Solvent solute interaction (IEFPCM model), Michael addition-based anticancer drug synthesis, FTIR, NMR, and UV–visible investigations of spirooxindole-pyranoindole (2AIPC) − in vitro and in silico anti-cancer activity

Abstract

Herein, click chemistry was chosen to synthesize 2AIPC using Knoevenegel and Michael addition reactions. In this synthesis, Lewis base was attracted by the generation of sp3 hybridized carbanion at active methylene group in the reactants for propagation reaction proceeding towards conducting the Michael addition product. The synthesized 2AIPC was characterized by NMR(13C and 1H), UV, FTR and FT-IR analytical tools; it was also evaluated utilizing density functional theory. According to DFT analyses, the comparative study of the functional groups of 2AIPC molecule was successfully described using Raman and FT-IR spectra with simulated spectra. NLO behaviour and charge exchange utilizing the hyperpolarizability and FMO band gap characteristics were also investigated. Through computational studies using MEP, FUKUI, RDG, and NBO, intermolecular interaction and the reactive area of the synthesized molecule were demonstrated.Moreover, the anticancer activity under the in-vitro analysis was tested, and the molecule showed 61.04 % GI against the K-562 leukemia cells at 10-5 M. Molecular docking also evaluated cytotoxicity by in silico study against leukemia-related proteins (60QN, 6OQC, 1EMR, and 606F). The docked complexes showed binding affinities of −7.82, −7.1, −6.9, and −6.71 kcal/mol. A nucleophile elimination process at 2AIPC’s main amino group may also increase the molecule’s potential to be a more effective lead medication.