Développement de stratégies d'imagerie multimodalités pour la pharmacologie des agents anticancéreux / Development of multimodal imaging strategies for the pharmacology of anticancer agents

Brullé, Laura

24 May 2012

L’imagerie préclinique dans le domaine de la cancérologie est en plein essor. Elle permet grâce à des modèles animaux représentatifs de cancers humains de comprendre les mécanismes de développement des pathologies et d’évaluer l’efficacité thérapeutique d’un nouveau traitement. Le principal objectif de ce travail a été de développer deux modèles orthotopiques de cancer (pancréas et colon) et d’évaluer des traitements de références ainsi qu’une nouvelle stratégie thérapeutique par plasma froid fibré appelée Plasma Gun. Les 2 modèles de cancers développés ont montré une bonne représentativité vis-à-vis des cancers humains, avec l’apparition de métastases à distance et la présence de zones hypoxiques. Le 5-fluorouracile pour le modèle orthotopique de carcinome colorectal HCT116-luc et la gemcitabine pour le modèle d’adénocarcinome pancréatique MIA PaCa2-luc ont induit à faible dose des effets discrets pouvant être mis en évidence grâce aux modalités d’imageries mises en oeuvre. Après validation de nos démarches expérimentales une nouvelle stratégie thérapeutique, le Plasma Gun, a été évaluée et a montré des effets significatifs sur l’inhibition de la croissance tumorale. Le second objectif de ma thèse a été de mettre en oeuvre des outils pour l’induction et la caractérisation des métastases osseuses ainsi que pour l’imagerie haute résolution de la vascularisation. D’une part, les métastases osseuses obtenues par injection de cellules PC3M-luc en intracardiaque ont été évaluées et quantifiées grâce à différentes modalités d’imagerie (bioluminescence, scintigraphie et scanner X). D’autre part, la réalisation d’une imagerie haute résolution de la vascularisation a été possible grâce à la technique de casting qui permet de recréer la structure 3D de l’architecture vasculaire suite à l’injection d’une résine dans la circulation. Les développements réalisés lors de cette thèse ont ainsi permis d’apporter des outils pour l’évaluation préclinique de nouvelles thérapies anticancéreuses. / Preclinical imaging in oncology is booming. It allows, using representative animal models of human cancers, to understand the mechanisms of development of pathologies and to assess the therapeutic efficiency of a new treatment. The main objective of this work was to develop two orthotopic models of cancer (pancreas and colon) and to assess on them the reference treatments as well as a new therapeutic strategy by non thermal plasma so called Plasma Gun. The two cancer models developed showed good representation in relation to human cancers, with the appearance of distant metastases and hypoxia. 5-fluorouracil for the HCT116-luc orthotopic model of colorectal carcinoma and gemcitabine for the MIA PaCa2-luc pancreatic adenocarcinoma model, have induced discrete effects at low dose wich can be detected thanks imaging modalities. After validation of our experimental steps, a new therapeutic strategy, Plasma Gun was evaluated and showed significant effects on tumor growth inhibition. The second objective was to carry out tools for the induction and the characterization of bone metastases and for high resolution imaging of the vasculature. On the one hand, bone metastases obtained by injection of PC3M-luc cells intracardially, was evaluated and quantified with different imaging modalities (bioluminescence, scintigraphy and Computed Tomography). And the other hand, the achievement of a high resolution imaging of vascularization, was possible by the casting method that restores the 3D structure of the vascular architecture following injection of a resin in the circulation.

Imagerie du petit animal

Modèles orthotopiques

Technique de casting

Plasma Gun

Small animal imaging

Orthotopic model

Casting method

Plasma Gun

Development Of A Multigrid Accelerated Euler Solver On Adaptively Refined Two- And Three-dimensional Cartesian Grids

Cakmak, Mehtap

01 July 2009

Cartesian grids offer a valuable option to simulate aerodynamic flows around complex geometries such as multi-element airfoils, aircrafts, and rockets. Therefore, an adaptively-refined Cartesian grid generator and Euler solver are developed. For the mesh generation part of the algorithm, dynamic data structures are used to determine connectivity information between cells and uniform mesh is created in the domain. Marching squares and cubes algorithms are used to form interfaces of cut and split cells. Geometry-based cell adaptation is applied in the mesh generation. After obtaining appropriate mesh around input geometry, the solution is obtained using either flux vector splitting method or Roe&rsquo / s approximate Riemann solver with cell-centered approach. Least squares reconstruction of flow variables within the cell is used to determine high gradient regions of flow. Solution based adaptation method is then applied to current mesh in order to refine these regions and also coarsened regions where unnecessary small cells exist. Multistage time stepping is used with local time steps to increase the convergence rate. Also FAS multigrid technique is used in order to increase the convergence rate. It is obvious that implementation of geometry and solution based adaptations are easier for Cartesian meshes than other types of meshes. Besides, presented numerical results show the accuracy and efficiency of the algorithm by especially using geometry and solution based adaptation. Finally, Euler solutions of Cartesian grids around airfoils, projectiles and wings are compared with the experimental and numerical data available in the literature and accuracy and efficiency of the solver are verified.

TJ Mechanical Engineering. 1-1570

Synthesis And Characterization Of Bulk Glass-forming Iron-boron Based Alloy Systems

Gurbuz, Selen Nimet

01 June 2004

The aim of this study, which was carried out in two main parts, is to investigate the glass forming ability of Fe-based systems. The first part involves the theoretical modeling to cover the requirement of a predictive model to identify the Fe-based alloy families that have high glass forming ability in the frame of atomistic and thermodynamic approach. The second part involves the experimental investigations to prove the results of the conducted theoretical modeling studies. For this purpose, in the first part, theoretical investigations were performed to identify the third alloying elements that will lead to an increase in the glass forming ability on the base of electronic theory of alloys in pseudopotential approximation for selected Fe- based systems, Fe - (B, Zr, Nb, C, W). In the experimental part, in the frame of the theoretical investigation results, one of the theoretically modeled binary system, and the third alloying elements that were predicted to lead an increase in the glass forming ability of the selected binary system, were determined. As a first step, designated compositions were synthesized by using low grade conventional Fe-B alloy as a raw material by using centrifugal casting technique and copper mold casting method. To compare the results, same compositions were also cast from the high purity elements by using the same technique and method. For the characterization of these cast specimens, DSC, XRD, SEM, EDS and metallographic examination techniques were used. Amorphous structure was successfully obtained in the thin sections of the wedge-cast samples for Fe-B-Nb and Fe-B-W ternary systems.

TN Mining Engineering, Metallurgy. 1-997