Antioxidant Activity of Deferasirox and Its Metal Complexes in Model Systems of Oxidative Damage: Comparison with Deferiprone.
Viktor A TimoshnikovLilia A KichiginaOlga Yu SelyutinaMarina Sergeevna BorisovaGeorge J KontoghiorghesPublished in: Molecules (Basel, Switzerland) (2021)
Deferasirox is an orally active, lipophilic iron chelating drug used on thousands of patients worldwide for the treatment of transfusional iron overload. The essential transition metals iron and copper are the primary catalysts of reactive oxygen species and oxidative damage in biological systems. The redox effects of deferasirox and its metal complexes with iron, copper and other metals are of pharmacological, toxicological, biological and physiological importance. Several molecular model systems of oxidative damage caused by iron and copper catalysis including the oxidation of ascorbic acid, the peroxidation of linoleic acid micelles and the oxidation of dihydropyridine have been investigated in the presence of deferasirox using UV-visible and NMR spectroscopy. Deferasirox has shown antioxidant activity in all three model systems, causing substantial reduction in the rate of oxidation and oxidative damage. Deferasirox showed the greatest antioxidant activity in the oxidation of ascorbic acid with the participation of iron ions and reduced the reaction rate by about a 100 times. Overall, deferasirox appears to have lower affinity for copper in comparison to iron. Comparative studies of the antioxidant activity of deferasirox and the hydrophilic oral iron chelating drug deferiprone in the peroxidation of linoleic acid micelles showed lower efficiency of deferasirox in comparison to deferiprone.
Keyphrases
- iron deficiency
- drug delivery
- hydrogen peroxide
- reactive oxygen species
- end stage renal disease
- chronic kidney disease
- ejection fraction
- emergency department
- prognostic factors
- risk assessment
- oxide nanoparticles
- health risk
- electron transfer
- human health
- single molecule
- aqueous solution
- case control
- atomic force microscopy