Conformation stability and organization of mefloquine molecules in different environments.

The crystal structures of mefloquine base, [C17H16F6N2O], and two salts of mefloquine: hydrochloride [(C17H17F6N2O)+]3[Cl-]3.3H2O and hydrochloride tetrachlorocobaltate [(C17H17F6N2O)+]3Cl-[CoCl4]2-.C2H6O.H2O, were determined by X-ray diffraction measurements. A comparison of the crystal structures of mefloquine in three different crystalline environments shows that their conformations are stable regardless of mefloquine being a base or a salt. In addition, the conformation of mefloquine is similar to those of crystalline Cinchona alkaloids. The CF3 substituents in the quinoline moiety affect the packing of molecules.

Cobalt complexes with cinchonidine and quinidine: effect of C8/C9 stereochemistry and 6'-substitution on intermolecular interactions.

The title compounds, (cinchonidinium)trichlorocobalt(II) [(C(19)H(23)ON(2))CoCl(3)] (CoCdn) and (quinidinium)trichlorocobalt(II) [(C(20)H(25)O(2)N(2))CoCl(3)] (CoQd), are zwitterions that differ in absolute configuration and conformation. In both complexes, the sp(3) nitrogen of quinuclidine is protonated, whereas the sp(2) nitrogen of quinoline is linked to the Co(II) atom, which coordinates three chlorine atoms in distorted tetrahedral geometry. The mutual orientations of the quinoline and quinuclidine moieties in CoCdn and CoQd differ significantly because of different hydrogen bonding involving the hydroxyl group. In both complexes, the quinuclidine NH groups and hydroxyl groups are hydrogen-bond donors to the chlorine atoms of Co(II) tetrahedra. In CoQd the hydrogen bonding leads to formation of a nine-membered ring consisting of Co, two chlorines, and a fragment of the quinidine molecule. A comparison of the crystal structures of four Cinchona alkaloid complexes with trichlorocobalt(II) shows that their space groups are determined by the absolute configuration of the alkaloid, whereas the hydrogen-bonding pattern is mainly affected by the substituent in the quinoline ring, i.e., by hydrogen or methoxyl group.

Cobalt complex of cinchonine: intermolecular interactions in two crystalline modifications.

Two crystalline modifications of cinchonine cobalt complex, C19H23Cl3CoN2O, were obtained from mixture of saturated alcohol solutions of CoCl3 x 6H2O and cinchonine. The X-ray structure analysis revealed that the asymmetric unit of one modification, CoCn1, contains only zwitterionic molecules of the complex. In the asymmetric unit of the other, CoCn2, there are two molecules of the title compound and two molecules of ethanol. The influence of the absolute configuration, the CoCl3 coordination with quinoline, and the presence of alcohol molecules on the studied structures was established by comparison of the crystal and molecular structures of both cobalt complexes with the analogous quinine complex and zinc complex of cinchonine. The interactions that dominate in the packing of the molecules in both structures are intermolecular hydrogen bonds. They form characteristic ring systems, depending on the presence of the alcohol molecules. The ring features are also related to the absolute configuration of the alkaloid.