Description

Despite its relatively low incidence SCI represents a devastating chronic condition for which there is still no cure or consistent approach for intervention. Cervical SCI tremendously affects the quality of life since the use of the upper extremities is critical for completing basic activities of daily living. Extensive research conducted on SCI animal models and humans has revealed that cortical and subcortical reorganization (ie., remote plasticity) takes place after SCI and it is associated with recovery of sensorimotor function (in humans the relevance of these aspect has been mainly emphasised in incomplete SCI). Current rehabilitation after traumatic SCI mainly consists of intensive training of lost/impaired function that is assumed to augment activity-dependent plasticity of spared circuits and thus, leading to functional improvements. Recently, neuromodulatory interventions targeting the sensorimotor systems at various levels has been applied in humans with SCI in combination with training to enhance functional recovery. Neurological rehabilitation of SCI can also benefit of cognitive training based on MI, that enables active stimulation of brain motor areas promoting brain plasticity associated with positive effects on motor performance. In the effort of encouraging the top-down contribution of supraspinal sensorimotor signaling in SCI rehabilitation, the BCI technology may provide for fundamental tools not only for restoring but even recovering sensorimotor function. The long history of BCI research in SCIs has been substantially devoted to develop systems to control external devices to restore function. However, recent findings indicate that non invasive BCI training in combination with intensive rehabilitation can be beneficial to chronic SCI patients for gait, as well as arm function recovery. The current study relies on the hypothesis that monitoring and modulating brain plasticity occurring as a consequence of a SCI is a key factor in shaping clinically valuable top-down rehabilitation strategies that target the recovery of sensorimotor function in patients with SCI. To ground such vision, the researchers will use a goal-oriented action imagery training which is controlled and objectified by a BCI as a means to engage sensorimotor system and thus to facilitate neuroplasticity and optimize functional recovery in SCI during the subacute phase in which brain and spinal plasticity is at its climax.

In this study researchers will test the superiority of a BCI-assisted MI training (up to 12 weeks duration) with respect to MI practiced without BCI feedback (similar training setting and duration) to promote recovery of sensorimotor functions in traumatic cervical SCI subjects. The main hypothesis is that establishing a real-time contingency between the content of MI and an ecological feedback specifically designed to train MI in SCI patients will boost the effect of MI training in engaging the sensorimotor system. Primary and secondary outcome measures (reported in the dedicated section) include the most commonly used clinical and functional scales to assess SCI patients recovery. Neurophysiological and Neuroimaging outcomes are reported as other outcome measures in the dedicated session. Neuropsychological evaluation will include Test of Attentional Performance (TAP), Stroop Test, Trail Making Test (TMT), assessment of depression and anxiety; body ownership and representation. Furthermore, motivation, satisfaction, workload and usability will be evaluated along training.