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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Multicellular Tumor Spheroids as a Model to Study Tumor Cell Adaptations within a Hypoxic Environment

Riffle, Stephen January 2017 (has links)
No description available.
2

Optode-bead-based Functional Chemical Imaging of 2D Substrates

Ahuja, Punkaj N. 30 June 2011 (has links)
No description available.
3

Ciblage tumoral par des nanoparticules photoactivable basée sur des complexes de cyclodextrines encapsulées dans des liposomes / Cyclodextrin-based photoactive liposomal nanoparticles for tumor targeting

Yakavets, Ilya 12 November 2019 (has links)
La thérapie photodynamique (PDT) est un traitement alternatif du cancer plus ciblé et moins invasif que les modalités traditionnelles. La Temoporfine (mTHPC, nom sous forme médicamenteuse : Foscan®), est l'un des PS les plus puissants cliniquement approuvés. Cependant, sa faible solubilité en milieu aqueux a provoqué plusieurs complications lors de son administration. La présente étude vise à mettre au point des nanoparticules constituées d’une molécule anticancéreuse couplée à la cyclodextrine intégré dans un liposome (drug-in-cyclodextrin-in-liposome, DCL) en couplant deux systèmes d'administration indépendants : les complexes d'inclusion cyclodextrine-mTHPC et les vésicules liposomales pour améliorer le transport et la pénétration de la mTHPC dans le tissu cible. La formation de complexes d'inclusion entre les cyclodextrines et la mTHPC a été étudiée en détail. Sur la base de ces données, des mTHPC-DCL à simple et double charge ont été préparées, optimisées et caractérisées. Il a été démontré que les mTHPC-DCL sont stables et que presque tous les mTHPC-DCL sont liés à β-CDs dans la lumière aqueuse interne des liposomes. L'influence des DCLs sur l'accumulation, la distribution et l'efficacité photodynamique de la mTHPC a été étudiée dans des modèles cellulaire en monocouche et sphéroïde multicellulaires 3D d’adénocarcinome de pharynx humain (HT29). En utilisant des sphéroïdes, nous avons démontré que le DCL à base de triméthyl-β-CD fournissait une accumulation homogène de la mTHPC dans tout le volume des sphéroïdes tumoraux, suggérant ainsi une distribution optimale de la mTHPC. / Photodynamic therapy (PDT) is an alternative cancer treatment which offers a more targeted and less invasive treatment regimen compared to traditional modalities. Temoporfin (mTHPC, medicinal product name: Foscan®), is one of the most potent clinically approved PS. However, its poor solubility in aqueous medium caused several complications of its administration. The present study is aimed at the development of drug-in-cyclodextrin-in-liposome (DCL) nanoparticles by coupling two independent delivery systems: cyclodextrin/mTHPC inclusion complexes and liposomal vesicles to improve the transport and penetration of mTHPC to the target tissue. The formation of inclusion complexes between cyclodextrins and mTHPC was studied in detail. Based on these data, single and double loaded mTHPC-DCLs have been prepared, optimized and characterized. It was demonstrated that mTHPC-DCLs are stable and almost all mTHPC is bound to β-CDs in the inner aqueous liposome lumen. The influence of DCLs on mTHPC accumulation, distribution and photodynamic efficiency was studied in human adenocarcinoma HT29 cellular monolayer and spheroid models. Using 3D multicellular HT29 tumor spheroids we demonstrated that trimethyl-β-CD-based DCL provides homogenous accumulation of mTHPC across tumor spheroid volume thus supposing optimal mTHPC distribution.
4

Quiescent cancer cells : Three-dimensional cell models for evaluation of new therapeutics / Vilande cancerceller : Tredimensionella cellmodeller för utvärdering av nya cancerläkemedel

Ek, Frida January 2022 (has links)
Inadequate metabolic conditions in solid tumors lead to the formation of quiescent cancer cells that are suspended in a transient cell cycle arrest. When conditions change, quiescent cancer cells can re-enter the cell cycle and cause recurrence. Drug screening efforts have revealed mitochondrial oxidative phosphorylation as a unique metabolic dependency in quiescent cancer cells. The anthelmintic drug nitazoxanide is an inhibitor of oxidative phosphorylation and preferentially active against quiescent cancer cells in multicellular tumor spheroids.  In this thesis, we employed current and developed new models of quiescent cancer cells and applied live cell imaging for improved preclinical evaluation of cancer drugs in hepatocellular and colorectal carcinoma cell lines. As part of this work, a new assay to measure mitochondrial membrane potential in three-dimensional cell models was developed, an application of the JC-1 assay, and we demonstrated that the preferential activity against quiescent cancer cells of nitazoxanide is shared by two kinase inhibitors: sorafenib and regorafenib. The sensitivity of quiescent cancer cells to nitazoxanide, sorafenib, and regorafenib correlated with the disruption of the mitochondrial membrane potential. Nitazoxanide and sorafenib, in combination, caused an additive decrease in viability, mitochondrial membrane potential, and colony regrowth capacity.  Furthermore, we developed a quiescent hollow fiber assay and implemented an improved analysis using live cell imaging and adenosine triphosphate analysis. Hypoxia and cancer cell quiescence were enriched in hollow fiber macrocapsules over time, and the culture conditions affected nitazoxanide sensitivity. Additionally, we used basement membrane extract gel to support cell growth in hollow fiber macrocapsules and implanted macrocapsules in mice. We observed that the in vivo environment was favorable to cell growth. Through this characterization of the quiescent hollow fiber assay, we were able to outline important paths for future research.

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