Conductive ionic liquid/chitosan hydrogels for neuronal cell differentiation

Abstract

To regulate cell behaviors and promote nerve function recovery, three-dimensional (3D) conductive hydrogel can transmit intercellular electrical signals, and effectively provide the cell survival environment. However, producing hydrogels with simultaneous high conductivity, favorable biocompatibility, and tissue-matching properties remains a challenge for spinal cord injury (SCI) treatment. Here, a conductive, multifunctional, and biocompatible VPImBF4 ionic liquid (IL) with photosensitive chitosan-based hydrogel ([email protected]) is developed. The [email protected] hydrogel exhibits a 3D microporous structure that could maintain cell viability and improve cell growth. Elastic modulus, conductivity, and biodegradability of the [email protected] hydrogels are investigated with tissue-matching mechanical properties. The [email protected] conductive hydrogels synergistically enhance neuronal cell proliferation and promote neuronal cells differentiation via upregulates synapse gene (Tubulin β3, GAP43, Synaptophysin) expression. Furthermore, in vivo studies of the [email protected] conductive hydrogels as implants demonstrate low-inflammation and neovascularize promotion and appropriate biodegradable properties. The developed [email protected] conductive hydrogel is a promising therapeutic scaffold biomaterial for SCI repair.