Long-train intracortical stimulation in awake rats elicited alternated bilateral rhythms.
(A) Schematic representation of the locomotor-like rhythmic movements evoked by long-train (250ms) cortical stimulation (amplitude 100 µA). Evoked rhythms are characterized by alternated hindlimb movements. (B) In n=6 intact rats, stimulation of the left motor cortex generated bilateral alternated hindlimb rhythms. After SCI, rats are sorted by injury severity, using their ladder score at week 1 for ranking. One week after injury, long-train cortical stimulation failed to evoke bilateral alternated rhythms in half of the cohort. In two of these rats, contralateral rhythms were still present and bilateral alternated rhythms were recovered by week 2. In the most severe rat, contralateral-only rhythms were evoked on week 2 and bilateral alternated rhythms on week 3. For the remaining half of the cohort, long-train cortical stimulation recruited bilateral alternated rhythms at all tested time points. (C) Stimulus-synchronized ankle flexor EMG traces from n=1 rat with a moderate-severe injury, showing loss (week 1) and following recovery (week 2-3) of ipsilateral evoked hindlimb rhythms. (D) Stimulus-synchronized EMG trace from n=1 rat with mild injury, showing that bilateral alternated evoked rhythms are preserved at week 1. (E) Stimulus-synchronized EMG trace from n=4 intact rats before and after ketamine sedation, showing transient loss of bilateral alternated rhythms. (F) Loss of bilateral alternated rhythms in n=4 rats after ketamine sedation. 1X, 2X, 3X: number of complete repetitions of alternating movements produced by long-train cortical stimulation (amplitude 150 µA)