Sprouting of brainstem-spinal tracts in response to unilateral motor cortex stroke in mice.

After a stroke to the motor cortex, sprouting of spared contralateral corticospinal fibers into the affected hemicord is one mechanism thought to mediate functional recovery. Little is known, however, about the role of the phylogenetically old, functionally very important brainstem-spinal systems. Adult mice were subjected to a unilateral photothrombotic stroke of the right motor cortex ablating 90% of the cross-projecting corticospinal cells. Unilateral retrograde tracing from the left cervical spinal hemicord devoid of its corticospinal input revealed widespread plastic responses in different brainstem nuclei 4 weeks after stroke. Whereas some nuclei showed no change or a decrease of their spinal projections, several parts of the medullary reticular formation as well as the spinally projecting raphe nuclei increased their projections to the cortically denervated cervical hemicord by 1.2- to 1.6-fold. The terminal density of corticobulbar fibers from the intact, contralesional cortex, which itself formed a fivefold expanded connection to the ipsilateral spinal cord, increased up to 1.6-fold specifically in these plastic, caudal medullary nuclei. A second stroke, ablating the originally spared motor cortex, resulted in the reappearance of the deficits that had partially recovered after the initial right-sided stroke, suggesting dependence of recovered function on the spared cortical hemisphere and its direct corticospinal and indirect corticobulbospinal connections.

Deep brain stimulation of the midbrain locomotor region improves paretic hindlimb function after spinal cord injury in rats.

In severe spinal cord injuries, the tracts conveying motor commands to the spinal cord are disrupted, resulting in paralysis, but many patients still have small numbers of spared fibers. We have found that excitatory deep brain stimulation (DBS) of the mesencephalic locomotor region (MLR), an important control center for locomotion in the brain, markedly improved hindlimb function in rats with chronic, severe, but incomplete spinal cord injury. The medial medullary reticular formation was essential for this effect. Functional deficits of rats with 20 to 30% spared reticulospinal fibers were comparable to patients able to walk but with strong deficits in strength and speed [for example, individuals with American Spinal Injury Association Impairment Scale (AIS)-D scores]. MLR DBS enabled close to normal locomotion in these rats. In more extensively injured animals, with less than 10% spared reticulospinal fibers, hindlimbs were almost fully paralyzed, comparable to wheelchair-bound patients (for example, AIS-A, B, and C). With MLR DBS, hindlimb function reappeared under gravity-released conditions during swimming. We propose that therapeutic MLR DBS using the brain's own motor command circuits may offer a potential new approach to treat persistent gait disturbances in patients suffering from chronic incomplete spinal cord injury.