Brain-computer interfaces (BCI) are used in stroke rehabilitation to translate brain signals
into intended movements of the paralyzed limb. However, the efficacy and mechanisms of …

Motor recovery after stroke is an unsolved challenge despite intensive rehabilitation training
programs. Brain stimulation techniques have been explored in addition to traditional …

Stroke is among the leading causes of long-term disabilities leaving an increasing number
of people with cognitive, affective and motor impairments depending on assistance in their …

Brain-computer interfaces (BCIs) provide a unique technological solution to circumvent the
damaged motor system. For neurorehabilitation, the BCI can be used to translate neural …

Repeated use of brain-computer interfaces (BCIs) providing contingent sensory feedback of
brain activity was recently proposed as a rehabilitation approach to restore motor function …

Stroke is a leading cause of acquired disability resulting in distal upper extremity functional
motor impairment. Stroke mortality rates continue to decline with advances in healthcare and …

Brain-computer interface (BCI) technology is being incorporated into new stroke
rehabilitation devices, but little is known about brain changes associated with its use. We …

The idea of using brain computer interfaces (BCI) for rehabilitation emerged relatively
recently. Basically, BCI for neurorehabilitation involves the recording and decoding of local …

Stroke is a leading cause of motor disability worldwide. Upper limb rehabilitation is
particularly challenging since approximately 35% of patients recover significant hand …

Introduction Numerous recent publications have explored Brain Computer Interfaces (BCI)
systems as rehabilitation tools to help subacute and chronic stroke patients recover upper …