Unraveling the Antioxidant Activity of 2R , 3R -dihydroquercetin.

It has been reported that in an oxidative environment, the flavonoid 2R , 3R -dihydroquercetin ( 2R , 3R -DHQ) oxidizes into a product that rearranges to form quercetin. As quercetin is a very potent antioxidant, much better than 2R , 3R -DHQ, this would be an intriguing form of targeting the antioxidant quercetin. The aim of the present study is to further elaborate on this targeting. We can confirm the previous observation that 2R , 3R -DHQ is oxidized by horseradish peroxidase (HRP), with H 2 O 2 as the oxidant. However, HPLC analysis revealed that no quercetin was formed, but instead an unstable oxidation product. The inclusion of glutathione (GSH) during the oxidation process resulted in the formation of a 2R , 3R -DHQ-GSH adduct, as was identified using HPLC with IT-TOF/MS detection. GSH adducts appeared on the B-ring of the 2R , 3R -DHQ quinone, indicating that during oxidation, the B-ring is oxidized from a catechol to form a quinone group. Ascorbate could reduce the quinone back to 2R , 3R -DHQ. No 2S , 3R -DHQ was detected after the reduction by ascorbate, indicating that a possible epimerization of 2R , 3R -DHQ quinone to 2S , 3R -DHQ quinone does not occur. The fact that no epimerization of the oxidized product of 2R , 3R -DHQ is observed, and that GSH adducts the oxidized product of 2R , 3R -DHQ on the B-ring, led us to conclude that the redox-modulating activity of 2R , 3R -DHQ quinone resides in its B-ring. This could be confirmed by chemical calculation. Apparently, the administration of 2R , 3R -DHQ in an oxidative environment does not result in 'biotargeting' quercetin.