Advances in our understanding of brain function, along with the development of neural
interfaces that allow for the monitoring and activation of neurons, have paved the way for …

Brain–computer interfaces have revolutionized the field of neuroscience by providing a
solution for paralyzed patients to control external devices and improve the quality of daily …

Objective. Individuals with neurological disease or injury such as amyotrophic lateral
sclerosis, spinal cord injury or stroke may become tetraplegic, unable to speak or even …

General-purpose computers have become ubiquitous and important for everyday life, but
they are difficult for people with paralysis to use. Specialized software and personalized …

Consolidation of memory is believed to involve offline replay of neural activity. While amply
demonstrated in rodents, evidence for replay in humans, particularly regarding motor …

Brain-computer interface (BCI) can be used as a real-time bidirectional information gateway
between the brain and machines. In particular, rapid progress in invasive BCI, propelled by …

Objective. To evaluate the potential of intracortical electrode array signals for brain-computer
interfaces (BCIs) to restore lost speech, we measured the performance of decoders trained …

A brain–computer interface (BCI) is a technology that uses neural features to restore or
augment the capabilities of its user. A BCI for speech would enable communication in real …

Brain‐computer interfaces (BCIs) can be used to control assistive devices by patients with
neurological disorders like amyotrophic lateral sclerosis (ALS) that limit speech and …

Brain–computer interfaces are used for direct two-way communication between the human
brain and the computer. Brain signals contain valuable information about the mental state …