ENHANCED NEURONAL REGENERATION BY RETINOIC ACID OF MURINE DORSAL-ROOT GANGLIA AND OF FETAL MURINE AND HUMAN SPINAL-CORD INVITRO

This study demonstrates that retinoic acid (RA), an active metabolite of vitamin A, can act to enhance regeneration of neurites, at physiologic concentrations, in vitro. Explanted fragments of mouse dorsal root ganglia (DRG) and mouse and human spinal cord (SC) were maintained, in vitro, for periods up to 11 d. Murine DRG neurons were exposed to RA concentrations ranging from 100-mu-M to 1 nM, whereas neurons within murine and human SC explants were exposed to 10-mu-M to 10 nM RA. Results show that RA significantly (P < 0.001) increases mean neurite length but not neurite number. Specifically, murine DRG neurons showed increases in mean neurite length of 30.7% with individual explants showing increases of up to 133.5%. Murine and human SC showed mean enhancements of 43.4 and 58.1%, respectively, but did so at lower concentrations of RA. The results indicate that RA may play a potentially critical role in neuronal regeneration.