Multifunctional Magnetic Nanoparticles for Cancer Imaging and Therapy

Foy, Susan Patricia

30 January 2012

No description available.

Biomedical Engineering

Biomedical Research

Nanoscience

Nanotechnology

Oncology

magnetic nanoparticles

magnetic resonance imaging

optical imaging

NIR dyes

drug delivery

Doxorubicin

Paclitaxel

iron-oxide

Fenton reaction

cancer

Organometallic approach to the growth of metallic magnetic nanoparticles in solution and on substrates / Approche organométallique de la synthèse de nanoparticules métalliques magnétiques en solution et sur des substrats

Liakakos, Nikolaos

08 July 2013

Cette thèse concerne une nouvelle méthode chimique de croissance par germes qui peut produire des assemblés de nanostructures métalliques epitaxiées sur des surfaces macroscopiques cristallines qui agissent comme germes. Cette approche permet d’obtenir des assemblés bien organisées en échelle centimétrique de nanofils métalliques de Co, qui sontmonocristallins, monodisperses de diamètres inferieurs à 10nm et qui ont une orientation perpendiculaire. Ils ont une anisotropie magnétique perpendiculaire et sont intéressantes pour des applications d’enregistrement magnétique à très haute densité. L’extension de cette méthode au fer donne des films nanostructurés de fer. L’orientation des nanostructures sur le support solide dépend de l’orientation cristallographique du substrat, alors que leur morphologie est dictée par la composition de la solution. Cet objectif a été atteint grâce à des études parallèles sur le mécanisme de croissance de nano-cristaux de cobalt en solution qui ont révélées une influence inattendue de la procédure de préparation de la solution mère sur la morphologie des nanocristaux. En plus,l’utilisation des germes nanoscopiques pour la croissance de Co et de Fe a rendu des nanofils longs de Co et des altères de Co-Fe et elle a contribué à la définition et l’amélioration des conditions expérimentales pour la croissance par germes de Co et de Fe sur les substrats solides. / This thesis concerns a new wet chemical seeded growth method that can produce arrays of metal nanostructures epitaxially grown on crystalline macroscopic surfaces which act as seeds. This approach produces wafer-scale organized 2D hexagonal arrays of perpendicularly oriented, monodisperse and monocrystalline metallic Co nanowires with diameters below 10 nm which exhibit perpendicular magnetic anisotropy and are interesting for applications in ultra high density magnetic recording. Extension of this approach to iron gives rise to nanostructured iron films. The orientation of the nanostructures on the solid substrate depends on the substrate crystallographic orientation, whereas their morphology is dictated by the solution composition. This objective was attained through parallel studies on the growth mechanism of cobalt nano-crystals in solution which revealed an unexpected influence of the stock solution preparation procedure on the nanocrystal morphology. In addition, the use of nanoscopicseeds for the overgrowth of cobalt and iron gave rise to long Co nanowires and Co-Fe dumbbells and contributed to the definition and the improvement of the experimental conditions for the seeded growth of Co and Fe on the solid substrates

Cobalt

Fer

Nanoparticules

Nano-objets hybrides

Nanoparticules magnétiques

Croissance par germes

Croissance épitaxiale

Assemblés de nanofils

Couches minces

Cobalt

Hybrid nano-objects

Magnetic nanoparticles

Seeded growth

Epitaxial growth

Nanowire arrays

Thin films

Nanoparticles

Iron

620.5

FePt magnetic nanoparticles : syntheses, functionalisation and characterisation for biomedical applications

Chen, Shu

January 2011

Iron platinum (FePt) has attracted growing interest because of its high Curie temperature, magneto-crystalline anisotropy and chemical stability. Nanoparticles (NPs) made of this alloy are promising candidates for a wide range of biomedical applications including magnetic separation, magnetic targeted drug delivery, hyperthermia for cancer therapy and also as magnetic resonance imaging (MRI) contrast agents. This thesis presents the synthesis, functionalization and characterization of FePt NPs along with a toxicity study and an investigation into their application as MRI contrast agents. Regarding their synthesis, different approaches have been explored including the co-reduction of Fe and Pt precursors in an aqueous media, the thermal decomposition in a conventional high-boiling solvent such as benzyl ether, and in low-melting organic salts (ionic liquids). The data revealed an inhomogeneous composition distribution of Fe and Pt between particles obtained in aqueous media, due to the iron salts hydrolysis, and a mismatch in the co-reduction kinetic of the two metal precursors. While the iron content in the NPs could be increased by using more hydrolytically stable iron precursors or stronger reducing agents, there are remaining limiting parameters which prevent further Fe content increase in NPs. In contrast, by excluding the water from the reaction system and using a Fe²⁻ iron precursor, homogenous 1:1 Fe to Pt ratio NPs can be obtained through a modified thermal decomposition pathway in benzyl ether. Based on the study of synthesis in this conventional chemical, the potential of ionic liquids (ILs) to be used as novel solvents for FePt NPs synthesis was further explored. It was then demonstrated that ionic liquids (ILs) can not only be used as a solvent for synthesis of FePt NPs, but also can provide an exciting alternative pathway to direct synthesis fct-FePt NPs. In the context of the bioapplication of FePt NPs, a family of FePt NPs was specifically designed to enhance their MRI contrast agents properties. In contrast with previous reports, this thesis demonstrates that FePt NPs can be made non-toxic and provides the first data on their cellular uptake mechanisms. A six times increase in the FePt based T₂ contrast properties compared to clinical iron oxide NPs is reported. The relationship between the MRI contrast properties and the NPs architecture is explored and rationalised as the basis for the design of NPs as enhanced MRI contrast agents. Finally, the first observations of cellular and in vivo MR imaging with FePt NPs is also reported. This study opens the way for several applications of FePt NPs such as regenerative medicine and stem cell therapy, thus providing a bio-platform to develop novel diagnostic and therapeutic agents.

