Gregory A. Stephenson scite author profile

5-Methyl-2-[(2-nitrophenyl)amino]-3-thiophenecarbonitrile has been crystallized as six solvent-free polymorphs, which differ in the mode of packing and in molecular conformation. The conformational difference results principally from the thiophene torsion relative to the o-nitroaniline fragment, which leads to different crystal colors (red, orange, and yellow). Thermodynamic stability relationships between polymorphs have been determined from solid-state conversions and calorimetric data of melting and eutectic melting. Vibrational spectroscopy and ab initio calculations showed that most conformers in solution feature perpendicularly arranged thiophene and o-nitroaniline fragments, although a minor population of more planar conformers also exist. Crystallization has a stabilizing effect for more planar and higher dipole conformers over perpendicular ones by 3−6 kJ/mol. The only exception to this pattern is the one polymorph containing weak intermolecular hydrogen bonds.

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Formation of Isomorphic Desolvates: Creating a Molecular Vacuum

Stephenson¹,

Groleau²,

Kleemann³

et al. 1998

Journal of Pharmaceutical Sciences

159

151

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The objective of this work was to investigate a common but poorly understood category of crystalline organic substances: isomorphic desolvates. When solvent is lost from a crystal lattice but the lattice retains its three-dimensional order, a lattice is created which is in a high-energy state relative to the original solvate structure. The desolvated lattice can reduce its internal energy by either resorbing solvent or by relaxation processes which increase the packing efficiency of the solid by reducing the unit cell volume. In the following paper, solid-state properties of isomorphic desolvates of cephalexin, cefaclor, erythromycin A, and spirapril hydrochloride hydrates are investigated. The hygroscopicity of the compounds are evaluated using a vacuum moisture balance, and structural relaxation is measured using a combination of X-ray powder diffraction and isothermal microcalorimetry. The study results are explained in terms of Kitaigorodski's close packing principle.

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Assessment of the Amorphous “Solubility” of a Group of Diverse Drugs Using New Experimental and Theoretical Approaches

et al. 2014

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The supersaturation potential of poorly water-soluble compounds is of interest in the context of solubility enhancing formulations for enhanced bioavailability. In this regard, the amorphous "solubility", i.e., the maximum increase in solution concentration that can be obtained relative to the crystalline form, is an important parameter, albeit a very difficult one to evaluate experimentally. The goal of the current study was to develop new approaches to determine the amorphous "solubility" and to compare the experimental values to theoretical predictions. A group of six diverse model compounds was evaluated using the solvent exchange method to generate an amorphous phase in situ, determining the concentration at which the amorphous material was formed. The theoretical estimation of the amorphous "solubility" was based on the thermal properties of the crystalline and amorphous phases, the crystalline solubility, and the estimated concentration of water in the water-saturated amorphous phase. The formation of an amorphous precipitate could be captured transiently for all six compounds and hence the amorphous "solubility" determined experimentally. A comparison of the experimental amorphous "solubility" values to those calculated theoretically showed excellent agreement, in particular when the theoretical estimate method treated the precipitated phase as a supercooled liquid, and took into account heat capacity differences between the two forms. The maximum supersaturation ratio in water was found to be highly compound dependent, varying between 4 for ibuprofen and 54 for sorafenib. This information may be useful to predict improvements in biological exposure for poorly water-soluble compounds formulated as amorphous solid dispersions or other formulations that rely on supersaturation.

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