Chang Chun-Yi, Ju Shin-Pon, Wang Li-Fang, Chen Chien-Chia, Chuang Ying-Chen, Wu Hong-Lin, Chen Hsin-Tsung
Department of Mechanical and Electro-Mechanical Engineering, National SunYat-sen University, Kaohsiung, Taiwan, 804.
Department of Medicinal and Applied Chemistry, Kaohsiung Medical University, Kaohsiung, Taiwan, 807.
J Mol Model. 2017 May;23(5):151. doi: 10.1007/s00894-017-3294-z. Epub 2017 Apr 3.
Coarse-grained molecular dynamics (CGMD) simulation was employed to investigate how stable chondroitin sulfate-graft-polycaprolactone (CS-PCL, CP) copolymers self-assemble into micelles in an aqueous environment. Three types of CP containing low (2.4%), medium (6.3%), and high (18.7%) PCL contents (denoted L-CP, M-CP, and H-CP, respectively) in which PCL molecules consisting of 63 monomers were grafted onto each CS molecule consisting of 120 monomers were considered. L-CP and M-CP were found to display spheroidal micellar structures, while H-CP presented a rod-like structure, in agreement with previous experimental observations. In addition, the entanglement of the PCL segment increased as its molecular weight was increased. The number density distribution profiles of PCL, CS, and water molecules indicated that there were a few water molecules between the PCL core of the micelle and the water solution surrounding the micelle (in the micelle layer immediately above the core), and the number density of water in the CP micelle increased as the PCL content decreased. Using the radius of gyration, the three-dimensional conformations of the micelles were explored. When the number of CP chains was 3, H-CP adopted a long nanorod form, whereas L-CP and M-CP were roughly nanospherical. When the number of CP chains was increased beyond 3, however, the structure of L-CP changed from a nanosphere to a nanodisk. Finally, the slope of the mean square displacement profile was greatest when the molecular weight of the PCL segment was lowest, indicating that the mobilities of the CS and PCL segments are highest in L-CP. The self-diffusion coefficients of the CS and PCL segments decreased as the number of PCL segments grafted increased. Graphical abstract Morphologies of H-CP micelle.
采用粗粒度分子动力学(CGMD)模拟来研究硫酸软骨素接枝聚己内酯(CS-PCL,CP)共聚物在水性环境中如何自组装成胶束。考虑了三种类型的CP,其聚己内酯(PCL)含量分别为低(2.4%)、中(6.3%)和高(18.7%)(分别表示为L-CP、M-CP和H-CP),其中由63个单体组成的PCL分子接枝到由120个单体组成的每个CS分子上。发现L-CP和M-CP呈现球形胶束结构,而H-CP呈现棒状结构,这与先前的实验观察结果一致。此外,PCL链段的缠结随着其分子量的增加而增加。PCL、CS和水分子的数密度分布曲线表明,在胶束的PCL核与围绕胶束的水溶液之间(在核上方紧邻的胶束层中)存在少量水分子,并且CP胶束中水的数密度随着PCL含量的降低而增加。利用回转半径,探索了胶束的三维构象。当CP链的数量为3时,H-CP呈长纳米棒形式,而L-CP和M-CP大致为纳米球形。然而,当CP链的数量增加到3以上时,L-CP的结构从纳米球变为纳米盘。最后,当PCL链段的分子量最低时,均方位移曲线的斜率最大,表明CS和PCL链段在L-CP中的迁移率最高。CS和PCL链段的自扩散系数随着接枝的PCL链段数量的增加而降低。图形摘要H-CP胶束的形态。