615.84

Desenvolvimento, síntese e caracterização de nanopartículas magnéticas hidrofílicas e lipofílicas para aplicação em nanotecnologia do petróleo / Development, synthesis and characterization of hydrophilic and lipophilic magnetic nanoparticles applied to oil nanotechnology

Silva, Delmarcio Gomes da

22 April 2014

A tese de doutorado tem como foco o desenvolvimento de nanopartículas superparamagnéticas (Fe3O4 - magnetita) hidrofílicas e lipofílicas aplicadas à nanotecnologia do petróleo. Inicialmente, os objetivos foram voltados para a elaboração e transferência de tecnologia envolvendo uma rota de síntese de nanopartículas lipofílicas, em escala semi-industrial. Para isso, foram realizados ensaios piloto num reator com capacidade de uma tonelada, visando a produção de nanopartículas magnéticas recobertas com ácido esteárico. Mais tarde, esse trabalho foi otimizado, permitindo sua execução em laboratório, prosseguindo depois, com um escopo mais amplo, incluindo a síntese de nanopartículas recobertas com polímero hidrofílico. Nesse sentido, foram desenvolvidas duas rotas inéditas para produção desses nanomateriais. Em um segundo estágio, as investigações foram voltadas para a utilização das nanopartículas sintetizadas, em estudos de avaliação das condições dos reservatórios de petróleo. Para isso, a técnica de ressonância magnética nuclear (RMN) foi explorada, monitorando o efeito da concentração dessas nanopartículas superparamagnéticas sobre o tempo de relaxação dos prótons, e o consequente efeito de contraste nas imagens em função da magnetização. A aplicação desse tipo de ferramenta (RMN) já vem sendo feita (sem nanopartículas magnéticas) pelas empresas prestadoras de serviço ao setor de petróleo e gás, na avaliação e perfilagem de reservatórios. Isso motivou o estudo dos nanomateriais magnéticos como sondas para melhorar o mapeamento de fluidos em meio poroso. Eles seriam aplicados como aditivos em fluidos de injeção em reservatórios, tanto para imageamento, como para a obtenção de parâmetros petrofísicos. Por fim, devido à presença de grupos carboxílicos na superfície das nanopartículas hidrofílicas, foram investigadas suas interações com microcristais de carbonato de cálcio, pensando no modelo de reservatório petrolífero do tipo carbonáceo. Explorando técnicas de microscopia eletrônica de varredura (MEV) e de microscopia Raman confocal, a presença das nanopartículas magnéticas sobre a superfície da matriz mineral foi constatada, confirmando sua interação efetiva com o CaCO3. Abordando a síntese, caracterização e aplicações das nanopartículas superparamagnéticas, esta tese proporciona uma base para estudos de aplicação de nanomateriais, assunto cada vez mais relevante, diante dos inúmeros problemas e desafios enfrentados pelo setor de petróleo e gás. / The Ph.D thesis is focused on the preparation of hydrophilic and lipophilic superparamagnetic nanoparticles (Fe3O4 - magnetite) for application in oil nanotechnology. The initial efforts have been directed to the upscaling of a laboratory route of synthesis of lipophilic nanoparticles, aiming technology transfer to the industry. Accordingly, a pilot process, involving a one ton reactor, has been tested for the production of magnetic nanoparticles coated with stearic acid. After this, the research has evolved, allowing the production in the laboratory scale, and continued, pursuing the development of nanoparticles coated with a hydrophilic polymer. Two new routes for the production of these nanomaterials have been developed. In a second step, the investigations were directed to the application of these nanoparticles to the evaluation of oil reservoirs, by monitoring the proton relaxation times, using nuclear magnetic resonance (NMR), and the consequent contrasting effects observed on the images, as a function of the magnetization and the concentration of these particles. Currently, NMR tools are being employed in the oil and gas sector for the evaluation and profiling of reservoirs. This fact has stimulated the use of such nanomaterials for improving the mapping of the fluids in porous media. Introduced as additives for fluid injection into reservoirs, they can enhance the imaging and also perform the rating of petrophysical parameters. Finally, the presence of carboxylic groups on the surface of the hydrophilic nanoparticles has been explored in studies of interaction with calcium carbonate, simulating a carbonaceous type reservoir. Based on electron microscopy (SEM) and confocal Raman microscopy, the presence of magnetic nanoparticles on the surface of the mineral matrix has confirmed the interaction of these particles with the CaCO3 surface. By developing the synthesis, characterization and application of superparamagnetic nanoparticles, this work provides a useful starting point for further research on the use nanoparticles, for solving problems and challenges in the oil and gas sector.

