Parmi les sondes actuellement en développement, les sondes à nanotubes de carbone mono-paroi offrent de bonnes caractéristiques en termes de qualité d'imagerie et de longévité. Ces sondes sont plus résistantes et de plus petite taille que les sondes traditionnelles.Cette thèse s’intéresse à la fabrication directe de sondes à nanotubes mono-paroi sur des extrémités de pointes AFM commerciales par la méthode de dépôt chimique en phase vapeur assistée par filament chaud dans un réacteur développé au CBMN. En jouant sur les paramètres de synthèse, tels que la quantité de catalyseur ou la température, nous optimisons le protocole de synthèse originel en collaboration avec son auteur Anne-Marie Bonnot afin de l’adapter à notre réacteur. Les nanotubes obtenus sont caractérisés par les microscopies Raman, électronique à balayage et transmission et à force atomique. La caractérisation montre que les nanotubes obtenus ont une structure mono-paroi. Le rendement d’obtention de sondes nanotubes utilisables est de 30%.Les courbes d’approche-retrait d'AFM nous donnent des informations sur la sonde à nanotube utilisée, telles que sa raideur, le nombre de nanotubes en contact avec la surface. Ces courbes nous permettent de sélectionner les paramètres d’imagerie. Deux échantillons sont testés avec les sondes produites : du graphite pyrolytique haute orientation et des origamis d’ADN rectangulaires. Nous réalisons des expériences d’imagerie avec des sondes à nanotube dans l’air en mode dynamique FM et en milieu liquide en mode Peak Force. Les résultats montrent des images à haute résolution de l’origami d’ADN où la période de 5,8 nm est observable. Les sondes à nanotube présentent également une plus longue durée de vie que les pointes AFM en silicium. / Atomic force microscopy (AFM) is used to study at nanometer scale samples on surfaces. It offers many advantages over conventional optical microscopes and electron microscopes: no freezing, metal coating, vacuum or dye is needed to prepare the sample. The AFM imaging resolution is mostly determined by the sharpness of the used probe and can reach molecular resolution. However, silicon probes are brittle. Additionally, their pyramidal or conical shape generates artifacts on the resulting image. Among the probes currently under development, single-walled carbon nanotube probes offer good characteristics in terms of imaging quality and longevity. These probes are more resistant and smaller in size than traditional probes.This thesis focuses on the direct fabrication of single-wall nanotube probes at the apex of commercial AFM tips by the hot-filament chemical vapor deposition method in a reactor developed at CBMN. By playing on the synthesis parameters, such as the amount of catalyst or the temperature of synthesis, we optimize the original synthesis protocol in collaboration with its author Anne-Marie Bonnot in order to adapt it to our reactor. The nanotubes obtained are characterized by Raman, scanning electron microscopy and transmission electron microscopy and AFM. The characterization shows that the nanotubes obtained have a single-wall structure. The yield of nanotube probes for AFM is 30%.AFM approach-retract curves give us information about the nanotube probe used, such as its stiffness or the number of nanotubes in contact with the surface. These curves allow us to select the imaging parameters. Two samples are tested with the produced probes: highly oriented pyrolytic graphite and rectangular DNA origamis. We image the samples with nanotube probes in both air with dynamical FM mode and in liquid medium with Peak Force mode. The results show high resolution images of DNA origami where the 5.8 nm period is observable. Nanotube probes also have longer life than silicon AFM tips. Sonde à Nanotube de Carbone Mono-Paroi AFM en Phase Liquide Hfcvd AFM Peak Force Pointe AFM à nanotube de carbone Single-Walled carbon nanotube probe AFM in Liquide Phase Hot filament CVD AFM Peak Force Carbon nanotube tip
79	Numerical Modeling and Characterization of Vertically Aligned Carbon Nanotube Arrays Joseph, Johnson 01 January 2013 (has links) Since their discoveries, carbon nanotubes have been widely studied, but mostly in the forms of 1D individual carbon nanotube (CNT). From practical application point of view, it is highly desirable to produce carbon nanotubes in large scales. This has resulted in a new class of carbon nanotube material, called the vertically aligned carbon nanotube arrays (VA-CNTs). To date, our ability to design and model this complex material is still limited. The classical molecular mechanics methods used to model individual CNTs are not applicable to the modeling of VA-CNT structures due to the significant computational efforts required. This research is to develop efficient structural mechanics approaches to design, model and characterize the mechanical responses of the VA-CNTs. The structural beam and shell mechanics are generally applicable to the well aligned VA-CNTs prepared by template synthesis while the structural solid elements are more applicable to much complex, super-long VA-CNTs from template-free synthesis. VA-CNTs are also highly “tunable” from the structure standpoint. The architectures and geometric parameters of the VA-CNTs have been thoroughly examined, including tube configuration, tube diameter, tube height, nanotube array density, tube distribution pattern, among many other factors. Overall, the structural mechanics approaches are simple and robust methods for design and characterization of these novel carbon nanomaterials CNT Carbon nanotube SWCNT Single walled carbon nanotube DWCNT Double walled carbon nanotube MWCNT Multi walled carbon nanotube VA-CNT Vertically aligned carbon nanotube CVD Chemical vapor deposition EAD / CAD Applied Mechanics Nanoscience and Nanotechnology Other Mechanical Engineering Structural Materials Structures and Materials
