Purpose: This study aimed to investigate the physicochemical factors contributing to stable co-amorphous formations and to design a co-former selection strategy.
Methods: Non-steroidal inflammatory drugs were used as main components and/or co-formers. Physical mixtures of the materials were melted. Co-amorphization was characterized by the inhibition effect of the co-former on crystallization of the main component from the undercooled melt. The contribution of physicochemical factors to the co-amorphous formation was analyzed by multivariate analysis. Co-amorphous samples prepared by melting were subjected to thermal and spectroscopic analyses and the isothermal crystallization test.
Results: Naproxen (NAP) was employed as the main component having a rapid crystallization tendency. Some materials used as the co-former inhibited the crystallization of amorphous NAP; decreasing melting temperatures of the components was an indicator of co-amorphization. The contribution of some physicochemical features (e.g., crystallization tendency, glass transition temperature (Tg)/melting temperature and molecular flexibility) of the co-formers to a co-amorphous formation was suggested by multivariate analysis. Deviation of the glass transition temperature from the theoretical value and changes in the infrared spectra of the co-amorphous samples were correlated with intermolecular interaction. The crystallization behaviors of the co-amorphous samples depended on their Tg.
Conclusions: The results showed a relationship between stable co-amorphous formation and the physicochemical features of the components, which should inform efficient co-former selection to design stable co-amorphous formations.
Keywords: amorphous; co-amorphous; crystallization; glass transition temperature; intermolecular interaction; multivariate analysis.