Improving the Physicochemical and Biopharmaceutical Properties of Active Pharmaceutical Ingredients Derived from Traditional Chinese Medicine through Cocrystal Engineering.

Active pharmaceutical ingredients (APIs) extracted and isolated from traditional Chinese medicines (TCMs) are of interest for drug development due to their wide range of biological activities. However, the overwhelming majority of APIs in TCMs (T-APIs), including flavonoids, terpenoids, alkaloids and phenolic acids, are limited by their poor physicochemical and biopharmaceutical properties, such as solubility, dissolution performance, stability and tabletability for drug development. Cocrystallization of these T-APIs with coformers offers unique advantages to modulate physicochemical properties of these drugs without compromising the therapeutic benefits by non-covalent interactions. This review provides a comprehensive overview of current challenges, applications, and future directions of T-API cocrystals, including cocrystal designs, preparation methods, modifications and corresponding mechanisms of physicochemical and biopharmaceutical properties. Moreover, a variety of studies are presented to elucidate the relationship between the crystal structures of cocrystals and their resulting properties, along with the underlying mechanism for such changes. It is believed that a comprehensive understanding of cocrystal engineering could contribute to the development of more bioactive natural compounds into new drugs.

Impact of cocrystal solution-state stability on cocrystal dissociation and polymorphic drug recrystallization during dissolution.

The present study aimed to investigate how cocrystal solution-state stability may affect the polymorphic drug formation and transition during dissolution. In this work, curcumin-resorcinol (CUR-RES), curcumin-hydroquinone (CUR-HYQ) and curcumin-phloroglucinol (CUR-PHL) cocrystals were employed for dissolution studies in three buffer systems to study the effects of solvent and cocrystal thermodynamic stability. The undissolved solids were collected at designed time points and characterized by powder X-ray diffraction, differential scanning calorimetry and scanning electron microscopy. In pH 1.2 buffer, three cocrystals generated > 94% of metastable CUR form III with trace amount of stable CUR form I, while the phase purity of CUR form III recrystallized from buffers containing ethanol (EtOH) were decreased dramatically. For the same cocrystal, the cocrystal form maintained longer in the pH 1.2 buffer when compared with buffers containing EtOH. The phase purity of recrystallized CUR form III in the metastable cocrystal systems followed a linear relationship against CUR solubility, while the thermodynamically stable cocrystal resulted in a non-linear relationship. Due to different intermolecular interactions analyzed by 1H NMR, the stable cocrystal required a higher supersaturation level to precipitate pure CUR form III, in comparison to two metastable cocrystals. Our study offers important insights into mitigating the risk of recrystallization of drug polymorphs during cocrystal dissolution and demonstrates the potential use of cocrystals for drug polymorph preparation, both of which are crucial to the pharmaceutical cocrystal development and reformulation of existing drugs.

Effects of the Glass-Forming Ability and Annealing Conditions on Cocrystallization Behaviors via Rapid Solvent Removal: A Case Study of Voriconazole.

The kinetic entrapment of molecules in an amorphous phase is a common obstacle to cocrystal screening using rapid solvent removal, especially for drugs with a moderate or high glass-forming ability (GFA). The aim of this study was to elucidate the effects of the coformer's GFA and annealing conditions on the nature of amorphous phase transformation to the cocrystal counterpart. Attempts were made to cocrystallize voriconazole (VRC) with four structural analogues, namely fumaric acid (FUM), tartaric acid (TAR), malic acid (MAL), and maleic acid (MAE). The overall GFA of VRC binary systems increased with decreasing glass transition temperatures (Tgs) of these diacids, which appeared as a critical parameter for predicting the cocrystallization propensity such that a high-Tg coformer is more desirable. A new 1:1 VRC-TAR cocrystal was successfully produced via a supercooled-mediated re-cocrystallization process, and characterized by PXRD, DSC, and FTIR. The cocrystal purity against the annealing temperature displayed a bell-shaped curve, with a threshold at 40 °C. The isothermal phase purity improved with annealing and adhered to the Kolmogorov-Johnson-Mehl-Avrami kinetics. The superior dissolution behavior of the VRC-TAR cocrystal could minimize VRC precipitation upon gastric emptying. This study offers a simple but useful guide for efficient cocrystal screening based on the Tg of structurally similar coformers, annealing temperature, and time.