80	Biodistribution and biological impact of nanoparticles using multimodality imaging techniques : (Magnetic resonance imaging) / Biodistribution et effet biologique des nanoparticules utilisant des techniques d’imagerie multimodale : (Imagerie de résonance magnétique) Faraj, Achraf Al 30 June 2009 (has links) En raison de leurs propriétés uniques, des nanoparticules industriellement fabriquées comme les nanotubes de carbone (NTC) ont révolutionné le domaine de la nanotechnologie. Il apparait nécessaire de développer des techniques d’investigation in vivo basées sur les propriétés intrinsèques de ces particules et permettant un suivi longitudinal pour évaluer leur risque après inhalation accidentelle par voie respiratoire. Un protocole d’IRM pulmonaire non-invasive utilisant l’hélium-3 hyper polarisé sous respiration spontanée a été développé en complément d’un protocole d’IRM systémique proton pour permettre la détection des NTC grâce à l’effet de susceptibilité magnétique induit par les impuretés de fer, associées aux nanotubes après leur exposition intra pulmonaire. Combiné avec l’IRM pulmonaire proton et des analyses en microscopie optique et électronique à différents temps d’investigation, ce protocole d’imagerie multimodale permet d’évaluer la biodistribution et l’impact biologique des NTC bruts après exposition intra pulmonaire.Une accentuation des réactions inflammatoires (granulomes multifocaux, dépôt de fibres de collagène…) avec le temps et la dose administrée a été observée.De l’évaluation de l’impact biologique des NTC après une exposition intra pulmonaire vers leurs applications biomédicales, les nanotubes de carbone avec leurs propriétés physicochimiques fascinantes et leur forme spécifique laissent entrevoir des applications potentielles en nanomédecine. La bio distribution et le profil pharmacologique des différents types de NTC ont été évalués longitudinalement par IRM et dosage dans le sang et les organes cibles après une injection intraveineuse, et leur impact biologique sur le métabolisme du foie a été examiné ex vivo par RMN haute résolution à l’angle magique (HR-MAS). Aucun signe de toxicité aiguë (variation du métabolisme du foie) n’a été observé et les analyses statistiques conduits sur les spectres RMN (tests PCA) ne montrent aucune différence entre les échantillons analysés et donc l’absence de discrimination entre les différents groupes par rapport aux animaux contrôles. / As novel engineered nanoparticles such as single-walled carbon nanotubes (SWCNT) are extensively used in nanotechnology due to their superior properties, it becomes critical to fully understand their biodistribution and effect when accidently inhaled. There fore, development of animaging technique which allow longitudinal in vivo follow-up of SWCNT effect based on their intrinsic properties is highly desirable. Non invasive free-breathing hyperpolarized 3He lung MRI protocol was developed complementary to proton systemic MR protocol to allow monitoring SWCNT based on their intrinsic iron impurities after intrapulmonary exposition. Combined toproton lung MRI and ex vivo optical and electron microscopy at different time points, this protocol represents a powerful multimodality imaging techniques which allows a full characterization of the biodistribution and biological impacts of iron containing SWCNT. SWCNT was found to produce granulomatous and inflammatory reactions in a time and dose dependent manner with their bio persistenc eafter intrapulmonary exposition.From biological impact evaluations after intrapulmonary exposition towards biomedical applications, SWCNT hold promise for applications in nanomedicine field with their distinct architecture and their novel physicochemical properties. The biodistribution and pharmacological profile of various well-dispersed pristine and functionalized SWCNT were assessed in blood and target tissues after their intra venous administration by longitudinal in vivo susceptibility weighted MRI and their potential effect on liver metabolism by ex vivo HRMAS 1H NMR. No presence ofacute toxicological effect (variation in liver metabolism) was observed confirmed by the absence of clustering in NMR spectra using Principal Component Analysis (specific biomarkers of toxicity). IRM hélium-3 IRM proton systémique Imagerie pulmonaire Nanoparticules Nanotubes de carbone Biodistribution et effet biologique Microscopie optique et électronique RMN HR-MAS proton Spectroscopie Raman HP-3He MRI Proton systemic MRI Lung imaging Nanoparticles Single-walled carbon nanotubes Biodistribution and biological impact Optical and electron microscopy Raman spectroscopy

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