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Degradation Mechanisms of Six Typical Glucosidic Bonds of Disaccharides Induced by Free Radicals

Biyang Zhu, Cong Ma, Lijun You

2024Journal of Agricultural and Food Chemistry21 citationsDOI

Abstract

Increasing hydrogen peroxide (H 2 O 2 )-based systems have been developed to degrade various polysaccharides due to the presence of highly reactive free radicals, but published degradation mechanisms are still limited. Therefore, this study aimed to clarify the degradation mechanism of six typical glucosidic bonds from different disaccharides in an ultraviolet (UV)/H 2 O 2 system. The results showed that the H 2 O 2 concentration, disaccharide concentration, and radiation intensity were important factors affecting pseudo-first-order kinetic constants. Hydroxyl radical, superoxide radical, and UV alone contributed 58.37, 18.52, and 19.17% to degradation, respectively. The apparent degradation rates ranked in the order of cellobiose ≈ lactose > trehalose ≈ isomaltose > turanose > sucrose ≈ maltose. The reaction pathways were then deduced after identifying their degradation products. According to quantum chemical calculations, the cleavage of α-glycosidic bonds was more kinetically unfavorable than that of β-glycosidic bonds. Additionally, the order of apparent degradation rates depended on the energy barriers for the formation of disaccharide-based alkoxyl radicals. Moreover, energy barriers for homolytic scissions of glucosidic C 1 –O or C 7 –O sites of these alkoxyl radicals ranked in the sequence: α-(1 → 2) ≈ α-(1 → 3) < α-(1 → 4) < β-(1 → 4) < α-(1 → 6) < α-(1 → 1) glucosidic bonds. This study helps to explain the mechanisms of carbohydrate degradation by free radicals.

Topics & Concepts

RadicalChemistryGlycosidic bondDisaccharidePhotochemistryTrehaloseHydrogen peroxideMaltoseAlkoxy groupHydroxyl radicalOrganic chemistrySucroseAlkylEnzymeAdvanced Glycation End Products researchPhytochemicals and Antioxidant ActivitiesFree Radicals and Antioxidants