AI Article Synopsis
- A new method was developed to create platinum (Pt) complexes with bioactive molecules using bipyridine-type ligands that include components like ethacrynic acid and flurbiprofen.
- The resulting complexes demonstrated high stability in water/DMSO at 37 °C and showed the release of active fragments in cell culture, indicating promising bioactivity.
- These complexes exhibited significant antiproliferative effects against various cancer cell lines, with one combination effectively overcoming resistance to cisplatin, highlighting the potential for improved cancer treatment strategies.
Article Abstract
A facile route to Pt complexes doubly functionalized with bioactive molecules through a bipyridine-type ligand is described. Initially, ligands L (containing two ethacrynic acid units), L (ethacrynic acid+flurbiprofen) and L (ethacrynic acid+biotin) were obtained in moderate to good yields from 2,2'-bipyridine-4,4'-dicarboxylic acid. Subsequent reaction of the ligands with [PtCl (DMSO) ] afforded complexes [PtCl (L )] (2), [PtCl (L )] (3) and [PtCl (L )] (4) in high yields. All compounds were fully characterized by analytical and spectroscopic methods. Complexes 2-4 are highly stable in water/DMSO solution at 37 °C after 72 h, whereas progressive release of the bioactive fragments was detected in a cell culture medium. The compounds were assessed for their in vitro antiproliferative activity towards tumorigenic A2780, A2780cisR and Y79 cells and non-tumourigenic HEK293 cells. In particular, the combination of ethacrynic acid and flurbiprofen in 3 overcomes cisplatin-based resistance and provides strong cancer cell selectivity. Enzyme inhibition assays on human GST P1 and human COX-2 and cross-experiments with complex 1, analogous to 2-4 but lacking bio-groups, revealed a clear synergy between the Pt frame and the bioactive organic components.
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