3.9 Article

Theoretical study of chemical reactivity descriptors of some repurposed drugs for COVID-19

Journal

MRS ADVANCES
Volume -, Issue -, Pages -

Publisher

SPRINGER HEIDELBERG
DOI: 10.1557/s43580-023-00590-6

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This study uses density functional theory calculations to investigate the chemical reactivity descriptors of proposed drugs for COVID-19. The structure optimization and analysis of frontier orbitals reveal the importance of the highest occupied molecular orbital (HOMO) and the lowest unoccupied molecular orbital (LUMO) in molecular interactions and reactivity. The polarizability is higher in complex drugs such as Hydroxychloroquine, Remdesivir, and Ivermectin, and the calculated energy gap suggests that larger gaps correspond to lower reactivity and higher stability.
This study focuses on computational studies of chemical reactivity descriptors of some proposed drugs for COVID-19. Density functional theory calculations were used to optimize the structure and investigate the frontier orbitals and the chemical reactivity descriptors of these drugs. The frontier orbitals, which include both the highest occupied molecular orbital (HOMO) and the lowest unoccupied molecular orbital (LUMO), play an essential role in molecular interactions and chemical reactivity of molecule. Polarizability, which determines the response of the susceptibility of a molecule to an approaching charge, is higher in the more complex drugs such as Hydroxychloroquine, Remdesivir, and Ivermectin compare to the smaller drugs. The HOMO and LUMO orbital energies were calculated to obtain the energy gap of the studied drugs, which is in the following order: Favipiravir < Hydroxychloroquine, Remdesivir < Ivermectin < Artesunate < Artemether < Artemisinin. Generally, molecules with a larger energy gap have lower chemical reactivity and higher kinetic stability.

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