Anderson, Mark A.Squair, Jordan W.Gautier, MatthieuHutson, Thomas H.Kathe, ClaudiaBarraud, QuentinBloch, JocelyneCourtine, Gregoire2022-12-052022-12-052022-12-052022-11-1710.1038/s41593-022-01196-1https://infoscience.epfl.ch/handle/20.500.14299/193010WOS:000884942400003The authors summarize changes in circuits after spinal cord injury and current strategies to target these circuits in order to improve recovery, but also advocate for new concepts of reorganizing circuits informed by multi-omic single-cell atlases.A spinal cord injury disrupts communication between the brain and the circuits in the spinal cord that regulate neurological functions. The consequences are permanent paralysis, loss of sensation and debilitating dysautonomia. However, the majority of circuits located above and below the injury remain anatomically intact, and these circuits can reorganize naturally to improve function. In addition, various neuromodulation therapies have tapped into these processes to further augment recovery. Emerging research is illuminating the requirements to reconstitute damaged circuits. Here, we summarize these natural and targeted reorganizations of circuits after a spinal cord injury. We also advocate for new concepts of reorganizing circuits informed by multi-omic single-cell atlases of recovery from injury. These atlases will uncover the molecular logic that governs the selection of 'recovery-organizing' neuronal subpopulations, and are poised to herald a new era in spinal cord medicine.NeurosciencesNeurosciences & Neurologycorticospinal tract lesionneural stem-cellsfunctional recoveryaxon regenerationelectrical-stimulationcritical regulatorfibroblasts formmotor recoveryscar formationfibrotic scartext::journal::journal article::review article