A conductive piezoelectric hydrogel combined with perampanel and wireless electrical stimulation for spinal cord injury repair

Abstract

After experiencing spinal cord injury (SCI), the interruption of electrical signal transmission impedes both nerve regeneration and functional recovery. Despite its potential as a treatment for spinal cord injury, intrathecal electrical stimulation (ES) is hindered by the risk of infection and the need for a subsequent operation to remove the tethered electrical interface, thereby severely limiting its effectiveness and clinical applicability. Herein, we constructed a conductive piezoelectric hydrogel (SFBP/PER) with ultrasound-triggered wireless ES capability and satisfied conductivity for SCI regeneration. The fabrication process involved the integration of perampanel and polypyrrole-modified BaTiO3 nanoparticles into silk fibroin, followed by enzymatic crosslinking at physiological temperature. We demonstrate that the SFBP/PER hydrogel exhibits anti-glutamate excitotoxicity and antioxidative capabilities in vitro. In vivo, experiments revealed that the SFBP/PER hydrogel significantly enhanced recovery of SCI rats by mitigating oxidative stress, apoptosis, and inflammation, reducing lesion cavities, enhancing remyelination, and promoting the regeneration of functional neurons. This study presents a novel approach utilizing a conductive piezoelectric hydrogel system for in vivo ES in tissue engineering applications.