Macrophages are rapidly activated and polarized toward the M1 phenotype after spinal cord injury (SCI), and inhibiting M1-like macrophages has emerged as a promising SCI treatment approach. Metalloregulatory proteins, which sense specific metal ions with high affinity and specificity, play a critical role in immune regulation. Here, we screened various bioactive metal ions associated with metalloregulatory proteins and discovered that Zn2+ and Mn2+ effectively suppressed M1 polarization. Based on these findings, mildly alkaline ZnMn-based layered double hydroxides (ZnMn-LDHs) self-assembled from Zn2+ coordinated with Mn2+ were developed to inhibit M1-like macrophages. ZnMn-LDHs effectively neutralized the acidic environment and promoted the expression of metalloregulatory proteins, including metallothionein (MT), superoxide dismutase 1 (SOD1), and superoxide dismutase 2 (SOD2), thereby eliciting robust M1-like macrophage inhibition. More importantly, nerve growth factor (NGF) released by macrophages following the regulation by ZnMn-LDHs promoted the elongation and spreading of Schwann cells. By integrating ZnMn-LDHs with silk fibroin (SF), ZnMn@SF injectable hydrogels were constructed for SCI repair. An in vivo animal model further revealed the excellent anti-inflammatory effects of the ZnMn@SF hydrogels in treating SCI, which promoted functional recovery. Our findings underscore the importance of metalloregulatory proteins regulated by metal ions in inhibiting M1-like macrophages, providing a promising therapeutic strategy for SCI treatment.
Keywords: hydrogels; layered double hydroxides; metal ions; metalloregulatory protein; spinal cord injury.