Modeling the scavenging activity of ellagic acid and its methyl derivatives towards hydroxyl, methoxy, and nitrogen dioxide radicals.

The reaction mechanisms involved in the scavenging of hydroxyl (OH(·)), methoxy (OCH₃(·)), and nitrogen dioxide (NO2 (·)) radicals by ellagic acid and its monomethyl and dimethyl derivatives were investigated using the transition state theory and density functional theory. The calculated Gibbs barrier energies associated with the abstraction of hydrogen from the hydroxyl groups of ellagic acid and its monomethyl and dimethyl derivatives by an OH· radical in aqueous media were all found to be negative. When NO₂(·) was the radical involved in hydrogen abstraction, the Gibbs barrier energies were much larger than those calculated when the OH(·) radical was involved. When OCH₃(·) was the hydrogen-abstracting radical, the Gibbs barrier energies lay between those obtained with OH(·) and NO₂(·) radicals. Therefore, the scavenging efficiencies of ellagic acid and its monomethyl and dimethyl derivatives towards the three radicals decrease in the order OH(·) >> OCH₃(·) > NO₂(·). Our calculated rate constants are broadly in agreement with those obtained experimentally for hydrogen abstraction reactions of ellagic acid with OH· and NO₂· radicals.