Recent advances in nanotechnology for repairing spinal cord injuries.

Spinal cord injury (SCI) remains a formidable clinical challenge with limited therapeutic options. Recent advances in nanotechnology have introduced paradigm-shifting strategies that transcend the limitations of traditional treatments by offering precision, controllability, and multifunctionality in modulating the hostile post-injury microenvironment. This review systematically summarizes nanotechnology-based therapeutic approaches for SCI, including cell-based nanotherapeutics, nanogels/hydrogels, nano-engineered materials, and combinatorial strategies. We emphasize the synergistic design of multifunctional nanoplatforms that integrate neuroprotection, immune modulation, antioxidative capacity, and axonal regeneration within a single system. Special attention is given to microenvironment-responsive smart materials capable of dynamic therapeutic delivery in response to pathological cues. We critically analyze the challenges of clinical translation, such as the need for standardized safety evaluation and personalized therapeutic dosing, and explore emerging solutions including AI-driven nanocarrier design and organoid-based validation. By integrating interdisciplinary innovations, nanotherapies represent an irreplaceable therapeutic paradigm with the potential to achieve spatiotemporal precision and sustained regenerative support for SCI repair.