A novel relationship between the radical-scavenging activity of flavonoids and enthalpy of formation revealed with Hartree–Fock computations and thermochemical deduction

Abstract

Objective

The present study aims to establish the relationship between the reported radical-scavenging activities of flavonoids and some enthalpy changes that may occur during flavonoids' reactions with free radicals.

Method

Eight flavonoids were chosen for the study on the basis of their structural merits and reported 1,1-diphenyl-2-picryl-hydrazyl scavenging activities. Enthalpy changes accompanying interconversions between selected conformations (including spin multiplicities) and homolytic dissociations were estimated.

Results

A novel relationship exists between the total enthalpy of reaction for the abstraction of two hydrogen atoms from flavonoids, their reported radical-scavenging activities and the enthalpy of the homolytic dissociation of hydrogen molecule (104.206 kcal mol⁻¹). Only those flavonoids which could give up two hydrogen atoms with total enthalpy changes well below 104.206 kcal mol⁻¹ were active radical scavengers.

Discussion

By appealing to equilibrium dynamics, we demonstrated that, for flavonoids to be able to donate hydrogen atoms, the change in enthalpy accompanying the abstraction of two hydrogen atoms needs to be less than 104.206 kcal mol⁻¹. This condition does not seem to be restricted to flavonoids only but rather generally applicable to chian-breaking antioxidants.

Conclusion

Thermodynamical relationships may be the most important factors governing the radical-scavenging reactions of flavonoids and possibly other compounds as well. Nevertheless, a more complete characterization of antioxidants would necessitate kinetic analysis.

Keywords:

• Flavonoids
• Free radical scavengers
• Antioxidants
• Oxidation–reduction
• Hydrogen bonding
• Molecular conformation
• Thermodynamics

View correction statement:

A novel relationship between the radical-scavenging activity of flavonoids and enthalpy of formation revealed with Hartree–Fock computations and thermochemical deduction

Acknowledgements

This work was supported by UWSIPRS scholarship and the NCI National Facility at the ANU. Computational and storage resources used were provided by Intersect Australia Ltd.

Funding

The funding was supported by UWSIPRS, University of Western Sydney International Postgraduate Research Scholarships and NCI National Facility at the Australian National University (ANU).