Computational study of metformin hydrochloride nucleation in hydroxylic solvents: Experimental kinetics and DFT simulation.

Metformin hydrochloride (MET-HCl) was applied as a model compound to investigate the nucleation behavior in four hydroxylic solvents based on the experimental and simulated methods. Over 320 induction time experiments were measured in four solvents, and the induction time increased in the order: water < methanol < ethanol < n-propanol. The metastable zone widths were determined with different cooling rates and saturation temperatures. According to classical nucleation theory, the nucleation kinetics and thermodynamic parameters (interfacial energy, critical nucleus size and Gibbs free energy) were estimated. The result indicates that the nucleation rate of MET-HCl in water was highest among four solvents. The density functional theory (DFT) calculation was applied to reveal the solvent-solute interaction in crystal nucleation, showing the binding energies increased in the order: water < methanol < ethanol < n-propanol. The simulation results combined with experimental data suggested that the stronger the interactions of solvent-solute molecules, the more difficult the nucleation becomes.

A novel cocrystal of metformin hydrochloride with citric acid: Systematic synthesis and computational simulation.

Pharmaceutical cocrystals have matured into an effective technique for tuning the physicochemical and mechanical properties of drugs in solid form simultaneously. Herein, in order to provide a novel cocrystal form of oral medicine metformin hydrochloride (MH), citric acid (CA) was selected as an efficient ligand after screening a variety of inorganic and organic acids. Thus, based on the principle of crystal engineering, we report a novel cocrystal: metformin hydrochloride - citric acid (MHCA) after the systematic screening, which was experimentally proved to be constituted with 1:1 stoichiometry. Compared with pure MH, MHCA has been proved higher solubility in water, methanol, and ethanol from 283.15 to 313.15 K. Through single-crystal X-ray diffraction (SC-XRD), the particular molecular structure of MHCA has been determined as the orthorhombic system and Pbca space group. Besides, the binding model of MH-CA was built for investigating the binding energy and stability between two components at 278, 298, and 318 K, which were found to be essential for the prediction and analysis of cocrystals. The contribution of different intermolecular interactions and the strength of molecular packing in the cocrystal also have been investigated by Hirshfeld surface analysis. It was found that the cocrystal structure was mainly stabilized by intermolecular hydrogen bonds existing as N-H···O between components, which indicated that the diffusion-combination trend of molecules enhanced the regular array of cocrystal. The results revealed that the molecules of MH and CA formed supramolecular cocrystals mainly induced by hydrogen bonds after passive contacts, such as co-crystallization or grind.