2016年发表论文

[1] Cai S, Zeng, C, Zhang, N, Li, J, Meyer, M, Fink, RH, Shi, D, Ren, J. Enhanced mechanical properties of PLA/PLAE blends via well-dispersed and compatilized nanostructures in the matrix. RSC Advances 2016, 6(30): 25531-25540.

[2] Lin C, Lou, B, Zhao, J, Jin, R, Zhao, P, Li, J, Ren, J. Self-assembled micelles of PEG-poly(disulfide carbamate amine) copolymers for intracellular dual-responsive drug delivery. Journal of Materials Chemistry B 2016, 4(5): 902-909.

[3] Ye L, Ren, J, Cai, S-y, Wang, Z-g, Li, J-b. Poly(lactic acid) nanocomposites with improved flame retardancy and impact strength by combining of phosphinates and organoclay. Chinese Journal of Polymer Science 2016, 34(6): 785-796.

[4] Gao XL, Wang, GM, Shi, T, Shao, ZH, Zhao, P, Shi, DL, Ren, J, Lin, C, Wang, PJ. Biodegradable gadolinium-chelated cationic poly(urethane amide) copolymers for gene transfection and magnetic resonance imaging. Materials Science & Engineering C-Materials for Biological Applications 2016, 65: 181-187.

[5] Gu S-y, Gao, X-f, Jin, S-p, Liu, Y-l. Biodegradable shape memory polyurethanes with controllable trigger temperature. Chinese Journal of Polymer Science 2016, 34(6): 720-729.

[6] Huang DX, Lin, C, Wen, XJ, Gu, SY, Zhao, P. A Potential Nanofiber Membrane Device for Filling Surgical Residual Cavity to Prevent Glioma Recurrence and Improve Local Neural Tissue Reconstruction. Plos One 2016, 11(8): 15.

[7] Gu SY, Jin, SP, Gao, XF, Mu, J. Polylactide-based polyurethane shape memory nanocomposites (Fe3O4/PLAUs) with fast magnetic responsiveness. Smart Materials and Structures 2016, 25(5): 12.

[8] M. Tang, H. Q. Dong, Y. Y. Li, T. B. Ren. Harnessing the PEG-cleavable strategy to balance cytotoxicity, intracellular release and the therapeutic effect of dendrigraft poly-L-lysine for cancer gene therapy. Journal of Materials Chemistry B 2016, 4(7): 1284-1295.

[9] Xiaolong Gao, Gangmin Wang, Ting Shi, Zhihong Shao, Peng Zhao, Donglu Shi, Jie Ren, Chao Lin, Peijun Wang. Biodegradable gadolinium-chelated cationic poly(urethane amide) copolymers for gene transfection and magnetic resonance imaging. Materials Science & Engineering C-Materials for Biological Applications 2016, 65: 181-187.

[10] Yuan H, Chi, H, Yuan, WZ. A star-shaped amphiphilic block copolymer with dual responses: synthesis, crystallization, self-assembly, redox and LCST-UCST thermoresponsive transition. Polymer Chemistry 2016, 7(30): 4901-4911.

[11] Yuan WZ, Chen, XN. Star-shaped and star-block polymers with a porphyrin core: from LCST-UCST thermoresponsive transition to tunable self-assembly behaviour and fluorescence performance. RSC Advances 2016, 6(8): 6802-6810.

[12] Yuan H, Chi, H, Yuan, WZ. Ethyl cellulose amphiphilic graft copolymers with LCST-UCST transition: Opposite self-assembly behavior, hydrophilic-hydrophobic surface and tunable crystalline morphologies. Carbohydrate Polymers 2016, 147: 261-271.

[13] Yuan WZ, Huang, WW, Zou, H. Synthesis and properties of CO2-responsive copolymer by the combination of reversible addition-fragmentation chain transfer polymerization and click chemistry. Polymer Bulletin 2016, 73(8): 2199-2210.

[14] Yuan WZ, Zou, H, Shen, J. Amphiphilic graft copolymers with ethyl cellulose backbone: Synthesis, self-assembly and tunable temperature-CO2 response. Carbohydrate Polymers 2016, 136: 216-223.

 

地址:上海市嘉定区曹安公路4800号 Copyright © 2018 纳米与高分子生物材料研究所 版权所有