Magnetic nanoparticles

Nanoparticulas magnéticas

Nanotechnology

Nanotecnologia do petróleo

Nuclear magnetic resonance (NMR)

Petroleum

Ressonância magnética nuclear (RMN)

Nanocomposites à base de particules magnétiques : synthèse et contribution de la dispersion des charges et de la conformation des chaines sur les propriétés de renforcement / Magnetic nanoparticles based nanocomposites : synthesis, contribution of the fillers dispersion and the chains conformation on the reinforcement properties

Robbes, Anne-sophie

14 October 2011

Les propriétés mécaniques de films polymériques peuvent être considérablement améliorées par l'inclusion de nanoparticules au sein de la matrice du fait de deux effets majeurs : (i) la structure locale de la dispersion des charges et (ii) la modification potentielle de la dynamique et de la conformation des chaînes à l'interface charge/polymère. Néanmoins, les mécanismes précis qui permettent de relier ces contributions à l’échelle nanométrique aux propriétés macroscopiques des matériaux, et en particulier aux propriétés mécaniques, sont actuellement mal décrits. Dans ce contexte, nous avons synthétisé des nanocomposites modèles à base de nanoparticules magnétiques de maghémite γ-Fe2O3 (nues ou greffées d'une couronne de polystyrène (PS) par polymérisation radicalaire contrôlée) dispersées dans une matrice de PS, que nous avons caractérisé en couplant la diffusion de rayonnement (Rayons X et neutrons) et la microscopie électronique à transmission. En jouant sur différents paramètres tels que la taille des particules, la concentration, ou le rapport de taille entre les chaînes greffées et celles de la matrice pour les charges greffées, nous avons obtenu des nanocomposites présentant un éventail de dispersions de charges variées, contrôlées, parfaitement reproductibles, allant de particules individuelles ou d’agrégats ramifiés jusqu’à la formation d’un réseau de charges connecté. En appliquant un champ magnétique externe durant la synthèse des nanocomposites, nous sommes parvenus à aligner les différentes structures le long de la direction du champ et ainsi former des matériaux présentant des propriétés remarquables de renforcement anisotropes. La conformation des chaînes au sein des nanocomposites, déterminée expérimentalement grâce aux propriétés spécifiques de contraste neutronique du système, n'est pas affectée par la présence des charges, quels que soient le degré de confinement des chaînes, l’orientation, la dispersion ou l'état de surface des charges. L’alignement des charges sous champ magnétique a permis de décrire précisément l’évolution du module de renforcement des matériaux avec la réorganisation structurale locale des charges et des chaînes sous étirement, et de finalement mettre en évidence le rôle majeur joué par la réorganisation des charges sous déformation dans les mécanismes de renforcement. / The mechanical properties of polymeric nanocomposite films can be considerably enhanced by the inclusion of inorganic nanoparticles due to two main effects: (i) the local structure of fillers dispersion and (ii) the potential modification of the chains conformation and dynamics in the vicinity of the filler/polymer interface. However, the precise mechanisms which permit to correlate these contributions at nanometric scale to the macroscopic mechanical properties of the materials are actually poorly described. In such a context, we have synthesized model nanocomposites based on magnetic nanoparticles of maghemite γ-Fe2O3 (naked or grafted with a polystyrene (PS) corona by radical controlled polymerization) dispersed in a PS matrix, that we have characterized by combining small angle scattering (X-Ray and neutron) and transmission electronic microscopy. By playing on different parameters such as the particle size, the concentration, or the size ratio between the grafted chains and the ones of the matrix in the case of the grafted fillers, we have obtained nanocomposite films a large panel of controlled and reproducible controlled filler structures, going from individual nanoparticles or fractal aggregates up to the formation of a connected network of fillers. By applying an external magnetic field during the film processing, we succeeded in aligning the different structures along the direction of the field and we obtained materials with remarkable anisotropic reinforcement properties. The conformation of the chains of the matrix, experimentally determined thanks to the specific properties of neutron contrast of the system, is not affected by the presence of the fillers, whatever their confinement, the dispersion the fillers or their chemical state surface. The alignment of the fillers along the magnetic field has allowed us to describe precisely the evolution of the reinforcement modulus of the materials with the structural reorganization of the fillers and the chains at the local scale under stretching, and thus to highlight the key role played by the fillers reorganization under stretching on the nanocomposite reinforcement mechanisms.

