Solid state characterization of mometasone furoate anhydrous and monohydrate forms.

Mometasone furoate is a potent glucocorticoid anti-inflammatory agent. Its anhydrous Form 1 and monohydrate form were characterized by X-ray crystallography, X-ray powder diffraction at ambient and elevated temperature, thermal analysis, FT-IR, and dynamic moisture adsorption. In Form 1, mometasone furoate molecules pack tightly with molecules interlocked in a space group of P2(1)2(1)2(1). The monohydrate form crystallizes in space group P1. The unit cell of the monohydrate contains one water molecule and one mometasone furoate molecule. The water molecules form channels along the a axis and mometasone furoate molecules pack in layers in the same direction. Dehydration was observed between 60 and 100 degrees C by thermogravimetric analysis with a heating rate of 10 degrees C/min. It corresponds to a broad endotherm over the same temperature range in the differential scanning calorimetry with the same heating rate. Variable temperature X-ray powder diffraction reveals that a new anhydrous form (Form 2) was fully produced above 90 degrees C. This crystalline form was converted to Form 1 after being heated above 150 degrees C; and was totally converted to the monohydrate after 1 day at 23 degrees C, 45% RH.

Structural analysis of polymorphism and solvation in tranilast.

Five polymorphic forms of tranilast were characterized by thermal, diffractometric, and spectroscopic techniques. The crystal structures of the most stable anhydrous form (Form I), a chloroform solvate, and a dichloromethane solvate were determined from single-crystal X-ray analysis. Two additional anhydrous forms of tranilast (Forms II and III) were also studied, but were not amenable to SCXRD. All five forms were also analyzed using solid-state nuclear magnetic resonance, Fourier transform infrared, and Fourier transform-Raman spectroscopy, and thermal methods. From the trends observed in the crystal structures and the spectral data, some conclusions can be made about hydrogen bonding, molecular conformation, and crystal packing differences in the polymorphs and solvates. Form II was found to be a spectroscopically distinctive polymorph that is probably missing an important intramolecular hydrogen bond coupled with a conformational change. In contrast, Form III was found to be more similar to the crystallographically characterized forms, and is more likely a packing and hydrogen-bonding polymorph with a weakened intermolecular hydrogen-bonding interaction relative to the other forms. From a pharmaceutical development perspective, it is shown that although the anhydrous forms of tranilast have similar thermal properties, they can be reliably distinguished by spectroscopic methods.