Elucidating the Complex Phase Behavior of a Cocrystal System Containing Two APIs and One Coformer

A method has been developed to determine the phase behavior of a cocrystal system that contains two APIs (active pharmaceutical ingredients) and one coformer. Isoniazid, nicotinamide, and succinic acid (denoted as A, B, and C, respectively, hereafter) can form a ternary cocrystal ABC, along with two...

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Veröffentlicht in:Crystal growth & design 2019-01, Vol.19 (1), p.157-165
Hauptverfasser: Abundo, Maria Paulene, Yu, Zai-Qun, Chow, Pui Shan, Tan, Reginald B. H
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Yu, Zai-Qun
Chow, Pui Shan
Tan, Reginald B. H
description A method has been developed to determine the phase behavior of a cocrystal system that contains two APIs (active pharmaceutical ingredients) and one coformer. Isoniazid, nicotinamide, and succinic acid (denoted as A, B, and C, respectively, hereafter) can form a ternary cocrystal ABC, along with two binary cocrystals, A2C and B2C, making the phase behavior very complex because of a variety of eutectic points. The phase diagram of such a complex system has never been reported. During experiment, solids of A, B, C, or A2C were added in lots to suspensions of pure ABC cocrystal or a mixture of ABC and another solid phase. Attenuated total reflectance Fourier transform spectroscopy (ATR-FTIR) was used to measure the concentrations of A, B, and C during the process. The constitution of solid phases in suspension at each equilibrium point was determined in a real-time manner by performing mass balance between the liquid and solid phase. Multiple eutectic points in equilibrium with a mixture of ABC and A2C, a mixture of ABC and B2C and a mixture of ABC and A, respectively, were obtained. In the 3D phase diagram spanned by the concentrations of A, B and C, these eutectic points constitute the boundary for a surface where pure ternary cocrystal can be obtained. Eutectic points in equilibrium with three solid phases simultaneously were not reached. With such a phase diagram, a cocrystallization process can be designed that thermodynamically guarantees the production of pure ABC cocrystal. In addition, practical issues and resolutions in applying ATR-FTIR to phase diagram measurement were discussed.
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