Global ETD Search

71	Contribution to nano or micro crystallization induction in silica-based glass by femtosecond laser irradiation / Contribution à l’étude de l’induction de nano ou micro cristallisations dans des verres à base de silice à l’aide du laser femtoseconde Fan, Chaxing 14 September 2012 (has links) Le traitement par laser femtoseconde dans des matériaux transparents est prometteur du fait de la possibilité de contrôler le dépôt d'énergie dans le temps et dans l'espace. Il ouvre ainsi des possibilités fantastiques pour la fabrication de nouveaux matériaux composites multifonctionnels en manipulant la taille, la forme et l'orientation des cristaux non linéaires dans les verres. Cette thèse contribue principalement à la maîtrise de la nano ou micro cristallisation dans des verres à base de silice pour le développement de nouveaux matériaux électro-optiques multi-fonctionnels par l’irradiation au laser femtoseconde. On démontre la faisabilité du traitement des matériaux par le laser femtoseconde pour remodeler les propriétés optiques linéaires et non linéaires ou de la fabrication de micro / nano agrégats, ainsi que les formes et les orientations (en particulier agrégats asymétriques), les tailles et les distributions (à l'échelle sub-micrométrique). Le mémoire débute par un chapitre introductif sur l’investigation de l’écriture par laser impulsionnel ultra-bref dans la silice pure, ainsi que dans le verre à base de silice, afin de bien maîtriser l’inscription avec ce nouveau type de laser. Nous discutons les effets des paramètres du laser sur l’écriture, telle que la vitesse de déplacement du faisceau et la polarisation du laser, sur les propriétés optiques et les structures atomiques, par exemple, la biréfringence, les champs de contraintes et le changement d’arrangement atomique. Il est mis en évidence des effets orientationnels et directionnels spécifiques de l’interaction de ce type de laser avec les verres. Le mécanisme associé fait probablement intervenir l'inclinaison du front de la phase du champ de l’impulsion par rapport au déplacement du faisceau dans le solide. La précipitation des cristaux LiNbO3 orientés dans le verre avec l’irradiation laser femtoseconde est réalisée dans le cas d’une fréquence de répétition élevée (typ. 300 kHz) permettant l’accumulation de chaleur. Des cristaux orientés avec leur axe polaire aligné dans la direction d’inscription du laser ont été fabriqués en manipulant le gradient de température par le réglage des paramètres du laser. L’imagerie microscopique de génération de seconde harmonique (GSH) montre le caractère cristallin asymétrique et fournit des informations sur les orientations dominantes favorisées lors des processus de cristallisation. Les résultats de diffraction d’électrons rétrodiffusés (EBSD) fournissent des informations détaillées sur l’orientation des cristaux et révèlent la structure des lignes écrites notamment tailles et dispersion des orientations. En outre, des débuts de modélisation ont été réalisés pour se diriger vers une maîtrise de l’écriture de structures linéaires cristallines. Une autre section du mémoire rapporte l’étude de reformation par l’irradiation avec le laser femtoseconde de nanoparticules d'or quasi-sphériques ou quasi-tige dans le verre à base de silice. Les nanoparticules d'or de la taille de 3-4 nm ont été précipitées par traitement thermique. Après l’irradiation par le laser, des mesures optiques d'absorption, de biréfringence et de dichroïsme ont été effectuées pour étudier la modification de la forme de nanoparticules d'or dans le verre. Les simulations théoriques ont été menées pour interpréter les résultats expérimentaux basés sur la théorie de Gans et le modèle de Drude avec les constantes diélectriques connus de l'or. Enfin, des stratégies de conception efficaces sont aussi suggérées pour le futur pour des applications possibles utilisant la précipitation, la forme et l'orientation des micro/nanoparticules en 3D. / Femtosecond laser processing in transparent materials is promising owing to the accessible control of energy deposition in time and in space. In this regime, it opens fantastic opportunities to manufacture novel multifunctional composite materials by manipulating the size, shape and orientation of nonlinear crystals with intrinsic symmetry embedded in glasses. This dissertation mainly contributes to the control of nano or micro crystallization inside silica-based glasses for the development of novel multifunctional electro-optical materials by femtosecond laser irradiation. We demonstrate the feasibilities of femtosecond laser materials processing for re-shaping linear and non-linear optical properties in silica-based glass by inducing or fabricating different micro/nanoclusters as well as their shapes and orientation (especially asymmetric clusters), sizes, and distributions (at the sub-micrometer scale). In this thesis, it firstly covers a chapter for the investigation on ultrafast asymmetric orientational writing in pure silica as well as in silica-based glass in order to well master the laser writing. We discuss the effects of the laser parameters on asymmetric writing such as writing speed and the laser polarization by the femtosecond-laser generated optical properties and structures, e.g., birefringence, phase change and surface topography of the cross section of laser tracks. The mechanism of orientational dependent writing is likely due to the oblique pulse front tilt affected by the polarization orientation plane leading to different anisotropic photosensitivity. 