Nanocomposites

Particules magnétiques

Dispersion des charges

Conformation des chaînes

Diffusion aux petits angles

Propriétés mécaniques

Grafting from

Nanocomposites

Magnetic nanoparticles

Fillers dispersion

Chain conformation

Small angles scattering techniques

Mechanical properties

Radical controlled polymerization (NMP)

Grafting from

Estudo da imobiliza??o de proteases para a s?ntese de oligolisinas

Fagundes, Fabio Pereira

16 September 2011

Made available in DSpace on 2014-12-17T15:42:15Z (GMT). No. of bitstreams: 1 FabioPF_TESE.pdf: 3376603 bytes, checksum: 15dfaa7fe12ca918fd7e1b98c4378dd9 (MD5) Previous issue date: 2011-09-16 / Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico / Enzymatic synthesis of peptides using proteases has attracted a great deal of attention in recent years. One key challenge in peptide synthesis is to find supports for protease immobilization capable of working in aqueous medium at high performance, producing watersoluble oligopeptides. At present, few reports have been described using this strategy. Therefore, the aim of this thesis was to immobilize proteases applying different methods (Immobilization by covalent bound, entrapment onto polymeric gels of PVA and immobilization on glycidil metacrylate magnetic nanoparticles) in order to produce water-soluble oligopeptides derived from lysine. Three different proteases were used: trypsin, α-chymotrypsin and bromelain. According to immobilization strategies associated to the type of protease employed, trypsin-resin systems showed the best performance in terms of hydrolytic activity and oligopeptides synthesis. Hydrolytic activities of the free and immobilized enzymes were determined spectrophotometrically based on the absorbance change at 660 nm at 25 ?C (Casein method). Calculations of oligolysine yield and average degree of polymerization (DPavg) were monitored by 1H-NMR analysis. Trypsin was covalently immobilized onto four different resins (Amberzyme, Eupergit C, Eupergit CM and Grace 192). Maximum yield of bound protein was 92 mg/g, 82 mg/g and 60 mg/g support for each resin respectively. The effectiveness of these systems (Trypsin-resins) was evaluated by hydrolysis of casein and synthesis of water-soluble oligolysine. Most systems were capable of catalyzing oligopeptide synthesis in aqueous medium, albeit at different efficiencies, namely: 40, 37 and 35% for Amberzyme, Eupergit C and Eupergit CM, respectively, in comparison with free enzyme. These systems produced oligomers in only 1 hour with DPavg higher than free enzyme. Among these systems, the Eupergit C-Trypsin system showed greater efficiency than others in terms of hydrolytic activity and thermal stability. However, this did not occur for oligolysine synthesis. Trypsin-Amberzyme proved to be more successful in oligopeptide synthesis, and exhibited excellent reusability, since it retained 90% of its initial hydrolytic and synthetic activity after 7 reuses. Trypsin hydrophobic interactions with Amberzyme support are responsible for protecting against strong enzyme conformational changes in the medium. In addition, the high concentration of oxirane groups on the surface promoted multi-covalent linking and, consequently, prevented the immobilized enzyme from leaching. The aforementioned results suggest that immobilized Trypsin on the supports evaluated can be efficiently used for oligopeptides synthesis in aqueous media / S?ntese enzim?tica de pept?deos usando proteases tem atra?do uma enorme aten??o nos ?ltimos anos. Um desafio chave na s?ntese de pept?deos ? encontrar suportes para imobiliza??o de proteases capazes de apresentar um alto desempenho em meio aquoso, produzindo oligopept?deos sol?veis em ?gua, j? que at? o presente momento, pouco tem sido descrito usando essa estrat?gia. Dessa forma, o objetivo dessa tese foi imobilizar proteases usando diferentes m?todos (imobiliza??o por liga??o covalente, aprisionamento em g?is polim?ricos de PVA e imobiliza??o em nanopart?culas magn?ticas de Glicidil) para a produ??o de oligopept?deos derivados da lisina. Tr?s proteases foram utilizadas: tripsina, α-quimotripsina e bromela?na. De acordo com as estrat?gias de imobiliza??o associadas ao tipo de protease empregada, foi provado que os sistemas tripsina-resinas mostraram os melhores desempenhos em termos de atividade hidrol?tica e s?ntese de oligopept?deos. A atividade hidrol?tica das enzimas livres e imobilizadas foi determinada por espectrofotometria com base na mudan?a de absorb?ncia em 660 nm ? temperatura de 25 ?C (Casein method). O rendimento de oligolisina e o c?lculo do grau de polimeriza??o m?dio foram monitorados por RMN H. A protease tripsina foi covalentemente imobilizada em quatro diferentes resinas (Amberzyme, Eupergit C, Eupergit CM and Grace 192). O m?ximo rendimento de prote?na imobilizada foi 92, 82, 60, e 71 mg/g de suporte para cada resina, respectivamente. A efici?ncia desses sistemas (Tripsina-resinas) foi avaliada pela hidr?lise do substrato case?na e a s?ntese de oligolisina em meio aquoso. A maioria dos sistemas foram capazes de catalisar a s?ntese de oligopept?deos, entretanto com diferentes efici?ncias, tais como: 40, 37 e 35% para os suportes Amberzyme, Eupergit C e Eupergit CM, respectivamente, em compara??o com a enzima livre. Esses sistemas produziram olig?meros em somente 1 hora com grau de polimeriza??o m?dio mais alto que a enzima livre. Dentre esses sistemas, Eupergit CTripsina mostrou ser mais eficiente que os outros sistemas em termos de atividade hidrol?tica e estabilidade t?rmica, ao passo que n?o exibiu a mesma efici?ncia como era esperado para a s?ntese de oligolisina. Tripsina-amberzyme provou ser mais eficiente para a s?ntese de oligopept?deos, al?m de exibir um excelente reuso, mantendo 90% de sua atividade hidrol?tica e sint?tica ap?s sete reusos. As intera??es hidrof?bicas da tripsina com o suporte Amberzyme s?o respons?veis por proteger a enzima contra as fortes mudan?as conformacionais no meio reacional. Al?m disso, a alta concentra??o de grupos oxiranos na superf?cie da resina promoveu liga??es covalentes multipontuais e, consequentemente, preveniu a enzima imobilizada do processo de desor??o (Leaching process). Os resultados acima mencionados sugerem que a tripsina imobilizada nesses suportes pode ser eficientemente usada para a s?ntese de oligopept?deos em meio aquoso

