Building‐Block Size Mediates Microporous Annealed Particle Hydrogel Tube Microenvironment Following Spinal Cord Injury

Spinal cord injury (SCI) is a life‐altering event, which often results in loss of sensory and motor function below the level of trauma. Biomaterial therapies have been widely investigated in SCI to promote directional regeneration but are often limited by their pre‐constructed size and shape. Herein, the design parameters of microporous annealed particles (MAPs) are investigated with tubular geometries that conform to the injury and direct axons across the defect to support functional recovery. MAP tubes prepared from 20‐, 40‐, and 60‐micron polyethylene glycol (PEG) beads are generated and implanted in a T9‐10 murine hemisection model of SCI. Tubes attenuate glial and fibrotic scarring, increase innate immune cell density, and reduce inflammatory phenotypes in a bead size‐dependent manner. Tubes composed of 60‐micron beads increase the cell density of the chronic macrophage response, while neutrophil infiltration and phenotypes do not deviate from those seen in controls. At 8 weeks postinjury, implantation of tubes composed of 60‐micron beads results in enhanced locomotor function, robust axonal ingrowth, and remyelination through both lumens and the inter‐tube space. Collectively, these studies demonstrate the importance of bead size in MAP construction and highlight PEG tubes as a biomaterial therapy to promote regeneration and functional recovery in SCI. Building‐block size is investigated in modular microporous annealed particle tubes for regeneration following spinal cord injury. Bead size mediates the degree of scarring and the cellular inflammatory response. Tubes allow for robust regeneration of neural populations and improve functional recovery below the level of injury. These studies present a translational, modular platform for the treatment of spinal cord injury.