Worm-like vesicles prepared by photo nitroxide-mediated controlled/living radical polymerizationinduced self-assembly

4^th International Conference on Polymer Chemistry

June 25-27, 2018 | Stockholm, Sweden

Eri Yoshida

Toyohashi University of Technology, Japan

Scientific Tracks Abstracts: J Material Sci Eng

Abstract :

Worm-like organisms are often observed as baculiform cells and tubular organelles. Worm-like vesicles are regarded as artificial models of biomembrane for these cells and organisms and are expected as new carriers for drug and gene delivery. This paper describes the synthesis of worm-like vesicles consisting of amphiphilic poly(methacrylic acid)-blockpoly( methyl methacrylate-random-methacrylic acid), PMA-b-P(MMA-r-MA), through the photo nitroxide-mediated controlled/living radical polymerization (photo NMP)-induced self-assembly. The mechanism of the formation and stimuliresponsive behavior of the worm-like vesicles are also described. The worm-like vesicles were prepared by the photo NMPinduced self-assembly of PMA-b-P(MMA-r-MA) using 4-methoxy-2,2,6,6-tetramethylpiperidine-1-oxyl in an aqueous methanol solution. It was found that the polymerization had the living nature based on the linear correlation between the molecular weight and monomer conversion. The copolymer during the early stage of the polymerization produced cup-like vesicles with the thin and flexible bilayer including some holes in the surface. As the hydrophobic P(MMA-r-MA) block chain was extended by the polymerization progress, the cup-like vesicles were transformed into spherical vesicles, followed by worm-like vesicles due to the incorporation of the spherical vesicles. The worm-like vesicles had the major axis of 3.41 �¼m and minor axis of 0.437 �¼m on average. The vesicles were sensitive to temperature and transformed into spherical or shorter worm-like vesicles and finally into a fused plane by a temperature increase. The worm-like vesicles were restored by decreasing the temperature through branched tubules. The worm-like vesicles were also sensitive to pH and salt concentration and more stable than spherical vesicles consisting of PMA-b-P(MMA-r-MA).

Biography :

Eri Yoshida has completed her PhD in Polymer Engineering from Tokyo Institute of Technology. She has joined Kyoto Institute of Technology as an Assistant Professor. She was also a Visiting Scientist at the University of North Carolina at Chapel Hill. She is an Associate Professor at Toyohashi University of Technology. She has published more than 100 papers in international journals and has 24 patents. She has been serving as an Editorial Board Member of some international journals.

E-mail: eyoshida@ens.tut.ac.jp