S?ntese enzim?tica

Imobiliza??o por liga??o covalente

Aprisionamento em g?is de PVA

Nanopart?culas magn?ticas de glicidila

Proteases

Oligopept?deos

Enzymatic synthesis

Covalent immobilization

PVA gels entrapment

Glycidil magnetic nanoparticles

Proteases

Oligopeptides

Agrégats multicellulaires magnétiques : mécanique des tissus et biodégradation des nanomatériaux / Magnetic multicellular aggregates : tissues mechanics and nanomaterials biodegradation

Mazuel, François

22 September 2016

Les nanoparticules d’oxyde de fer ont récemment été envisagées comme outils pour l’ingénierie tissulaire. Elles sont internalisées par les cellules qui deviennent alors magnétiques. Des forces magnétiques peuvent ainsi être appliquées à distance sur ces cellules pour contrôler leur organisation spatiale et temporelle, et former un tissu. Ces applications posent la question du devenir des nanoparticules, qui conditionne in fine leur utilisation clinique. Ce travail s’inscrit dans ce cadre et comporte deux axes.La première partie traite de l’étude des propriétés mécaniques et rhéologiques de tissus biologiques modèles, les agrégats multicellulaires. Une combinaison de méthodes magnétiques est proposée pour fabriquer et stimuler des tissus magnétiques de taille et de forme contrôlées. Ces agrégats magnétiques sont soumis à distance à des contraintes magnétiques d’écrasement. L’étude de leur déformation permet d’explorer des caractéristiques statiques et dynamiques rarement étudiées à l’échelle tissulaire (tension de surface, loi puissance, non linéarité). La deuxième partie se concentre sur l'évolution à moyen terme des nanoparticules dans leur environnement tissulaire, au cœur des agrégats. En combinant ce tissu modèle avec des méthodes de quantification magnétique, nous avons pu mettre en évidence une dégradation massive d’origine endosomale, sans pour autant impacter de manière importante l’homéostasie du fer. De plus, le modèle tissulaire mis en place permet d’étudier la biodégradation intracellulaire de n’importe quel type de nanoparticules. Nous l'avons testé avec des nano-architectures plus complexes: nanocubes, nanodimers, ou nanoparticules magnéto-plasmoniques / Iron oxide nanoparticles are promising candidates for applications in nanomedecine (contrast agents, vectors). They were also recently considered as a powerful tool for tissue engineering. Cells, magnetized through nanoparticules internalization, can be organized in space and time thanks to remote magnetic forces. For all those applications the nanoparticles fate inside the cells remains a key issue concerning the final clinical use. The first part of this work focuses on the study of the mechanical and rheological properties of biological tissue models, the multicellular aggregates. An original magnetic molding method and two different experimental setups were developed to produce aggregates with controlled shapes and sizes, to measure their surface tension and to evidence their power law and non linear behavior.In the second part, we investigate the medium term fate of iron oxide nanoparticles in stem cells forming a spheroid as a model tissue. We reveal a massive endosomal degradation. The set of methods and spheroid model we propose allow a comprehensive and quantitative follow up of the biodegradation of any nanomaterials. This was illustrated by investigating the degradation of nanomaterials with more complex nano-architectures (nanocubes, nanodimers) and assessing the efficiency of a protection strategy to modulate the biodegradation

