MiRNA Profiling of Tumor-Derived Exosomes

Cancers and infectious diseases are becoming a growing public health problem in the world today. The importance of my work for public health is in detecting these diseases earlier and more accurately, potentially leading to better therapies and higher survival rates for patients. Current diagnostic techniques focus on detecting antibodies from serum, gene expression and miRNA profiles of tumor tissues and, more recently, in the bodily fluids of patients. This dissertation shows a novel technique that makes use of small microvesicles called exosomes and the microRNAs (miRNAs) they carry for the potential diagnosis of cancer. Exosomes are small (40-100 nm) membrane-bound vesicles that are created from the inverse budding of the multivesicular endosome and originate from a variety of tumor types. Exosomes can be easily purified from cell cultures and serum of patients and have recently been shown to carry small non-coding RNAs called miRNAs. In the first part of this study, I developed techniques that enabled us to increase the amount of our exosome and total RNA starting material before proceeding to use these as potential diagnostics for head and neck cancers. Although the use of exosomes to diagnose diseases is not novel, the use of miRNAs present in tumor-derived exosomes is a new approach. In the final two chapters, I discuss the use of exosomes to diagnose KSHV viral infections as well as head and neck cancer. Increasing the accuracy and reducing the amount of starting material needed for these studies would provide a non-invasive technique to detect viral infections and cancers. This would help in providing earlier therapeutic treatments and help to increase the longevity and quality of life of patients

Etude théorique et expérimentale du fonctionnement bifréquence de microlasers continus et impulsionnels pour la génération d'ondes RF et THz

Parmi les approches possibles pour réaliser des sources térahertz dans la gamme0,2 - 2 THz, nous nous sommes intéressés à la voie optoélectronique qui consiste à générerl onde térahertz par le photomélange de deux ondes lasers à des fréquences optiques. Letravail présenté dans cette thèse concerne l étude de lasers bi-fréquence capables d émettreles deux ondes requises simultanément. Nous commençons par développer un modèlethéorique décrivant la compétition de gain entre les modes laser grâce au calcul de différentscoefficients de couplage. Sur le plan expérimental, nous montrons tout d abord qu endésalignant légèrement un des miroirs de la cavité laser, il est possible d obtenir un régimestable d émission sur deux fréquences pourtant en compétition dans le milieu à gain, ici uncristal dopé néodyme. Nous nous intéressons ensuite au régime impulsionnel et montronsque les impulsions peuvent être synchronisées grâce à l action d un laser externe. Enfin, leprocessus de photomélange a été réalisé et des ondes électromagnétiques ont été généréesdans le domaine des radio-fréquences autour de 20 GHz.Among the possible solutions to build terahertz sources in the 0,2 - 2 THz range,we studied the optoelectronic way consisting in the generation of a terahertz wave by photomixingtwo laser waves at optical frequencies. The work presented in this PhD concernsthe study of dual-frequency lasers able to emit the two required waves simultaneously.We begin by developing a theoretical model describing the gain competition between thelaser modes by calculating different coupling coefficients. Experimentally, we first showthat a slight misalignment of the output mirror of the laser cavity allows to obtain a stableemission at two frequencies competing in the gain medium, which is a neodymium-dopedcrystal. Then, we focus on the pulsed regime and we show that the pulses can be synchronizedby the action of an external laser. Finally, the photomixing process has been achievedand electromagnetic waves have been generated in the radio frequencies range around 20GHz.SAVOIE-SCD - Bib.électronique (730659901) / SudocGRENOBLE1/INP-Bib.électronique (384210012) / SudocGRENOBLE2/3-Bib.électronique (384219901) / SudocSudocFranceF

On the formation and decay of a molecular ultracold plasma

Double-resonant photoexcitation of nitric oxide in a molecular beam creates a dense ensemble of $50f(2)$ Rydberg states, which evolves to form a plasma of free electrons trapped in the potential well of an NO$^+$ spacecharge. The plasma travels at the velocity of the molecular beam, and, on passing through a grounded grid, yields an electron time-of-flight signal that gauges the plasma size and quantity of trapped electrons. This plasma expands at a rate that fits with an electron temperature as low as 5 K, colder that typically observed for atomic ultracold plasmas. The recombination of molecular NO$^+$ cations with electrons forms neutral molecules excited by more than twice the energy of the NO chemical bond, and the question arises whether neutral fragmentation plays a role in shaping the redistribution of energy and particle density that directs the short-time evolution from Rydberg gas to plasma. To explore this question, we adapt a coupled rate-equations model established for atomic ultracold plasmas to describe the energy-grained avalanche of electron-Rydberg and electron-ion collisions in our system. Adding channels of Rydberg predissociation and two-body, electron- cation dissociative recombination to the atomic formalism, we investigate the kinetics by which this relaxation distributes particle density and energy over Rydberg states, free electrons and neutral fragments. The results of this investigation suggest some mechanisms by which molecular fragmentation channels can affect the state of the plasma

First results from the OSQAR photon regeneration experiment: No light shining through a wall

A new method to amplify the photon-axion conversions in magnetic field is proposed using a buffer gas at a specific pressure. As a first result, new bounds for mass and coupling constant for purely laboratory experiments aiming to detect any hypothetical scalars and pseudo-scalars which can couple to photons were obtained at 95% confidence level, excluding the PVLAS result newly disclaimed.Comment: 4 pages, 5 figure

Search for weakly interacting sub-eV particles with the OSQAR laser-based experiment: results and perspectives

Recent theoretical and experimental studies highlight the possibility of new fundamental particle physics beyond the Standard Model that can be probed by sub-eV energy experiments. The OSQAR photon regeneration experiment looks for "Light Shining through a Wall" (LSW) from the quantum oscillation of optical photons into "Weakly Interacting Sub-eV Particles" (WISPs), like axion or axion-like particles (ALPs), in a 9 T transverse magnetic field over the unprecedented length of $2 \times 14.3$ m. No excess of events has been detected over the background. The di-photon couplings of possible new light scalar and pseudo-scalar particles can be constrained in the massless limit to be less than $8.0\times10^{-8}$ GeV$^{-1}$. These results are very close to the most stringent laboratory constraints obtained for the coupling of ALPs to two photons. Plans for further improving the sensitivity of the OSQAR experiment are presented.Comment: 7 pages, 7 figure

Plasma Oscillations and Expansion of an Ultracold Neutral Plasma

We report the observation of plasma oscillations in an ultracold neutral plasma. With this collective mode we probe the electron density distribution and study the expansion of the plasma as a function of time. For classical plasma conditions, i.e. weak Coulomb coupling, the expansion is dominated by the pressure of the electron gas and is described by a hydrodynamic model. Discrepancies between the model and observations at low temperature and high density may be due to strong coupling of the electrons.Comment: 4 pages, 4 figures. Accepted Phys. Rev. Let

Growth and characterization of semiconductor nanoparticles in porous sol-gel films

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