3D photo-precipitation of oriented LiNbO3-like crystals in glass with femtosecond laser irradiation is also achieved at high repetition rate (typ. 300 kHz). Oriented crystals with their polar axis mostly aligned with the laser scanning direction have been fabricated by manipulation of the temperature gradient in adjusting the laser parameters. Second harmonic generation (SHG) microscopy demonstrates optical activity of crystalline features and provides some orientation information suggestive of certain dominant or favored orientations. Electron back-scattering diffraction (EBSD) results provide more detailed local crystal orientation information and illustrate interesting features of the structure of the lines, with regions of distinctly different grain sizes and orientations. Furthermore, modeling the temperature gradient was proposed for better understanding the formation mechanism of the orientation of femtosecond laser-induced crystallization when the laser is moved (not only in the static mode). Quasi-spherical or quasi-rod gold nanoparticles in silica-based glass can be re-shaped by femtosecond laser irradiation studying through their properties, and their orientation appears to be parallel to the written lines. Gold nanoparticles in the size range of 3-4 nm were precipitated by post heat-treatment. After ultrafast laser irradiation, optical absorption, birefringence and dichroism measurements are performed to investigate the modification of gold nanoparticle shape in glass. Theoretical simulations have been carried out to interpret the experimental results based on the Gans' theory and Drude model together with the known dielectric constants of gold. Furthermore, feasible applications and efficient design strategies are also referred for future devices based on micro/nanoclusters 3D precipitation, shaping and orientation mastering. Laser femtoseconde Écriture asymétrique Cristallisation orientée Verres contenant LiNbO3 Reformage de particules d’or Optique non linéaire Femtosecond laser Asymmetric writing Oriented crystallization LiNbO3 containing glasses Gold nanoparticle reshaping Nonlinear optics
72	Two-photon chromophore-polymer conjugates grafted onto gold nanoparticles as fluorescent probes for bioimaging and photodynamic therapy applications Cepraga, Cristina 30 November 2012 (has links) (PDF) Photodynamic therapy (PDT) is an alternative treatment of cancer requiring the use of chromophore molecules (photosensitizers), which can induce cell death after light excitation. Gold nanoparticles (AuNP), exhibiting localized Surface Plasmon Resonance, can enhance the photophysical response of chromophores located in their vicinity, and thus improve their therapeutic action. Moreover, the use of highly localized two-photon chromophores (photosensitizers and fluorophores), capable to undergo a localized excitation by light in the Near InfraRed region, should increase the penetration depth into tissues, thus improve the treatment efficiency (by PDT) and the imaging (by fluorescence microscopy) of cancer tissues.In this work, we describe the elaboration of water-soluble hybrid nano-objects for PDT and fluorescence bioimaging applications, composed of two-photon chromophore-polymer conjugates grafted onto gold nanoparticles. In order to obtain these nano-objects we follow a multistep strategy: i) the synthesis of a well-defined water-soluble chromophore-polymer conjugates; ii) the end-group oriented grafting of chromophore-polymer conjugates onto 20 nm AuNP. The coupling of hydrophobic two-photon chromophores on linear water-soluble copolymer chains (poly(N-acryloylmorpholine-co-N-acryloxysuccinimide)), obtained by controlled/living RAFT polymerization, resulted in well-defined water-soluble chromophore-polymer conjugates, with different polymer lengths (2 000 g.mol-1 < Mn < 37 000 g.mol-1) and architectures (random or block), and a controlled number of chromophores per chain (varying between 1 and 21). Their grafting onto 20 nm AuNP gave water-soluble hybrid nano-objects with high grafting densities (~0.5 chains/nm²). The role of the polymer chain being to tune the distance between chromophores and AuNP surface, we have evidenced the increase in the polymer corona thickness of grafted AuNP (estimated by TEM) with the increasing polymer Mn, corroborating with the corresponding distance-dependent fluorescence properties of those. Finally, the in cellulo biological properties of two-photon chromophore-polymer conjugates, before and after grafting onto AuNP, have been investigated, highlighting their potential for two-photon bioimaging and PDT applications. [SPI:OTHER] Engineering Sciences/Other Medical Imaging Phototherapy Gold nanoparticle Photoinduced death Photodynamic therapy Two-photon microscopy RAFT polymerization Two-photon chromophores Enhanced fluorescence
