Effect of hydroxyl position on antioxidant ability of hydroxycoumarin derivatives: A theoretical investigation

Abstract

Effect of the OH group position on the antioxidant ability of hydroxycoumarin derivatives (HOC) was investigated by quantum chemical computation. Frontier molecular orbitals, molecular electrostatic potential, and thermodynamic parameters were analyzed in detail. The results indicate that 3-HOC, 6-HOC, and 7-HOC exhibit as the best reactants with free radicals through analysis of global reactivity descriptor values, meanwhile H (in OH groups) of 4-HOC, 5-HOC, 6-HOC, and 7-HOC molecules are the most preferable sites for nucleophilic attacks. Besides, thermodynamic and kinetic studies reveal hydrogen atomic transfer is the primary mechanism when hydroxycoumarin derivatives react with HOO• free radical in the gas phase and pentyl ethanoate. Hydrogen atomic transfer products account for over 97 % of the total products of hydrogen atomic transfer and radical adduct formation mechanisms. According to the study, 6-HOC is the most effective scavenger of free radicals when compared to other derivatives, with a rate constant of 1.38 × 104 M−1s−1 in the gas phase and 6.5 × 103 M−1s−1 in pentyl ethanoate. The interaction of O20∙∙∙H21 in the transition state of 6-HOC is crucial in stabilizing its structure. This finding suggests that 6-HOC can be a potential candidate for developing antioxidants for various applications in the medical and industrial fields. The results of this study provide valuable insights into the mechanisms by which antioxidants can scavenge free radicals and protect against oxidative stress.