Agrégats multicellulaires

Tension de surface des tissus

Rhéologie des tissus

Loi puissance

Homéostasie du fer

Iron oxide magnetic nanoparticles

Multicellular aggregate

Tissue surface tension

Tissue rheology

Power law

Iron homeostasis

Developpement de nouveaux catalyseurs au palladium supporté sur polymères ou nanoparticules de cobalt : application à la formation de liaisons carbone-carbone / Development of new catalysts containing palladium supported on polymer or on cobalt nanoparticles : application to carbone-carbone bond forming reactions

Diebold, Carine

12 October 2012

Les réactions pallado-catalysées permettant la formation de liaisons carbone-carbone trouvent de nombreuses applications en synthèse organique et constituent l’étape clé de la synthèse d’un grand nombre de molécules. La première partie de cette thèse décrit la préparation et l’étude de catalyseurs hétérogènes et réutilisables comportant du palladium supporté sur un polymère portant des groupements phosphinés, polymère dérivé soit d'une résine de Merrifield soit d’une résine Rasta. De très bons résultats ont été obtenus pour leur utilisation dans les couplages croisés de Hiyama, Heck et Suzuki et dans chaque cas la possibilité de réutilisation jusqu’à 4 fois du catalyseur a été vérifiée. Notre travail constitue une des premières utilisations d’un catalyseur réutilisable dans le couplage de Hiyama. Nous avons aussi mis au point des conditions permettant d’effectuer le couplage de Heck en présence d’une quantité infime de palladium. Notre étude sur les résines Rasta constitue la première application de ces supports en pallado-catalyse. La deuxième partie de la thèse décrit l’étude de la préparation de catalyseurs où le palladium serait supporté sur des nanoparticules superparamagnétiques et qui pourraient donc être récupérés de tout milieu réactionnel grâce à un champ magnétique externe. Des nanoparticules de cobalt ont été préparées puis recouvertes de pyrocarbone par dépôt chimique en phase vapeur. Des groupements organiques ont été fixés sur la coque de carbone, ce qui permet l’introduction de ligands phosphinés. La structure de ces particules a été étudiée par microscopie électronique en transmission et leur préparation optimisée en fonction des résultats structuraux. / Palladium-catalyzed reactions forming carbon-carbon bonds have found widespread applications in organic synthesis as they represent the key step of many important syntheses in various domains. The first part of this work describes the preparation and study of heterogeneous, reusable, catalysts containing palladium supported on a polymer bearing phosphino groups derived from either a Merrifield resin or a Rasta resin. Very good results have been obtained for the use of these catalysts in Hiyama, Heck and Suzuki cross-couplings and, in each case, the possibility of reuse of the catalyst at least 4 times has been verified. Our work constitutes one of the first use of a reusable catalyst in a Hiyama coupling. We have also found experimental conditions allowing to run the Heck coupling in the presence of only a minimal amount of palladium. Our work constitutes the first use of Rasta resins to prepare heterogeneous palladium catalysts. The second part of the thesis describes the study of the preparation of catalysts where palladium would be supported on superparamagnetic nanoparticles and which could therefore be recovered from any reaction medium by using a magnetic field. Cobalt nanoparticles were prepared and then covered by pyrocarbon by Chemical Vapor Deposition. Organic groups, allowing the subsequent introduction of phosphino ligands, were then grafted on the carbon shells. The structure of the particles was determined by Transmission Electron Microscopy and their preparation optimized according to these structural results.

Synthèse organique

Catalyse hétérogène

Catalyseur supporté

Palladium

Nanoparticules magnétiques

Dépôt chimique en phase vapeur

Couplage Suzuki

Réaction de Heck

Organic synthesis

Heterogeneous catalysis

Supported catalyst

Magnetic nanoparticles

Chemical vapor deposition

Suzuki coupling

Heck reaction

Elaboration de Nanoparticules hybrides et multiphasées innovantes pour la délivrance de principe actif. / Development of novel hybrid and multi layered nanoparticles for the delivery of active ingredients

