Computational Study of Solvent Effects on Characterizations of ( E )‐3‐X‐Indoline‐2‐thiones Derivatives as Antivirus and Anticancer Compounds

( E )‐3‐X‐Indoline‐2‐thione derivatives (X = phenyl, furan‐2‐yl, 1H ‐pyrrole‐2‐yl, and thiophene‐2‐yl, I – IV , respectively) are considered as potent and selective inhibitors against different receptor tyrosine kinases. A particularly interesting issue for these biologically active compounds is how their stability is affected by solvation. Here we have tackled this issue using the self‐consistent reaction field theory for I – IV , in the gas phase as well as solution including: toluene, CH 2 Cl 2 , MeOH , and H 2 O . The highest observed total free energy difference between liquid (l) and gas (g) phase (∆ E l–g ) relates to structure III in water, whereas the lowest ∆ E l–g is associated with II in toluene. Thus, III is the most solvent sensitive and enjoys maximum stabilization in water. On the other extreme, II is the least solvent sensitive and its stability is least affected by solvation in toluene. Moreover, stability of each solute ( I – IV ) depends on the dielectric constant of the solvent and the possibility of the hydrogen bonding. In going from gas phase to different solvents, considerable changes of nucleophilicity as well as electrophilicity occur for scrutinized structures. The six‐ and five‐membered rings in indoline skeleton for all species show aromatic and nonaromatic property, respectively. Finally, the substituent rings appear the most aromatic property. These phenomena are confirmed by the succeeding geometrical parameters.