Equilibrium solubility, solvent effect, and equation correlations of cyclosporine in twenty mono solvents and four binary mixtures

In this study, the solid-liquid equilibrium solubility of cyclosporine in 20 pure solvents and four binary mixtures at 298.15 K were determined using shake-flask technique. Solid-state characterization exhibited that no solvate formation or polymorphic transformation occurred during the dissolution of cyclosporine in any of the solvent systems investigated. The experimental solubilities of cyclosporine in 20 pure mono solvents were ranked as follows: DEGME (2.21 x 10(-1)) > ethanol (1.22 x 10(-1)) > NMP (1.15 x 10(-1)) = 1-butanol (1.15 x 10(-1)) > dichloromethane (1.07 x 10(-1)) > acetonitrile (1.02 x 10(-1)) > PEG 200 (9.78 x 10(-2)) > PEG 300 (9.12 x 10(-2)) > chloroform (8.98 x 10(-2)) > PEG 400 (8.11 x 10(-2)) > DMF (7.65 x 10(-2)) > 2-propanol (7.09 x 10(-2)) > 1-propanol (6.57 x 10(-2)) > methanol (6.14 x 10(-2)) > propylene glycol (6.08 x 10(-2)) > tetrahydrofuran (4.69 x 10(-2)) > DMSO (2.64 x 10(-2)) > acetone (1.28 x 10(-2)) > glycerol (1.35 x 10(-5)) > water (4.29 x 10(-7)). In the four binary solvents (DEGME + water, PEG 200 + water, PEG 300 + water, and PEG 400 + water), the mole fraction solubility of cyclosporine increased with increasing mass fractions of the four different organic solvents. Based on the Kamlet-Taft linear solvation energy relationship (KAT-LSER) model, the solubility of cyclosporine was mainly affected by the self-cohesiveness of the solvent, which is related to the interaction between the solvent and the solvent. Additionally, the solubility parameter was used to explain and understand the solubility of cyclosporine in four different binary solvents. To correlate the solubility data of cyclosporine, two models (the Yalkowsky Log-Linear and simplified CNIBS/R-K models) were applied. The calculated data based on two mathematical models and experimental mole fraction solubility data for cyclosporine could provide information for the separation, extraction, purification, crystallization, and selection of suitable a solvent system.