73	The design of ultrasensitive immunosensors based on a new multi-signal amplification gold nanoparticles-dotted 4-nitrophenylazo functionalised graphene sensing platform for the determination of deoxynivalenol Sunday, Christopher Edozie January 2014 (has links) Philosophiae Doctor - PhD / A highly dispersive gold nanoparticle-dotted 4-nitrophenylazo functionalised graphene nanocomposite (AuNp/G/PhNO2) was successfully synthesised and applied in enhancing sensing platform signals. Three label-free electrochemical immunosensors for the detection of deoxynivalenol mycotoxin (DON) based on the systematic modification of glassy carbon electrodes (GCE) with AuNp/G/PhNO2 was effectively achieved. General electrochemical impedance method was employed for the sensitive and selective detection of DON in standard solutions and reference material samples. A significant increase in charge transfer resistance (Rct) of the sensing interface was observed due to the formation of insulating immune-complexes by the binding of deoxynivalenol antibody (DONab) and deoxynivalenol antigen (DONag). Further attachments of DONab and DONag resulted in increases in the obtained Rct values, and the increases were linearly proportional to the concentration of DONag. The three immunosensors denoted as GCE/PDMA/AuNp/G/PhNH2/DONab, GCE/Nafion/[Ru(bpy)3]2+/AuNp/G/PhNH2/DONab and GCE/Nafion/[Ru(bpy)3]2+/G/PhNH2/DONab have detection range of 6 – 30 ng/mL for DONag in standard samples. Their sensitivity and detection limits were 43.45 ΩL/ng and 1.1 pg/L; 32.14ΩL/ng and 0.3 pg/L; 9.412 ΩL/ng and 1.1 pg/L respectively. This result was better than those reported in the literature and compares reasonably with Enzyme Linked Immunosorbent Assay (ELISA) results. The present sensing methodology represents an attractive alternative to the existing methods for the detection of deoxynivalenol mycotoxin and other big biomolecules of interest due to its simplicity, stability, sensitivity, reproducibility, selectivity, and inexpensive instrumentation. And they could be used to develop high-performance, ultra-sensitive electrochemiluminescence, voltammetric or amperometric sensors as well. Deoxynivalenol mycotoxin Graphene 4-nitrophenyl diazonium cation Gold nanoparticle UV-Vis spectroscopy Raman spectroscopy Cyclic voltammetry Electrochemical impedance spectroscopy Electrochemiluminescence Chronoamperometry/Chronocoulometry
74	Mechanical Properties and Self-Assembly of Nanostructures Mandal, Taraknath January 2014 (has links) (PDF) This thesis is devoted to the investigation of mechanical properties and self-assembly process of materials at the nanoscale. Various nanostructured materials such as nanoparticles, nanotubes, nanowires and thin ﬁlms are used as constituent elements of nanodevices. Hence, knowledge of the mechanical properties of materials at the nanoscale is extremely important for understanding their functionality in nanodevices. Mechanical properties of nanostructured materials may signiﬁcantly differ from those of their bulk counterparts due to the high surface to volume ratio in nanostruc-tures. We particularly focus on the role of the surface region on the stiffness of nanomaterials. We have shown that the stiffness of a nanomaterial can be tuned over a wide range by introducing appropriate coating on the nanostructure surface. We have also explored the effects of the surface region on the stability of various phases in a nanostructure. In the second part of this thesis, we have described the self-assembly process of nanostructures mediated by drendrimers. Self-assembly techniques are frequently used to decorate nanostructures into speciﬁc networks. The motivation of this study is to investigate the mechanisms which control the effective interaction and the inter-particle distance between nanoparticle-dendrimer compos-ites. Control over the inter-particle separation is very important since it has a strong inﬂuence on the electronic and optical properties of the nanostructures. In the following paragraphs, we sum-marize the results of our study. We start with a brief introduction to the mechanical properties and self-assembly process of nanostructures in the ﬁrst chapter. A brief review of the work done on these topics in the recent past is presented in this chapter. We discuss the results and conclusions of various experimental and numerical studies on these topics. We also mention the motivation for the studies we have carried out. At the end, we brieﬂy describe the numerical methods (molecular dynamics (MD) and density functional theory (DFT)) which have been used in our investigations. In the second chapter, we discuss the effects of the surface region on the mechanical properties of nanostructures. We have investigated the size and growth direction dependence of the mechanical properties of ZnS nanowires and thin films as a case study. We observe that the Young’s modulus of nanowires and thin films strongly depends on their size and growth direction. This size and growth direction dependence of the stiffness of nanostructured materials can be explained in terms of their surface modifications. Since the energy of the surface region is usually higher