Crystal structures and Hirshfeld surface analyses of the di- and tri-hydrates of (5α,17E)-17-hydrazonoandrostan-3-ol: Significant differences in the hydrogen bonding patterns and supramolecular arrangements.

The crystal structures, Hirshfeld surface analyses and electrostatic potential surfaces of the di- and tri-hydrates of (5α,17E)-17-hydrazonoandrostan-3-ol, 3, namely [3·(H2O)2] and [3·(H2O)3], are reported. The trihydrate, isolated from a solution of 3 in moist methanol, recrystallizes in the orthorhombic space group, P212121, while that of the dihydrate, isolated from a 1:1 aqueous methanol solution, recrystallizes in the monoclinic space group, P21. The asymmetric unit of the trihydrate involves one steroid and three water molecules, while that of the dihydrate has two similar but independent steroid molecules and four hydrate molecules. Very similar conformations are found for the steroid molecules in both hydrates. As expected, the different mole ratios of water: steroid have major influences on the structures. In both cases, complex crystal structures are constructed from various classical hydrogen bonds, involving the hydrate molecules and the hydroxy and hydrazonyl moieties of the steroid. In the trihydrate, there are no direct connections between the steroid molecules, instead the water molecules link the steroid molecules, with only weak van der Waals forces between the steroid molecules. There are some direct links between the steroid molecules in the dihydrate, involving OH(steroid hydroxyl)⋯O(steroid oxo) hydrogen bonds, in a head to head fashion, and OH⋯N(hydrazonyl) hydrogen bonds, in a head to tail fashion. However, the major occurrence throughout the structure is of steroid molecules linked by water molecules.

Crystal structures and Hirshfeld surface analyses of the hemi-hydrate and hemi-methanolate of 3α-hydroxy-16α-bromoandrostan-17-one, 3: Differences in supramolecular arrangements.

The crystal structures and Hirshfeld surface analyses of two hemi-solvates of 3α-hydroxy-16α-bromoandrostan-17-one, 3, namely [(3)2.(H2O)] and [(3)2.(MeOH)], are reported. Both solvates crystallize in the monoclinic space group, P21, with Z = 4.. The asymmetric unit of the hemi-hydrate [(3)2.(H2O)] contains two independent but similar steroid molecules and a water molecule, while that of the hemi-methanoate [(3)2.(MeOH)] has four similar but independent steroid molecules and two methanol molecules. Very similar conformations are found for the steroid molecules in both solvates. In both solvates, the strongest intermolecular interactions are OH···O hydrogen bonds, involving hydroxyl groups of the steroid and the solvate molecule, which result in head-to-head directly linked steroid molecules and solvate separated steroid molecules. In both cases, the oxygen atoms of the carbonyl groups of the steroids are involved in weaker CH···O hydrogen bonds which directly link steroid molecules in tail-to-tail fashions. Combinations of the hydrogen bonds, both OH···O and CH···O, result in two-molecule wide sheets in the hemi-hydrate, which are further weakly linked in the hemi--methanoate into a 3-dimensional array. Very different hydrogen bonded chains are found in the two solvates. There is a higher proportion of CH···O to OH···O hydrogen bonds in the hemi-methanoate, [8-6], compared to that in the hemi-hydrate [1-4]: this is an indication of the weaker solvating influence of methanol compared to water.

Crystal structure of bis-[3-meth-oxy-17ß-estra-1,3,5(10)-trien-17-yl] oxalate.

In the title compound, C40H50O6, a symmetrical steroid oxalate diester, the dihedral angle between the CO2 planes of the oxalate linker is 61.5 (5)° and the C-C bond length is 1.513 (6) Å. The steroid B, C and D rings adopt half-chair, chair and envelope conformations, respectively, in both halves of the mol-ecule, which adopts an overall shallow V-shaped conformation. In the crystal, mol-ecules are linked by weak C-H⋯O inter-actions, forming a three-dimensional network.

Synthesis and spectroscopic data analyses of 5beta-cholane derivatives.

Facile synthesis and spectroscopic data analyses of three 5beta-cholane derivatives, 3alpha-tosyloxy-5beta-cholan-24-ol (3), 5beta-cholan-24-ol (4) and 5beta-cholan-24-yl tosylate (5), are described.

Synthesis of ester-linked lithocholic acid dimers.

Four lithocholic acid dimers were synthesised via esterification. The ester-linked dimer, 3-oxo-5beta-cholan-24-oic acid (cholan-24-oic acid methyl ester)-3-yl ester, (3alpha,5beta), was obtained by condensation of methyl lithocholate with 3-oxo-5beta-cholan-24-oic acid. Borohydride reduction of this ester-linked dimer gave 3alpha-hydroxy-5beta-cholan-24-oic acid (cholan-24-oic acid methyl ester)-3-yl ester, (3alpha,5beta), which was acetylated to 3alpha-acetoxy-5beta-cholan-24-oic acid (cholan-24-oic acid methyl ester)-3-yl ester, (3alpha,5beta). Reaction of methyl lithocholate with oxalyl chloride yielded the oxalate dimer, bis(5beta-cholan-24-oic acid methyl ester)-3alpha-yl oxalate.