Róisín M. Owens, Chrysanthi-Maria Moysidou, Michael De Volder, Akhila K. Jayaram, Ellasia Tan, Ji-Seon Kim, Charalampos Pitsalidis, Pitsalidis, Charalampos [0000-0003-3978-9865], Moysidou, Chrysanthi-Maria [0000-0001-9809-2764], De Volder, Michael [0000-0003-1955-2270], Owens, Roisin [0000-0001-7856-2108], Apollo - University of Cambridge Repository, and Engineering and Physical Sciences Research Council
Conducting polymer scaffolds combine the soft-porous structures of scaffolds with the electrical properties of conducting polymers. In most cases, such functional systems are developed by combining an insulating scaffold matrix with electrically conducting materials in a 3D hybrid network. However, issues arising from the poor electronic properties of such hybrid systems, hinder their application in many areas. This work reports on the design of a 3D electroactive scaffold, which is free of an insulating matrix. These 3D polymer constructs comprise of a water soluble conducting polymer (PEDOT:PSS) and multi-walled carbon nanotubes (MWCNTs). The insertion of the MWCNTs in the 3D polymer matrix directly contributes to the electron transport efficiency, resulting in a 7-fold decrease in resistivity values. The distribution of CNTs, as characterized by SEM and Raman spectroscopy, further define the micro- and nano-structural topography while providing active sites for protein attachment, thereby rendering the system suitable for biological/sensing applications. The resulting scaffolds, combine high porosity, mechanical stability and excellent conducting properties, thus can be suitable for a variety of applications ranging from tissue engineering and biomedical devices to (bio-) energy storage.