than that of the core region in a nanostructure, the surface atoms move their positions to minimize the surface energy. As a result, bond lengths at the surface region are usually different from their bulk values. We observe that in ZnS nanowires and thin films, the average bond length at the surface region is lower than that in the core region which remains unchanged from its bulk value. This decrease in the bond length (or equivalently increase in the bond energy) increases the effective stiffness of the entire nanostructure. As the size of the nanowire/thin film increases, the effect of the surface region gradually decreases and hence the Young’s modulus value converges to the bulk value. Since the surface region has a strong influence on the mechanical properties of nanostructures, the stiffness of a nanostructure can be tuned by modifying the surface region with other materials. In chapter three, we have shown that the stiffness of ZnS nanowires can be tuned by introducing a thin CdS shell on top of the ZnS surface. In general, the stiffness of a nanostructure can be increased (decreased) by coating the surface region with a stiffer (less stiff) material. However, the stiffness of the core/shell nanostructures strongly depends on the properties of the interface between the core and the shell. We observe that the binding energy between the core and shell regions is relatively low due to the lattice mismatch at the interface region of core/shell nanostructures. This lower binding energy strongly affects the stiffness of core/shell nanostructures. We have also shown that thermal properties such as thermal conductivity and melting temperature of core/shell structures can be tuned by changing the coating material. In chapter four, we discuss the effects of the surface region on the stability of various phases in a nanostructure. The surface atoms may stabilize a particular phase in a nanostructure which is not a stable phase in the bulk material. In this chapter, we investigate the stability of the h-MgO phase, an intermediate structure found during the wurtzite to rock salt transformation, in CdSe nanostructures. We observe that this five-fold coordinated phase is more stable at lower temperatures and smaller sizes of the nanowires. The appearance of this phase has not been observed till now in experiments. We show that this phase is not stable for larger CdSe nanocrystals on which the experiments have been done. In the rest of the thesis, we have presented the results of our studies of self-assembly of nanostructures mediated by DNAs and dendrimers. First we describe in chapter five the nature of the effective interaction between two PAMAM dendrimers. Dendrimers are frequently used to coat surfaces of nanoparticles to prevent the nanoparticles from aggregation. The interaction between such nanoparticle-dendrimer composites depends strongly on the nature of the effective interac-tion between dendrimers. We have used fully atomistic MD simulations to calculate the potential of mean force (PMF) between two PAMAM dendrimers. We show that the effective interaction strongly depends on the size (generation) and protonation level of the dendrimers. The PMF profiles of nonprotonated dendrimers show a global minimum which represents the attractive nature of the interaction between the dendrimers up to a certain center-to-center distance. On the other hand, the interaction between protonated dendrimers is repulsive throughout their interaction re-gion. The PMF profiles are fitted very well by a sum of an exponential and a Gaussian function. This observation is in contradiction with some of the results of existing coarse-grained simulations which predicted the effective interaction between dendrimers to be Gaussian. Our atomistic simulation which includes all the local fluctuations is expected to give more accurate results. Information about the effective interaction between two dendrimers helps in understanding how dendrimer molecules can be used to control the interaction strength and the preferred inter-particle distance between two nanostructures. In chapter six, we discuss the effective interaction between two dendrimer grafted gold nanoparticles. We observe that dendrimer molecules can get adsorbed spontaneously on the surface of a gold nanoparticle. These grafted dendrimers significantly alter the interaction between the gold nanoparticles. We have explored the effects of proto-nation level and the density of the grafted dendrimers on the effective interaction between two gold nanoparticle-dendrimer composites. We observe that these nanoparticle-dendrimer composites at-tract each other at low grafting density. However, the interaction strength and the inter-particle distance at the minimum of the potential are much lower and higher, respectively than those between two bare gold nanoparticles. Interestingly at higher grafting density, the nature of the interaction between the nanocomposites depends on the protonation level of the grafted dendrimers. Nanoparticles grafted with nonprotonated dendrimers still attract each other but with lower inter-action strength and higher inter-particle distance compared to the values for low