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1	Development and optimization of shape-specific, stimuli-responsive drug delivery nanocarriers using Step and Flash Imprint Lithography Caldorera-Moore, Mary 30 September 2010 (has links) The advent of highly sophisticated drugs designed to interfere with specific cellular functions has created the demand for “intelligent” carriers that can efficiently deliver therapeutic agents in response to a pathophysiogical condition. Nanoscale intelligent systems can maximize the efficacy of therapeutic treatments in numerous ways because they have the ability to rapidly detect and response to disease states directly at the site and sparing physiologically healthy cells and tissues, thereby improving a patient’s quality of life. Nanoparticle fabrication has primarily relied on emulsions, self-assembly and micelles based methods which inherently generate polydisperse spherical particles with little control over particle geometry. Despite significant progress in such drug delivery systems, critical limitations remain in synthesizing nanocarriers with highly controllable architecture (size, shape or aspect ratio) that can, at the same time, impart response-sensitive release mechanisms. These parameters are essential for controlling the in-vivo transport, bio-distribution, and drug release mechanisms. The objective of my dissertation is to employ the nanofabrication technique Step and Flash Imprint Lithography (S-FIL) to synthesize stimuli-responsive nanocarriers of precise architectures and composition. Applying S-FIL technology, fabrication of nanocarriers of a variety of shapes and sizes (down to 36nm length scale) that are also environmentally responsive by incorporating enzymatically-degradable peptides into the nanocarrier hydrogel matrix, to provide triggered release of encapsulated therapeutic agents in response to specific pathophysiological conditions, has been accomplished. Besides disease-responsive release, the two key properties of an effective nanocarrier are (a) efficient targeting to specific tissues and cells and (b) avoiding rapid clearance and remaining in circulation in the blood stream for a significant amount of time to increase particle uptake in target tissues. These two properties are expected to be dependent on the shape and size of the carriers. Using various shape and size S-FIL fabricated nanoparticles, the effects of particle geometry on intracellular uptake has also been evaluated. In this dissertation, I will present the extensive work that has been done in the fabrication and optimization of the S-FIL nanocarriers, evaluation of the nanocarrier’s in vitro properties, and evaluation of the effects of nanocarrier geometry on intracellular uptake. / text Stimuli-Responsive Hydrogels Nano-Imprint Lithography
2	Substrate Engineering to Control the Synthesis of Carbon Nanotubes Krishnaswamy, Arvind January 2014 (has links) No description available. Nanoscience Carbon Nanotubes Substrate Engineering Nano-Imprint Lithography Photo-Lithography Thermal CVD Plasma-enhanced CVD
3	Dispositifs ultra-sensibles pour le nano-adressage electrique. Application a la detection de biomolecules MALAQUIN, Laurent 09 June 2004 (has links) (PDF) " Because technology provides the tools and biology the problems, the two should enjoy a happy marriage ! "1 . Cette phrase resume parfaitement l'esprit du projet qui a motive ces travaux de these. En effet, le couplage des biotechnologies et des micro et nano technologies, resume sous le vocable < Nanobiotechnologies > est une activite en plein essor qui laisse presager de nombreuses applications en particulier dans le domaine de la biodetection. Lobjectif principal de ces travaux est dedie au developpement de strategies d'adressage de biomolecules a l'echelle nanometrique pour des applications de biodetection. Le premier aspect de ce travail est d'ordre technologique. Il concerne la fabrication de dispositifs d'adressage bases sur des reseaux de nanoelectrodes planaires. En utilisant un procede reposant sur lutilisation de la lithographie electronique haute resolution sur un microscope TEM/STEM, nous avons pu demontrer la fabrication de dispositifs a base de nanoelectrodes presentant des espaces inter-electrodes controlables entre 100 et 15nm. Une technique de lithographie alternative, la Nano-Impression est egalement presentee comme une solution possible a la replication de nanodispositifs fabriques par lithographie electronique. La deuxieme partie des travaux est dediee a la mise en place dun schema de detection de nanoparticules que nous avons developpe autour de dispositifs bases sur des reseaux delectrodes inter-digitees. Avant de nous interesser a l'utilisation de ces dispositifs pour une application biologique, nous avons etudie leur reponse electrique vis-a-vis de l'absorption de nanoparticules d'Or par interaction electrostatique. Les premiers resultats obtenus montrent que le schema de detection permet d'atteindre un niveau de sensibilite ultime au travers d'une mesure directe de la conductance des dispositifs. Certaines experiences montrent en effet la possibilite de mesurer electriquement l'adsorption d'une seule nanoparticule. Enfin, la derniere partie de ces travaux est dediee a l'adaptation de ce protocole pour la detection de biomolecules fonctionnalisees par des nanoparticules d'Or. Pour cela, nous avons employe une approche simple basee sur un systeme de reconnaissance entre une molecule cible et une molecule sonde. Ce schema a ete applique a la detection d'interaction antigene/anticorps et nous a permis de transcrire la selectivite de la reconnaissance entre les anticorps dans le depot des nanoparticules qui se traduit par une modification importante de la conductance du dispositif. Les possibilites d'integration ainsi que la compatibilite des dispositifs avec des systemes de microfluidique rendent ce schema de detection particulierement adapte pour le developpement d'un systeme integre de biodetection a tres haute sensibilite. 1 S. Fields, Proc. Natl. Acad. Sci. USA, vol 98, pp 10051-10054 (2001) [PHYS:PHYS] Physics/Physics Nanobiotechnologies Nanoelectrodes Detection electrique Biocapteurs Nanoparticules Immunodetection Lithographie electronique Nano-Impression Electrical biodetection Biosensor Nanoparticles Immunoassays Electron Beam Lithography Nano-Imprint Lithography

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