Brain–Machine Interfaces:Past, Present and Future

What is your doctor using of these to help your recovery?
http://scholar.google.com/scholar_url?url=http://www.ijircce.com/upload/2014/november/Brain_NEW%252010_%2520_10_dr_77B.pdf&hl=en&sa=X&scisig=AAGBfm2uOow5gw9696i7jI8B7UqmyJGWDQ&oi=scholaralrt
S.Senthilkumar1, T.Shanmugapriya2
Assistant Professor, Department of Electronics and Instrumentation, Bharath University, Chennai, Tamil Nadu, India1
Assistant Professor, Department of Information Technology, SSN Engineering College, Chennai, Tamil Nadu, India2
ABSTRACT: Since the original demonstration that electrical activity generated by ensembles of cortical neurons can be employed directly to control a robotic manipulator, research on brain-machine interfaces (BMIs) has experienced an impressive growth. Today BMIs designed for both
experimental and clinical studies can translate raw neuronal signals into motor commands that
reproduce arm reaching and hand grasping movements in artificial actuators. Clearly, these
developments hold promise for the restoration of limb mobility in paralyzed subjects. However, as
we review here, before this goal can be reached several bottlenecks have to be passed. These
include designing a fully implantable biocompatible recording device, further developing real-time
computa- tional algorithms, introducing a method for providing the brain with sensory feedback
from the actuators, and designing and building artificial prostheses that can be controlled directly by
brain-derived signals. By reaching these milestones, future BMIs will be able to drive and control
revolutionary prostheses that feel and act like the human arm.