grafting density. On the other hand, nanocomposites grafted with protonated dendrimers repel each other at high grafting density. Thus we show that the effective interaction and the optimal inter-particle distance between the nanostructures can be tuned over a wide range by using a suitable grafting density and protonation level of the dendrimers. In the seventh chapter, we describe a strategy to assemble dendrimers with the help of sin-gle stranded DNA (ssDNA). We attach an ssDNA to one dendrimer and a complementary ssDNA to a second dendrimer. These two complementary ssDNAs bind with each other through base pair formation to assemble the dendrimers into a single structure. The complementary ssDNAs form a dsDNA which is rigid enough to maintain the inter-dendrimer distance almost the same as the length of the DNA. The inter-dendrimer distance can be tuned by changing the DNA length. However, this method strongly depends on the protonation level of the dendrimers. It works well only for nonprotonated dendrimers. Since the protonated dendrimers are positively charged, they strongly interact with the negatively charged ssDNAs through electrostatic interaction. As a result, ssDNAs wrap the dendrimer surface and hence the inter-dendrimer distance can not be controlled. We have also verified that this method works for multiple nonprotonated dendrimers as well. In the final chapter of this thesis, we summarize the main results and conclude with a brief discussion of future directions of research on the problems considered in the thesis. Nanostructured Materials Mechanical Properties of Nanostructures Self-Assembly of Nanostructures ZnS Nanowires CdSe Nanowires ZnS/CdS Core/Shell Nanowires PAMAM Dendrimer Dendrimers Nanomaterials Thin Films Gold Nanoparticle Materials Science
75	Microscopie de nano-objets individuels : étude de la diffusion des intégrines dans les sites d'adhésion focales de cellules vivantes / Microscopy of single nano-objects : study of integrins diffusion in focal adhesions in live cells Octeau, Vivien 06 July 2010 (has links) L’effet photothermique permet de détecter efficacement des nanoparticules d’or avec un microscope en champ lointain grâce à leur forte absorption de la lumière. L’absence de problème photophysique fait des nanoparticules d’or une alternative au marquage de biomolécules par des sondes fluorescentes. La méthode PhACS (Photothermal Absorption Correlation Spectroscopy) utilise les fluctuations de signal photothermique dues au passage de nanoparticules dans le volume de détection pour étudier leur diffusion. Cette méthode permet également la mesure précise de diamètres hydrodynamiques de nanoparticules fonctionnalisées. La méthode SNaPT (Single Nano-Particle Tracking) réalise le suivi bidimensionnel de nanoparticules individuelles grâce à une localisation effectuée par triangulation. Nous avons appliqué cette méthode pour étudier la diffusion des intégrines alphaV-beta3 marquées par des nanoparticules d’or de 5 nm dans les adhérences focales, points d’ancrage entre le cytosquelette de la cellule et la matrice extracellulaire. Nous observons que ces intégrines ont tendance à former des agrégats qui alternent entre un mouvement diffusif et un mouvement confiné. Ce résultat appelle maintenant à un nouveau modèle où nous aurions une redistribution continue des intégrines au sein des adhérences focales. / Gold nanoparticles may be detected with optical far-field microscopy by use of the photothermal effect due to their strong light absorbance. With no photophysic issues, gold nanoparticles are an alternative to fluorescent probes for use in biological systems. The PhACS method (Photothermal Absorption Correlation Spectroscopy) is used to study diffusion by measuring the autocorrelation of photothermal signal fluctuations due to nanoparticles passing through the detection volume. This method is sensitive enough to mesure the precise hydrodynamic diameter of functionalised nanoparticles. The SnaPT method (Single Nano-Particle Tracking) can track 2-dimensional motion of individual nanoparticles by pinpointing the localization with a triangulation method. The SNaPT method was used to study motion of alphaV-beta3 integrins that were bound to a 5 nm gold nanoparticle inside focal adhesion, where the cell cytoskeleton is linked to the extracullular matrix. The integrin was found to organize into clusters oscillating between the bound and diffuse states. These observations require new working models where integrins would be constantly redistributed. Microscopie Effet photothermique Nanoparticule d'or Suivi de particule unique Spectroscopie de corrélation Intégrine Adhérence focale Microscopy Photothermal effect Gold nanoparticle Single particle tracking Correlation spectroscopy Integrin Focal adhesion
