Président du jury Kauffmann, Jean-Michel
Promoteur Dufrasne, François
Publication Non publié, 2013-12-05
| Résumé : | 15N-based nuclear magnetic resonance techniques are considered very powerful to study the molecular properties of platinum-containing anticancer agents, these properties being responsible for the efficacy of the compounds, but also for the understanding of resistance mechanisms and toxicity. Therefore, the first part of the present work aimed to develop a new method for synthesizing 15N-labeled, chiral platinum compounds. A theoretical discussion on the nucleophilic ring-opening of aziridines has also been envisaged, rationalizing an interesting regiochemistry question. Indeed, a surprising inversion of regiochemistry arose during the development of the above-mentioned synthetic pathway, and density functional theory calculation brought a rational framework to the experimental findings. Infrared spectroscopy probes the global chemical composition of a sample and has been used to produce a snapshot of cancer cells contents after treatment with platinum coordinates. Indeed, in vitro studies focused here on the use of modern spectroscopic methods to fingerprint the cellular impact of platinum complexes. These drug signatures help to classify and select promising compounds. It makes no doubt that such systemic approaches for compound discovery are helpful technologies. Also, we made the use of the COMPARE algorithm from the NCI, which analyzes similarity between any active compounds previously tested by the NCI large scale in vitro screening program of anticancer agents. The last chapter aimed to study the interactions between a series of platinum coordinates and DNA. Binding mode to telomeric-like sequences and binding kinetics to genomic-like sequences were assessed to investigate any differences between the compounds and to gain insight into structure-activity relationships. |
