A N‐Cadherin Nano‐Antagonist Hydrogel Enhances Recovery From Spinal Cord Injury by Impeding Glial Scarring

Abstract The role of glial scars in the pathophysiology of spinal cord injury (SCI) is widely recognized, as they pose physical barriers against axonal regeneration and persistent chronic inflammation by releasing cytotoxic agents, thereby impeding nerve repair. Consequently, preventing glial scarring has emerged as an important therapeutic objective in SCI management. Following SCI, astrocytes undergo a phenotypic transition into scar‐forming astrocytes, which critically depends on the activation of inflammatory responses and the integrin‐N‐cadherin pathway. To explore improved SCI treatment, a nano‐antagonist hydrogel (Nano‐ant Gel), comprising N‐cadherin nano‐antagonists and a polyphenol hydrogel designed to inhibit glial scarring by mitigating inflammatory response and modulating astrocyte behavior, thereby facilitating spinal cord‐injury repair, is developed and characterized. The hydrogel exhibits notable anti‐inflammatory properties, specific calcium ion‐adsorption capabilities, and antagonistic effects against N‐cadherin, effectively impeding the formation and aggregation of scar‐forming astrocytes. Its efficacy is comprehensively assessed using a model of contusive SCI, with which it effectively inhibits glial scar formation and promotes axonal regeneration. Notably, the Nano‐ant Gel significantly improves the locomotor functions of mice with SCI, suggesting that it represents a promising approach for treating the condition.