School of Pharmacy & School of Biological and Food Engineering, Changzhou University, Changzhou 213164, PR China; School of Traditional Chinese Pharmacy, China Pharmaceutical University, Nanjing 211198, PR China; Changzhou Pharmaceutical Factory Co., LTD, Changzhou 213018, PR China.
School of Pharmacy & School of Biological and Food Engineering, Changzhou University, Changzhou 213164, PR China.
J Pharm Sci. 2024 Jul;113(7):1874-1884. doi: 10.1016/j.xphs.2024.02.009. Epub 2024 Feb 12.
Intermolecular interactions between drug and co-former are crucial in the formation, release and physical stability of co-amorphous system. However, the interactions remain difficult to investigate with only experimental tools. In this study, intermolecular interactions of co-amorphous curcumin-piperine (i.e., CUR-PIP CM) during formation, dissolution and storage were explored by integrating experimental and modeling techniques. The formed CUR-PIP CM exhibited the strong hydrogen bond interaction between the phenolic OH group of CUR and the CO group of PIP as confirmed by FTIR, ss C NMR and molecular dynamics (MD) simulation. In comparison to crystalline CUR, crystalline PIP and their physical mixture, CUR-PIP CM performed significantly increased dissolution accompanied by the synchronized release of CUR and PIP, which arose from the greater interaction energy of HO-CUR molecules and HO-PIP molecules than CUR-PIP molecules, breaking the hydrogen bond between CUR and PIP molecules, and then causing a pair-wise solvation of CUR-PIP CM at the molecular level. Furthermore, the stronger intermolecular interaction between CUR and PIP was revealed by higher binding energy of CUR-PIP molecules, which contributed to the excellent physical stability of CUR-PIP CM over amorphous CUR or PIP. The study provides a unique insight into the formation, release and stability of co-amorphous system from MD perspective. Meanwhile, this integrated technique can be used as a practical methodology for the future design of co-amorphous formulations.
药物与共晶形成剂之间的分子间相互作用对共无定形系统的形成、释放和物理稳定性至关重要。然而,仅使用实验工具,这些相互作用仍然难以研究。在这项研究中,通过整合实验和建模技术,研究了共无定形姜黄素-胡椒碱(即 CUR-PIP CM)在形成、溶解和储存过程中的分子间相互作用。FTIR、ss C NMR 和分子动力学(MD)模拟证实,形成的 CUR-PIP CM 表现出 CUR 的酚羟基和 PIP 的 CO 基团之间的强氢键相互作用。与晶态 CUR、晶态 PIP 及其物理混合物相比,CUR-PIP CM 表现出明显增加的溶解,同时 CUR 和 PIP 同步释放,这是由于 HO-CUR 分子和 HO-PIP 分子之间的相互作用能大于 CUR-PIP 分子,打破了 CUR 和 PIP 分子之间的氢键,从而导致 CUR-PIP CM 在分子水平上的成对溶剂化。此外,通过 CUR-PIP 分子更高的结合能,揭示了 CUR 和 PIP 之间更强的分子间相互作用,这有助于 CUR-PIP CM 具有优于无定形 CUR 或 PIP 的优异物理稳定性。该研究从 MD 角度提供了对共无定形系统形成、释放和稳定性的独特见解。同时,这种集成技术可以用作未来共无定形制剂设计的实用方法。