Lemaire, Gaelle

20 December 2017

Les limites des nanovecteurs commerciaux ou actuellement en développement ont motivé l’élaboration de nouvelles nanoparticules mésoporeuses de silice (MSNP), hybrides et multiphasées, pour le contrôle de la délivrance d’actifs à application théranostique. Ainsi, de nouvelles MSNP ont été conçues pour la pénétration intracellulaire (diamètre entre 30 et 60 nm, taille des pores de 2,8 nm). Afin de les rendre hémocompatibles et de contrôler la cinétique de délivrance de principes actifs encapsulés, ces MSNP ont été enrobées d’une bicouche lipidique (MSNP+@SLB-). La composition lipidique s’inspire des membranes asymétriques des globules rouges ciblés par la présente étude.La technologie MSNP+@SLB- ayant montré des limites avec une cinétique de libération trop élevée de la calcéine et trop lente de la rhodamine B, deux améliorations majeures ont été apportées :1- Le recouvrement des SLB par un nanogel d’alginate, permettant un excellent contrôle de la libération d’actifs.2- L’insertion de nanoparticules magnétiques dans le coeur des MSNP, déclenchant la libération de l’actif par hyperthermie.Ces nouvelles architectures de nanovecteurs permettent de moduler les cinétiques de délivrance d’actifs, renforçant et élargissant ainsi le champ d’applications des vecteurs silicés dans les domaines biomédical ( Voie orale et intraveineuse) et dermato-cosmétique (Voie topique). / The limitations of commercial nanovectors or currently under development have motivated the development of new hybrid and core shell mesoporous silica nanoparticles (MSNP) for the control of molecular delivery.Therefore, new MSNP were designed for intracellular penetration (diameter between 30 and 60 nm, pore size of 2.8 nm). In order to make them hemocompatible and to control the kinetics of delivery of encapsulated active ingredients, these MSNP were coated with a lipid bilayer (MSNP+@SLB-). The lipid composition is inspired by the asymmetric membranes of the red blood cells.Since the MSNP+@SLB- technology has shown some limitations associated to the release of payloads which can be too fast (in the case of calcein) or to slow (case of rhodamine B), two major improvements have been made:1- The coating of SLB by an alginate nanogel, allowing an excellent control of the release of active molecules.2- Insertion of magnetic nanoparticles in the MSNP core, triggering the release of the active ingredient by hyperthermia.These new nanovector architectures enable the fine tuning of active ingredient delivery kinetics, reinforcing and expanding the applications of silicated vectors in the fields of biomedicine (oral and intravenous) and dermato-cosmetics (topical).

Nanoparticules mésoporeuses de silice

Bicouche lipidique

Nanoparticules magnétiques

Hémocompatibilité

Biocompatibilité

Recouvrement polymère

Nanogel

Mesoporous silica nanoparticles

Drug delivery system

Lipid bilayer

Magnetic nanoparticles

Hemocompatibility

Biocompatibility

Polymer coating

Nanogel

615.6

Mossbauer, Magnetization And Electrical Transport Studies On Iron Nanoparticles Embedded In The Carbon Matrix