76	Funktionalisierte Polymerkomposite auf Basis von Poly(3,4-ethylendioxythiophen) und Gold Hain, Jessica 15 April 2008 (has links) Poly(3,4-ethylenedioxythiophene), PEDOT, belongs to the group of conducting polymers and is characterized by its high stability, a moderate band gap and its optical transparency in the conductive state. A large disadvantage of conducting polymers, and also PEDOT, is their poor solubility. One way to achieve processible materials is the synthesis of colloidal particles. Thus, this work focuses on the development of conductive particles by preparing composite structures. Polymeric colloids like latex particles and microgels were used as templates for the oxidative polymerization of EDOT. Depending on template structure completely different composite morphologies with variable properties were obtained. It was found that modification with PEDOT did not only cause conductive particles for application as humidity sensor materials, but also candidates for further functionalization with gold nanoparticles (Au-NPs). Due to a multi-stage synthesis route it was possible to achieve polystyrene(core)-PEDOT(shell)-particles decored with Au-NPs. Microgels acting as “micro reactors” for the incorporation of PEDOT and Au-NPs were also used for preparing multifunctional composites for catalytic applications. / Poly(3,4-ethylendioxythiophen), PEDOT, gehört zur Gruppe der leitfähigen Polymere und zeichnet sich durch seine hohe Stabilität, eine moderate Bandlücke und seine optische Transparenz im dotierten Zustand aus. Ein Nachteil leitfähiger Polymere, wie auch von PEDOT, ist deren schlechte Löslichkeit. Die Synthese kolloidaler Partikel bietet jedoch eine Möglichkeit dieses Problem zu umgehen. In diesem Zusammenhang richtete sich der Fokus dieser Arbeit auf die Darstellung leitfähiger Partikel in Form von Kompositstrukturen. Polymerkolloide, wie Latex- und Mikrogelpartikel, sind als Template eingesetzt worden, in deren Gegenwart PEDOT durch eine oxidative Polymerisation synthetisiert wurde. In Abhängigkeit von der Struktur des Templats sind unterschiedliche Kompositmorphologien mit steuerbaren Eigenschaften erhalten worden. Auf diese Weise wurden neben Materialien für die Feuchtigkeitssensorik leitfähige Kompositpartikel hergestellt, die zusätzlich mit Gold-Nanopartikeln (Au-NP) funktionalisiert werden konnten. Durch ein mehrstufiges Syntheseverfahren sind somit Polystyrol(Kern)-PEDOT(Schale)-Partikel mit Au-NP-funktionalisierter Oberfläche synthetisiert worden. Mikrogelpartikel, die als „Mikroreaktoren“ für die Inkorporation von PEDOT- und Au-NP dienten, wurden ebenfalls eingesetzt, um multifunktionale Komposite mit katalytischen Eigenschaften herzustellen. info:eu-repo/classification/ddc/540 ddc:540
77	Physical, chemical and biological modelling for gold nanoparticle-enhanced radiation therapy : towards a better understanding and optimization of the radiosensitizing effect / Modélisation physique, chimique et biologique pour la radiothérapie améliorée par les nanoparticules : vers une meilleure compréhension et optimisation de l’effet radiosensibilisant Poignant, Floriane 27 September 2019 (has links) En radiothérapie, les nanoparticules faites de métaux lourds telles que les nanoparticules l’or (AuNPs) ont démontré des propriétés radiosensibilisantes particulièrement prometteuses. Une augmentation de la dose et du nombre de radicaux produits, à échelle tumorale (effet photoélectrique) et à échelle sub-cellulaire (électrons Auger) pourraient être responsables d’une partie des effets pour les rayons X de basse énergie. Dans le cadre de cette thèse, nous proposons d'étudier ces mécanismes physiques et chimiques précoces par des outils de simulation, afin de mieux les quantifier et comprendre leur impact sur la survie cellulaire. Nous avons d’abord finalisé et validé une simulation Monte Carlo développée pour suivre les électrons jusqu’à très basse énergie à la fois dans l’eau (meV) et dans l’or (eV). Nous avons obtenu de bons résultats pour l’or en comparant nos données avec des données expérimentales de la littérature, en terme de production d’électrons et de perte d’énergie. Nous avons utilisé cet outil de simulation pour quantifier l’énergie déposée dans des nanocibles situées près d’une AuNP, qui est corrélée à la probabilité de générer des dommages. Cette étude a nécessité d’importantes optimisations, afin d’atteindre des temps de calculs raisonnables. Nous avons montré une augmentation significative de la probabilité d’avoir un dépôt d’énergie dans la nanocible supérieur à une énergie seuil, dans un rayon de 200 nm autour de la AuNP, ce qui suggère qu’une AuNP pourrait efficacement détruire des cibles biologiques situées dans sa périphérie. Nous avons ensuite utilisé la simulation pour quantifier des effets chimiques. A échelle macroscopique, nous avons estimé l'augmentation de la quantité de radicaux libres produits en présence d’une concentration d’AuNPs. Nous avons également comparé la distribution radiale des espèces chimiques d’une nanoparticule d’or ionisée, à celle d’une nanoparticule d’eau ionisée. Si le nombre total d'espèces chimiques par ionisation était en moyenne plus important pour l'or que pour l'eau, le nombre d’espèces chimiques produites en périphérie de la nanoparticule n’était pas systématiquement supérieur pour l’or par rapport à l’eau. Cela suggère que l’effet de la AuNP dans sa périphérie réside surtout dans l’augmentation de la probabilité d’avoir une ionisation. Nous avons également étudié plusieurs scénarios pour expliquer l’augmentation expérimentale inattendue de la production d’espèces