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Fabrication of an electroconductive, flexible, and soft poly(3,4-ethylenedioxythiophene)–thermoplastic polyurethane hybrid scaffold by in situ vapor phase polymerization

Park, Jin Seul, Kim, Boram, Lee, Byong-Taek, ChoiThese authors contributed equally to this work., Jong Seob, Yim, Jin-Heong
Journal of materials chemistry 2018 v.6 no.24 pp. 4082-4088
biocompatibility, brittleness, cell culture, cell viability, confocal microscopy, electrical resistance, electrical treatment, modulus of elasticity, muscles, neurons, polymerization, polyurethanes, silica, thermoplastics, vapors
The inherent insolubility and brittleness of poly(3,4-ethylenedioxythiophene) (PEDOT) reduce its processability and practical applicability. Herein, we use in situ vapor phase polymerization (VPP) of 3,4-ethylenedioxythiophene (EDOT) on an oxidant-impregnated thermoplastic polyurethane (TPU) matrix comprising a three-dimensional silica particle assembly to produce a soft, flexible, and conductive TPU–PEDOT hybrid scaffold. The selective removal of silica yielded a highly porous (∼95%) skeletal structure, with the effective penetration, diffusion, and polymerization of EDOT resulting in uniform PEDOT formation both on the surface and the inner side of the TPU matrix. The mechanical and electrical properties of the obtained scaffold were investigated by bending, compression testing, and stress–strain and electrical measurements. The electrical resistance of the scaffold equaled 17 kΩ and did not change after ∼500-fold bending, whereas the observed elastic modulus was much lower (300 kPa) than that of TPU (3.3 MPa). In vitro biocompatibility was investigated by MC3T3-E1 cell culturing with cell viability evaluated using the WST assay and cell morphology examined by confocal microscopy. Thus, the soft and flexible TPU–PEDOT hybrid scaffold produced by VPP might be practically useful, implying that this preliminary investigation needs to be extended to study the behavior of muscle and nerve cells under electrical stimulation.