6533b871fe1ef96bd12d165a

RESEARCH PRODUCT

Porphyrines et tétraazamacrocycles dérivés du DOTA : association de deux ligands pour la chélation de métaux d'intérêt en imagerie médicale multimodale

subject

description

The goal of my PhD thesis was to synthesize new molecules, which give access to heterobimetallic complexes with interesting properties for multimodal imaging. In this manuscript, several main points have been studied. The first part of this work concerns the synthesis and characterization of ligands. We describe here the synthesis of five new ligands based on the association of one porphyrin and one or several cyclen derivatives. Those ligands are water-soluble. During the synthesis, we have targeted improvements to our work and developed a new synthetic pathway, which allowed us to obtain one ligand incorporating a porphyrin, a cyclen derivative and a free amine function. This function could be activated to further graft the ligand onto a biological vector. The second part of this manuscript describes the chelation of metallic centers into the ligands and the study of their efficiency as MRI contrast agents. We describe the synthesis of five gadolinium (III) complexes and three heterobimetallic complexes associating gadolinium (III) with copper (II). Indeed, gadolinium is currently used in contrast agents for MRI and the radioactive isotope of copper, copper-64 is used in PET imaging. We describe also a procedure to measure the relaxivity of the gadolinium complexes at low and high magnetic fields. Five complexes exhibit relaxivity values five times larger than commercially available MRI contrast agents. The last part of this work is related to the synthesis, characterization and photophysical studies of four molecular antennas incorporating porphyrins and BODIPY. We describe two original synthetic pathways. The first one is based on the formation of boron-oxygen bonds by substitution of the fluorine atoms bound to BODIPY boron atom. The second synthetic pathway involves the Huisgen’s dipolar cycloaddition. We describe photophysical data and give evidences of the energy transfer from BODIPY to porphyrin. We present also the first example of energy transfer from porphyrin to BODIPY in the system obtained by “click” chemistry involving an extended “blue” BODIPY.