Spinal cord injuries in humans and in other mammals are never followed by regrowth. In recent years, considerable progress has been made in analyzing mechanisms that promote and inhibit regeneration. The focus of this review is changes that occur in the transition period in development when the central nervous system (CNS) changes from being able to regenerate to the adult state of failure. In our experiments we have used the neonatal opossum (Monodelphis domestica), which corresponds to a 14-day embryonic rat or mouse. The CNS isolated from an opossum pup and maintained in culture shows dramatic regeneration. Fibers grow through and beyond lesions and reform synaptic connections with their targets. Similarly, anesthetized neonatal pups attached to the mother recover the ability to walk after complete spinal cord transection. Although the CNS isolated from a 9-day-old animal will regenerate in vitro, CNS from a 12-day-old will not. This is the stage at which glial cells in the CNS develop. Present research is devoted toward molecular screening to determine which growth-promoting molecules decrease during development, which inhibitory molecules increase, and which receptors on growing axons become altered. Despite progress in many laboratories, major hurdles must be overcome before patients can hope to be treated. Nevertheless, the picture today is not as discouraging as it was: one can think of strategies for research on spinal cord injury so as to promote regeneration and restore function.