Preliminary data suggests that spinal cord neural networks that contain intact sensory pathways, which include dorsal root ganglia (DRG) and thermal transient receptor potential (TRP) channels are more resilient to gradual temperature changes than isolated preparations. Moreover, how acute temperature changes affect mammalian CPG-driven motor activity remains uncertain. We studied how acute and gradual temperature changes impact the stability of motor networks with or without sensory pathways. More specifically, we aim to investigate: 1. the difference between how acute temperature changes versus gradual temperature changes can have an impact on the stability and robustness of motor networks; 2. how sensory inputs and TRP channels affect the adaptation of spinal central pattern generator (CPG) networks to changes in temperature. We compared changes in motor neuron bursting activity between ventral L2 and L5 roots of neonatal mouse spinal cord preparations under acute (from 20℃ directly to 29℃) and gradual (gradually from 20℃, to 23℃, to 26℃, and to 29℃) temperature change conditions. Spinal cord preparations both with and without DRGs were compared. We found that the locomotor activities were increased as temperature increase under both chronic and acute changes; however, spinal cord preparations without intact DRG showed activities with less stable phasing and more overall motor bursting variability compared to those preparations with intact DRGs (on L3, L4, and L5 spinal levels). Our results suggest that the lumbar spinal locomotor CPG network activity shows more susceptibility and less adaptation to temperature changes in the absence of sensory feedback provided by DRG sensory afferents. Further studies will be conducted in the presence of TRP channel blockers to preparations with DRGs to confirm the potential compensatory role that sensory feedback afferents convey to spinal CPG networks.
This research is funded by the Student Faculty Research Grant Fellowship via a NIH INBRE grant entitled amp;ldquo;Comparative Functional Genomics INBRE in Maineamp;rdquo;. This project is also supported by the Puerto Rico Center for Environmental Neuroscience NSF award (#1736019).
