Molecular modeling of beta-cyclodextrin complexes with nootropic drugs.

The geometry and structural features of the inclusion complexes of beta-cyclodextrin (beta-CD) with the chiral antiamnesic drugs (+/-)-1-benzyl-4-hydroxymethylpyrrolidin-2-one (WEB-1868). (+/-)-1-benzenesulfonyl-5-ethoxypyrrolidin-2-one (RU-35929), and (+/-)-1-(3-pyridinlysulfonyl)-5-ethoxypyrrolidin-2-one (RU-47010) were studied by the molecular modeling method (MacroModel interactive computer program). Docking procedures yielded the most stable complexes, which showed the aromatic ring of the guests inside the cavity and the pyrrolidinone ring out from the side of the beta-CD secondary hydroxyl groups. The binding energies were essentially due to hydrogen-bonded structures involving the C=O group of the guests. Selective interactions allowed chiral discrimination, and accordingly, separate beta-CD complexes of the R and S enantiomers of each guest compound were studied. The almost round beta-CD structure, in all the cases, assumed an elliptic shape on passing from the isolated molecule to the docked complex. The optimized structures and conformations of beta-CD and its inclusion compounds showed acceptable general agreement with information from proton nuclear magnetic resonance studies.

Nuclear magnetic resonance investigation of the stoichiometries in beta-cyclodextrin:steroid inclusion complexes.

Nuclear magnetic resonance at high field has been used to investigate the stoichiometries of pharmacologically important beta-cyclodextrin:steroid complexes. This technique provides evidence for the existence of true inclusion complexes and allows unequivocal determination of the stoichiometry for complexes obtained in the solid state, as well as in solution. The present data clarify previously published determinations of the stoichiometry of these complexes and show the influence of the nature and position of functional groups on the molecular ratio in the complex. The observed behavior can be rationalized using representative steroids and allows prediction of the strength of inclusion and the most probable stoichiometry.

High-field nuclear magnetic resonance techniques for the investigation of a beta-cyclodextrin:indomethacin inclusion complex.

The inclusion complex of indomethacin sodium salt in beta-cyclodextrin has been studied by proton NMR at high magnetic field. The continuous variation technique was used to evidence the formation of a soluble 1:1 complex in aqueous solution at physiological pH. The effective association constant was determined by the Benesi-Hildebrand procedure to be 760 M-1 at 303 K. This technique requires NMR measurements in the presence of a very large excess of one of the complex components and, since both beta-cyclodextrin and the sodium salt of indomethacin are sparingly soluble in water, NMR spectrometers operating at very high magnetic fields were used. Besides the effective association constant, the Benesi-Hildebrand approach allows a precise determination of all NMR parameters of the pure inclusion complex which may be used for a complete analysis of the geometry of this complex in solution.