An electroconductive hydrogel with injectable and self-healing properties accelerates peripheral nerve regeneration and motor functional recovery

Abstract

Peripheral nerve regeneration and functional recovery are slow due to disruption of bioelectrical signal transmission. As a new therapeutic strategy, conductive hydrogels have been shown to promote the regeneration of electroactive tissue, especially nerve tissue. However, conventional conductive hydrogels made of physically doped conductive particles suffer from fragility, agglomeration, poor durability, and discontinuous transmission of electrical signals, severely limiting the migration of Schwann cells (SCs) and the remyelination of axons. Herein, a novel water-soluble conductive material was synthesized by grafting polyaniline (PANI) onto carboxymethyl chitosan (CMCS). Dual cross-linked hydrogels with injectable, self-healing, and conductive properties were created by adding CMCS-PANI (CP) to the dynamic gel network generated by the Schiff base reaction between aldehyde-based hyaluronic acid (ALHA) and CMCS. The prepared self-healing ALHA/CMCS/CP (ACCP) hydrogel had good biocompatibility, elastic modulus, and electrical conductivity that matched the sciatic nerve. The in vitro experiments indicated that ACCP3 (3 wt% CP) promoted the proliferation and migration of the SCs. Injection of ACCP3 into the crush injury site of the sciatic nerve reduced tissue resistivity, increased nerve conduction velocity, decreased the sciatic nerve functional index, enhanced the expression of neuronal axon-specific proteins, induced axon extension and remyelination, and prevented muscle denervation atrophy. Overall, the injectable self-healing conductive ACCP3 hydrogel, as a safe and effective neural tissue substitute, opens up a new way for the treatment of peripheral nerve injury and has potential clinical application.