Experience-dependent amelioration of motor impairments in adulthood following neonatal medial frontal cortex injury in rats is accompanied by motor map expansion.

One of the most common, and disruptive, neurological symptoms following neonatal brain injury is a motor impairment. Neonatal medial frontal cortical lesions in rats produce enduring motor impairments, and it is thought that lesion-induced abnormal cortical morphology and connectivity may underlie the motor deficits. In order to investigate the functional consequences of the lesion-induced anatomical abnormalities in adulthood, we used intracortical microstimulation to determine the neurophysiologic organization of motor maps within the lesion hemisphere. In addition, groups of neonatal lesion rats were given reach training or complex housing rehabilitation in adulthood and then mapped with intracortical microstimulation. The results demonstrate that neonatal medial frontal cortex lesions produce motor deficits in adulthood that are associated with abnormal motor maps. Further, adult behavioral treatment promoted partial recovery that was supported by reorganization of the motor maps whereby there were increases in the size of the forelimb motor maps. The experience-induced expansion of the forelimb motor maps in adulthood provides a neural mechanism for the experience-dependent improvements in motor performance.

Subcortical middle cerebral artery ischemia abolishes the digit flexion and closing used for grasping in rat skilled reaching.

That rats reach for and grasp a food item using a single paw has prompted their use in neurobiological studies of skilled movements and modeling neural injury including middle cerebral artery stroke. Although motor system lesions have been shown to disrupt various qualitative aspects of the transport of a limb to a food target and withdrawal of the limb with the food, no lesion has been found to abolish digit flexion for grasping. Here, rats received unilateral transient middle cerebral artery ischemia that was restricted mainly to subcortical tissue of the forebrain (caudate-putamen, globus pallidus, and associated fibers) or a sham operation. Both paws were later trained and evaluated on skilled reaching using a rating scale for digit use. Middle cerebral artery rats did not flex and close their digits to grasp food when using their contralateral-to-lesion limb. The grasp impairment was not due to a failure to learn the task as middle cerebral artery rats used the ipsilateral limb as successfully as control rats and they were reinforced for reaching by raking food into the reaching box using an open paw. The impairment was also not due to an inability to move the digits, as they were flexed and closed in other phases of the reach. The paradigm should prove useful for further studies of rehabilitation in relation to the idea that digit closure may be controlled by the joint action of a number of neural systems that converge in the basal ganglia.

Middle cerebral artery (MCA) stroke produces dysfunction in adjacent motor cortex as detected by intracortical microstimulation in rats.

Middle cerebral artery (MCA) stroke in the rat produces impairments in skilled movements. The lesion damages lateral neocortex but spares primary motor cortex (M1), raising the question of the origin of skilled movement deficits. Here, the behavioral deficits of MCA stroke were identified and then M1 was examined neurophysiologically and neuroanatomically. Rats were trained on a food skilled reaching task then the lateral frontal cortex was damaged by unilateral MCA electrocoagulation contralateral to the reaching forelimb. Reach testing and training on two tasks was conducted over 30 post-surgical days. Later, M1 and the corticospinal tract were investigated using intracortical microstimulation (ICMS), anterograde and retrograde axon tracing. A skilled reaching impairment was observed post-surgery, which partly recovered with time and training. ICMS revealed a diminished forelimb movement representation in MCA rats, but a face representation comparable in size to sham rats. Anterograde and retrograde tract tracing suggest that M1 efferents were intact. Although M1 appears to be in the main anatomically spared after MCA stroke its function as assessed electrophysiologically and behaviorally is disrupted.