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Surface modification of titanium substrates with polymer brushes to control cell adhesion for bioapplicationsRaynor, Jenny E. 17 November 2008 (has links)
Modification of the surface chemistry of materials used as implants in biomedical applications affords the ability to control cell adhesion, prevent inflammation and enhance integration with the host. Titanium and its alloys are strong and lightweight thereby making them desirable for applications such as hip and knee replacements, dental implants, and cardiac pacemaker implants. However, the lifetime of these implants is often limited by poor incorporation into the surrounding bone which results in loosening and wear. In order to overcome these limitations we have studied the modification of titanium substrates with a self-assembled monolayer that can be used to perform surface-initiated atom transfer radical polymerization (SI-ATRP) of a monomer to afford polymer brushes that effectively prevent the adhesion of cells. In addition, the polymer brushes afford the ability to tether a peptide sequence. Specific peptides containing adhesion sequences have been tethered to the polymer brushes. The resulting surfaces promote cell adhesion and osteoblast differentiation, thereby increasing bone tissue formation around the implant resulting in better incorporation of the implant.
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Complexes osmium nitrosyle avec des ligands bioactifs : synthèse, structure, réactivité et activité antiproliférative in vitro / Osmium nitrosyl complexes with bioactive ligands : synthesis, structure, reactivity and antiproliferative activity in vitroGavriluta, Anatolie 24 September 2013 (has links)
Notre travail de thèse a été dédié à la synthèse et à la caractérisation bio-physicochimique de complexes osmium nitrosyle, qui pourraient relarguer l’oxyde nitrique (NO) au sein des cellules tumorales pour conjuguer les propriétés anticancéreuses souvent associés aux complexes du groupe du platine avec la toxicité de l’oxyde nitrique. Le premier chapitre de notre mémoire de thèse présente l’état de l’art dans le domaine des composés anticancéreux et le rôle de l’oxyde nitrique dans l’apoptose cellulaire. Le deuxième chapitre concerne la synthèse et la caractérisation de complexes d’azole (C)[Os(NO)Cl4(A)] (C = Bu4N+, Na+, HA+; A = indazole, pyrazole, benzimidazole, imidazole), où le plus cytotoxique est H2ind[cis-Os(NO)Cl4(indazole)]. Le troisième chapitre est consacré à l’étude cinétique et thermodynamique par RMN de l’isomérisation trans ↔ cis du complexe (Bu4N)[Os(NO)Cl4(indazole)] qui met en évidence un processus d’isomérisation de type dissociatif. Le quatrième chapitre concerne la synthèse et la caractérisation de complexes d’aminoacides (Bu4N)[Os(NO)Cl4(L)] (L = gly, picolinate, L-, D-pro) qui ont une très faible activité antiproliférative. Le dernier chapitre est consacré à la synthèse et à la caractérisation de clusters hétérométalliques [{Os(NO)Cl3(Ox)}4Ln] (Ln = Gd, Tb, Dy, Y ; Ox=oxalate) dans lesquels la coordinance 8 ou 9 du lanthanide dépend de son rayon ionique. Le précurseur {Os(NO)Cl3(Ox)} a l’activité antiproliférative la plus élevée de tous les complexes osmium nitrosyle connus / The PhD thesis was dedicated to the synthesis and bio-physic-chemical characterization of osmium nitrosyl complexes which could release nitric oxide (NO) in tumor cells to combine the anticancer properties of the platinum group complexes and the nitric oxide cytotoxicity. The first chapter presents the state of the art in the field of anticancer compounds and the role of nitric oxide in the apoptosis. The second chapter concerns the synthesis and characterization of azole complexes with the general formulae (C)[Os(NO)Cl4(A)] (C = Bu4N+, Na+, HA+; A = indazole, pyrazole, benzimidazole, imidazole), where the most cytotoxic is H2ind[cis-Os(NO)Cl4(indazole)]. The third chapter focuses on the kinetic and thermodynamic study of the trans ↔ cis isomerisation of (Bu4N)[Os(NO)Cl4(indazole)] complex by NMR, which highlights a dissociative isomerisation process. The fourth chapter concerns the synthesis and the characterization of amino acids complexes with the general formulae (Bu4N)[Os(NO)Cl4(L)] (L = gly, picolinate, L-, D-pro) of whose antiproliferative activity is very low. The last chapter is dedicated to the synthesis and characterization of heterometallic clusters with the general formulae [{Os(NO)Cl3(Ox)}4Ln] (Ln = Gd, Tb, Dy, Y ; Ox = oxalate), where the coordination number 8 or 9 depends on its ionic radius. The precursor {Os(NO)Cl3(Ox)} has the highest antiproliferative activity among of all osmium nitrosyl known so far
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