Investigation of the polymorphism of the angiotensin II antagonist agent MK-996

Application and use of isothermal calorimetry in pharmaceutical development

There are many steps involved in developing a drug candidate into a formulated medicine and many involve analysis of chemical interaction or physical change. Calorimetry is particularly suited to such analyses as it offers the capacity to observe and quantify both chemical and physical changes in virtually any sample. Differential scanning calorimetry (DSC) is ubiquitous in pharmaceutical development, but the related technique of isothermal calorimetry (IC) is complementary and can be used to investigate a range of processes not amenable to analysis by DSC. Typically, IC is used for longer-term stability indicating or excipient compatibility assays because both the temperature and relative humidity (RH) in the sample ampoule can be controlled. However, instrument design and configuration, such as titration, gas perfusion or ampoule-breaking (solution) calorimetry, allow quantification of more specific values, such as binding enthalpies, heats of solution and quantification of amorphous content. As ever, instrument selection, experiment design and sample preparation are critical to ensuring the relevance of any data recorded. This article reviews the use of isothermal, titration, gas-perfusion and solution calorimetry in the context of pharmaceutical development, with a focus on instrument and experimental design factors, highlighted with examples from the recent literature.

Trends in Solubility of Polymorphs

Polymorphism of drug substances has been the subject of intense investigation in the pharmaceutical field for over 40 years. Considering the multitude of reports on solubility or dissolution of polymorphs in the literature, an attempt is made in this study to answer the question: How big is the impact of polymorphism on solubility? A large number of literature reports on solubility or dissolution of polymorphs were reviewed and the data were analyzed for trends in solubility ratio of polymorphs. The general trend reveals that the ratio of polymorph solubility is typically less than 2, although occasionally higher ratios can be observed. A similar trend is also observed for anhydrate/hydrate solubility ratios, although anhydrate/hydrate solubility ratios appear to be more spread out and higher than the typical ratio for nonsolvated polymorphs. An attempt is also made in this commentary to estimate the ratio of solubilities of polymorphs from thermal data. The trend in estimated solubility ratio shows good agreement with the one observed with experimentally determined solubility values.

Neotame anhydrate polymorphs I: preparation and characterization

PURPOSE

To prepare, characterize, and compare polymorphs of neotame anhydrate.

METHODS

Neotame anhydrate polymorphs were prepared from amorphous or crystalline anhydrate by crystallization or suspension in various organic solvents, or by dehydration of neotame monohydrate. The following techniques were used for characterization: differential scanning calorimetry, thermogravimetry, hot-stage microscopy, powder X-ray diffractometry (PXRD), 13C solid-state nuclear magnetic resonance (SSNMR) spectroscopy, Fourier transform infrared (FTIR) spectroscopy, scanning electron microscopy, dynamic water vapor sorption/desorption, and density measurements.

RESULTS

Seven polymorphs (Forms A-G) of neotame anhydrate were prepared and show different thermal properties and PXRD patterns. Two enantiotropically related pairs were identified: B and C; E and A. 13C SSNMR and FTIR spectroscopy clearly distinguish between Forms A, D, F, and G, which show similar needle-shaped morphology but distinct differences in dynamic water vapor sorption/desorption and density. The 13C SSNMR chemical shifts suggest conformational polymorphism. The stability in the presence of water vapor follows the rank order, G > A > D approximately = F, which resembles the rank orders of the molar volume and of the polarity of the solvents from which they crystallized.

CONCLUSIONS

The neotame anhydrate polymorphs appear to show different molecular conformations. The less dense polymorphic structures crystallize from solvents of greater polarity and sorb water vapor less rapidly and less completely. Two enantiotropic pairs were discerned.