fluorescentes lors de l’irradiation d’une solution d’AuNPs et de coumarine. Notre étude suggère qu’un scénario plausible pouvant expliquer les observations expérimentales est l’interférence entre une AuNP et une des molécules intermédiaires produites suite à la réaction entre la coumarine et le radical hydroxyle. Pour finir, nous avons injecté les résultats des simulations dans le modèle biophysique NanOx, développé à l’origine à l’IPNL pour calculer des doses biologiques en hadronthérapie, afin de prédire la survie cellulaire en présence de AuNPs. Nous avons aussi implémenté le Local Effect Model (LEM), principal modèle biophysique utilisé dans le contexte des nanoparticules. Pour le LEM, nous nous sommes appuyés sur plusieurs approches dosimétriques proposées dans la littérature. Pour un système simpliste où les AuNPs étaient distribuées de façon homogène dans la cellule, nous avons montré que, selon l’approche dosimétrique, les prédictions de survies du LEM étaient significativement différentes. De plus, nous avons obtenu une augmentation de la mort cellulaire avec NanOx qui était due uniquement à l’augmentation macroscopique du dépôt de dose. Nous n’avons obtenu aucun effet supplémentaire dû aux électrons Auger, en contradiction avec les prédictions du LEM. Cette étude suggère que les modèles actuels proposés pour prédire l'effet radiosensibilisant des AuNPs doivent être améliorés pour être prédictifs, en prenant par exemple en compte de potentiels mécanismes biologiques mis en évidence par l'expérience / In radiation therapy, high-Z nanoparticles such as gold nanoparticles (GNPs) have shown particularly promising radiosensitizing properties. At an early stage, an increase in dose deposition and free radicals production throughout the tumour (photoelectric effect) and at sub-cellular scale (Auger cascade) might be responsible for part of the effect for low-energy X-rays. In this Ph.D work, we propose to study these early mechanisms with simulation tools, in order to better quantify them and better understand their impact on cell survival. We first finalised and validated Monte Carlo (MC) models, developed to track electrons down to low energy both in water (meV) and gold (eV). The comparison of theoretical predictions with available experimental data in the literature for gold provided good results, both in terms of secondary electron production and energy loss. This code allowed us to quantify the energy deposited in nanotargets located near the GNP, which is correlated with the probability to generate damages. This study required important optimisations in order to achieve reasonable computing time. We showed a significant increase of the probability of having an energy deposition in the nanotarget larger than a threshold, within 200 nm around the GNP, suggesting that GNPs may be particularly efficient at destroying biological nanotargets in its vicinity. The MC simulation was then used to quantify some chemical effects. At the macroscale, we quantified the increase of free radicals production for a concentration of GNPs. We also compared the radial distribution of chemical species following the ionisation of either a gold nanoparticle or a water nanoparticle. We showed that following an ionization, the average number of chemical species produced is higher for gold compared to water. However, in the vicinity of the nanoparticle, the number of chemical species was not necessarily higher for gold compared to water. This suggests that the effect of GNPs in its vicinity mostly comes from the increase of the probability of having an ionisation. We also studied several scenarios to explain the unexpectedly high experimental increase of the production of fluorescent molecules during the irradiation of a colloidal solution of GNPs and coumarin. Our study suggests that a plausible scenario to explain experimental measurements would be that GNPs interfere with an intermediate molecule, produced following the reaction between a coumarine molecule and a hydroxyl radical. During the last step of this Ph.D work, we injected our MC results in the biophysical model NanOx, originally developed at IPNL to calculate the biological dose in hadrontherapy, to predict cell survival in presence of GNPs. In addition, we implemented the Local Effect Model (LEM), currently the main biophysical model implemented for GNP-enhanced radiation therapy, to compare the NanOx and the LEM predictions with each other. In order to estimate cell survival with the LEM, we used various dosimetric approaches that were proposed in the literature. For a simple system where GNPs were homogeneously distributed in the cell, we showed that the LEM had different outcomes with regard to cell survival, depending on the dosimetric approach. In addition, we obtained an increase of cell death with the biophysical model NanOx that was purely due to the increase of the macroscopic dose. We did not obtain an increased biological effectiveness due to Auger electrons, which comes in contradiction with the LEM predictions. This study suggests that the current biophysical models available to predict the radiosensitizing effect of GNPs must be improved to be predictive. This may be done, for instance, by accounting for potential biological mechanisms evidenced by experimental works Radiothérapie Nanoparticule d'or Radiosensibilisant Monte Carlo Simulation Modélisation biophysique Radicaux libres Radiotherapy Gold nanoparticle Radiosensizer Monte Carlo Simulation Biophysical modelling Free radicals 530
