The implanted MEAs allow a computer to read the signals coming from the participant’s motor cortex. These signals convey the intention of movement. The computer then decodes and transmits these signals to the robotic arm, allowing the participant to control its movements similar to if it were the real arm.

The research team is investigating uses for the MEAs beyond controlling prosthetics. For example, the participant uses neurosignals to control a cursor on a computer or provides instructions to a smart home setup.

Additionally, we are testing whether the participant will be able to control two things at once using only neurosignals, such as controlling a wheelchair and a robotic arm at the same time.

While controlling a prosthetic limb is groundbreaking for someone with paralysis, it only solves half the problem. Without sensation, the participant would be controlling an arm that is essentially numb. Without sensory feedback, it is difficult to use the correct amount of pressure to pick up a cup, for example. Sensation also allows the participant to know where the arm is without having to look at it.

The goal behind implanting MEAs into the participant’s sensory cortex is to simulate sensation so that when the prosthetic arm is touched, the participant would be able to feel that touch and pinpoint its location. This ability will make robotic limbs much easier to use.

The research team wants to take perception beyond the scope of prosthetics as well. The goal is to use sensory cues to provide feedback for certain actions, such as a tap on the pinky indicating that a smart home system locked the front door.