Sajitha, E P

03 1900

This thesis deals with the studies of magnetization and electrical transport properties of iron nanoparticles embedded in the carbon matrix. The synthesis and characteristics of the nanoparticle systems studied, are also presented. Carbon-iron (C-Fe) based systems are of growing interest due to their improved magnetic properties as well as in their potential application as sensors, catalysts, and in various other applications. In particular, nanocomposites of iron carbide, such as the cementite phase Fe3C, are further suited to diverse technological exploitations due to their enhanced mechanical properties and importance in ferrous metallurgy. The recent interest in magnetic nanostructures lies in the emergence of novel magnetic and transport properties with the reduction of size. As the dimension approaches the nanometer length scale, interesting size-dependent properties like enhanced coercivity, enhanced magnetic moment, super paramagnetism etc. are seen. Thermal assisted chemical vapour deposition (CVD) is used to decompose and chemically react the introduced precursors, maleic anhydride and ferrocene. This method provides relative size control over the individual particles by varying C/Fe concentration in precursors and the pyrolysis temperature during the co-deposition process. Ferrocene has been used actively for the production of nanoparticle composites and in the production of nanostructured carbon. The temperature of preparation, reaction rate, and the time duration of annealing directly effects the nanoparticle compositions. The catalytic effect of transitional elements are well documented in literature. This thesis is an effort to understand the growth of ferromagnetic nanocrystallites in carbon matrix, which undergo partial graphitization due to the catalytic effect of transitional elements. The effect of transitional metal on the degree of graphitization of the carbon matrix, morphology of the nanoparticle and the carbon matrix are studied. The phase of the ferromagnetic iron nanoparticles and the structural investigation forms part of the study. Here X-Ray diffraction (XRD) is employed to study the presence of different phases of iron in the partially graphitized carbon matrix. The matrix morphology and the particle size distribution were studied using Transmission Electron Microscopy (TEM) and High-Resolution TEM (HRTEM). The ferromagnetic states of the iron nanoparticles are investigated using Mossbauer spectroscopy. The results from these studies, are used to correlated the macroscopic properties to the microscopic studies. The enhanced magnetization, coercivity and the temperature dependence of the magnetization value is understood within the frame work of ferromagnetic Bloch law and surrounding carbon spins. The logarithmic temperature dependence of conductivity of the nanoparticle composites is analyzed in the framework of interference models as well as the many-body Kondo interaction effect. This thesis contains seven chapters: In chapter 1, a brief introduction to mesoscopic physics and the size-dependent phenomenon are given. Special attention is paid to magnetic nanoparticle and its composites, and the various finite-size effects exhibited by them are discussed in detail. The relevance of carbon matrix and its importance on the growth of iron nanoparticles with high thermal stability is also discussed. The ballistic and diffusive transport phenomena observed in low-dimensional systems are briefly discussed. The interplay of localization and various interaction effects at nanoscale are examined. In disordered metals the low temperature conductivity is dominated by the interference effects. A brief discussion is made on the conductivity in disorder systems, with the presence of magnetic impurities and how the classic many-body Kondo problem, is effected by various interactions. Chapter 2, mainly deals with the experimental techniques employed in the thesis. The thermal-assisted chemical vapour deposition setup used to decompose and chemically react the introduced organometallic precursors, for the preparation of C:Fe composites are discussed and its advantage over other preparation methods are emphasized. The method is optimized to provide relative size control over the nanoparticles composites and the phase compositions by varying C/Fe concentration in precursors and the pyrolysis temperature, during the co-deposition process. The various structural characterization tools used in the present study are summed up concisely in this chapter. The SQUID magnetometer system; its working principle and the various protocol used for the low temperature magnetization measurements are elaborated. Further, details regarding superconducting magnetic cryostat, utilized for the low temperature conductivity and magneto resistance measurements, are discussed. Films of C:Fe composites are grown on substrates to study the effect of disorder and sample size on the conductivity behaviour of the composites at low temperature. Chapter 3, presents the outcome of the structural studies undertaken on the C:Fe composites using XRD, TEM, and HRTEM. X-ray diffraction measurements performed on the powder composites reveal that, in addition to the presence of sharp diffraction peak from nanographite, peaks corresponding to the different phases of Fe are also seen. The effect of preparation temperature on the matrix morphology is revealed from the estimation of degree of graphitization. Iron carbide is the predominant phase in all the prepared composites. For low concentration of iron, iron carbide alone is present but as the percentage of iron in the samples increased other phases of iron are also seen. The microscopic studies on the prepared compositions revealed the presence of nanosized iron particles well embedded in the partially graphitized matrix. Here again, with the increase in iron percentage, agglomeration of ferromagnetic nanoparticles are seen. The kinetics of the particle growth and the filamentous nature of the carbon matrix are also discussed. Mossbauer investigation on C:Fe composites are presented in chapter 4. The measurements revealed the iron atom occupation in the crystal lattice. In the lower Fe concentration samples, the room temperature Mossbauer spectrum revealed the presence of sextet from Fe3C (cementite) phase. As the percentage of iron increased, sextet from α-Fe, Fe3O4 are also seen in some of the prepared compositions. Effect of carbon atoms on the structure and magnetic properties of the nanoparticle species are obvious from the isomer shift measurements. Chapter 5 comprises of the various magnetic properties and interactions present in small particle system such as magnetic anisotropy, coercivity, enhanced magnetization, inter-and intra-particle interactions etc. Magnetization measurements carried out in SQUID magnetometer on the C:Fe composites and carbon flakes (prepared from organic precursor, maleic anhydride alone) are presented. The enhanced magnetic properties of the nanoparticle assembly is discussed in detail. The hysteresis loops trace, with a finite coercivity at room temperature, indicates the ferromagnetic nature of the samples. At room temperature the magnetization value saturates at high magnetic field, indicating negligible effect from super paramagnetic particles on the hysteresis loop. The squareness ratio, saturation magnetization, coercivity and remanence magnetization values are analyzed in detail. The temperature dependence of magnetization shows a combination of Bloch law and Curie-Weiss behaviour, consistent with the picture of ferromagnetic clusters embedded in a carbon matrix. The Bloch’s constant is found to be larger by an order of magnitude compared to the bulk value, implying stronger dependence of magnetization with temperature. Effort to understand the enhanced magnetic moment in the light of magnetism in carbon was taken up. The proximity effect of ferromagnetic metal on the carbon and the hydrogen bonding with the dangling bonds, both studied in detail in literature, in connection with the induced magnetic moments in carbon, are invoked. In chapter 6, the different conductivity regimes are identified, to study the conduction mechanisms in composites and films. For the transport measurements pelletized samples are used for the resistivity and magneto resistance measurements. The conductivity data are analyzed based on the interplay of localization and Kondo effect in the ferromagnetic disordered system. In order to understand the effect of disorder and thickness on the Kondo problem, transport measurements are carried on thin films of C:Fe composites grown on quartz and alumina substrate. Disorder induced metal-insulator transition is observed in the prepared samples. The zero-field conductivity and magneto resistance data is fitted to variable range hopping (VRH) in strong localization regime. Chapter 7 summarizes the thesis and presents some perspectives for the future.

Iron Nanoparticles

Mossbauer Effect

Iron - Magnetic Properties

Iron - Electrical Transport Properties

Carbon-Iron Matrix

Magnetic Nanoparticles

Ferromagnetic Iron Nanoparticles

Nanoparticle Composites

C:Fe Composites

Carbon Matrix

Ferromagnetic Nanoparticles

Iron Carbide Nanoparticle

Materials Science