78	Controlling Gold Nanoparticle Assembly through Particle-Particle and Particle-Surface Interactions Kelley, John Joseph 28 August 2018 (has links) No description available. Materials Science gold nanoparticle electrostatic self-assembly self-assembled monolayer amino silane mixed silane random sequential adsorption radial distribution function Voronoi tessellation
79	A Lateral Flow Smart Phone Image Analysis Diagnostic Tyrrell, Christina Holly 01 August 2013 (has links) (PDF) A low cost compact diagnostic has many implications in today’s society. Smart phone technology has exponentially grown and with it the imaging capabilities associated with smart phones. The goals of this research are i) to determine the feasibility of combining in the field smart phone images with color dependent assay results, ii) to develop a MatLab® image analysis code to analyze these results, and iii) compare limits of detection between the un-aided eye and MatLab® image analysis software. Orange G dye is used to create a stock solution and subsequent titers for analysis. Autocad is used to design an assay platform of 10x10 wells that are printed via a Xerox® Phaser printer with wax ink onto nitrocellulose paper. Dilutions are performed and pipetted into the wells. The image analysis code is used to determine hue, saturation, and value (HSV) values of wells. A limit of detection study using the dye is performed. HSV values are used to form calibration curves. The resulting curve fit equations are then integrated into the image analysis code to determine dye concentration. Finally, the complete capability is demonstrated by using an analogous 10x10 well experimental nitrocellulose sheet, which included a follow-up experiment via a spot check analysis. This study illustrates the feasibility of a low cost image analysis as a tool for lateral flow assay diagnostic versus the unaided eye. Future work includes using this protocol in conjunction with a lateral flow immunoassay and developing an application for the analysis. Lateral flow assay (LFA) Colloidal gold Orange G dye Gold nanoparticle (NP) Smart phone Image analysis code
80	Simulation of Microwave Heating of Healthy and Cancerous Human Tissue With Gold Nanoparticles Carlens, Hampus, Söderström, Mika January 2022 (has links) With a great need for new and better cancer treatments, microwaves and gold nanoparticles (GNPs) are increasingly being suggested to be used in radiotherapy. In thisreport, the authors present an investigation of how human tissue,both malignant and healthy, behaves under microwave radiation.Specifically, the focus has been on gradual transitions between healthy and GNP-treated cancerous tissue inside a waveguide.Here, the electromagnetic material property of concern is therelative permittivity. The permittivities of human tissues andGNPs have been modelled using well known analytical models.Furthermore, numerical simulations have been performed usingCOMSOL Multiphysics and the results have been compared to analytical equations suggested to describe the energy absorption in the material. The study shows that the analytical equations are in agreement with the numerical simulations for lower propagating electromagnetic (EM) modes. Some possible electromagnetic resonance has been seen within the GNP treated cancer tissue. Furthermore, the extensive analytical models and numerical software tools created will be of importance for future research of the feasibility of this cancer treatment method. / Med ett stort behov av nya, bättre cancer-behandlingar föreslås mikrovågsstrålning och guldnanopartiklar (GNPs) att användas i strålterapi. I denna rapport presenterar författarna en undersökning av hur mänsklig vävnad beter sig under mikrovågsstrålning. Specifikt har fokus varit på gradvisa övergångar mellan frisk och GNP fylld cancervävnad i en vågledare. Här är den elektromagnetiska egenskapen av intresse den relativa permittiviteten. Permittiviteterna av mänsklig vävnad och GNPs har modellerats med välkända analytiska modeller. Vidare har numeriska simuleringar utförts i COMSOL Multiphysics och resultaten av dessa har jämförts med de analytiska ekvationerna som sägs beskriva absorbtion av energi inuti materialet. Undersökningen visar att de analytiska ekvationerna stämmer överens med de numeriska simuleringarna för lägre propagerande elektromagnetiska (EM) moder. Möjlig elektromagnetisk resonans har setts inom den GNP fyllda cancervävnaden. De omfattande analytiska modellerna och numeriska mjukvaruverktygen som tagits fram kommer vara viktiga för framtida forskning på denna cancerbehandling. / Kandidatexjobb i elektroteknik 2022, KTH, Stockholm Gold nanoparticle (GNP) Electrophoretic resonance Dispersive permittivity Cancer treatment Waveguide Radiotherapy Graded material. Elektroteknik och elektronik

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