May 13, 2013

Sense of Touch Reproduced Through Prosthetic Hand

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Neurobiologists at the University of Chicago (UChicago), Illinois, have shown that a monkey can sense a tactile stimulus, in real time, through an artificial sensor in a prosthetic hand. The study was published in the May issue of IEEE Transactions on Neural Systems and Rehabilitation Engineering.

Scientists have made advances toward building lifelike prosthetic limbs that move and function like the real thing, but an important element to creating a realistic replacement for a hand is the sense of touch. Without somatosensory feedback from the fingertips about how hard you’re squeezing something or where it’s positioned relative to the hand, you rely instead on your sense of vision to compensate for the lack of touch.

“If you lose your somatosensory system it almost looks like your motor system is impaired,” said Sliman Bensmaia, PhD, a UChicago assistant professor of organismal biology and anatomy. “If you really want to create an arm that can actually be used dexterously without the enormous amount of concentration it takes without sensory feedback, you need to restore the somatosensory feedback.”

Bensmaia and his colleagues are now working with a robotic hand equipped with sensors that send electrical signals to electrodes implanted in the brain to recreate the same response to touch as a real hand.

The researchers performed a series of experiments with rhesus macaques that were trained to respond to stimulation of the hand. In one setting, they were gently poked on the hand with a physical probe at varying levels of pressure. In a second setting, some of the animals had electrodes implanted into the area of the brain that responds to touch. These animals were given electrical pulses to simulate the sensation of touch, and their hands were hidden so they wouldn’t see that they weren’t actually being touched. Using data from the animals’ responses to each type of stimulus, the researchers were able to create a function, or equation, that described the requisite electrical pulse to go with each physical poke of the hand. Then, they repeated the experiments with a prosthetic hand that was wired to the brain implants. They touched the prosthetic hand with the physical probe, which in turn sent electrical signals to the brain.

Bensmaia said that the animals performed identically whether poked on their own hand or on the prosthetic one. “This is the first time as far as I know where an animal or organism actually perceives a tactile stimulus through an artificial transducer,” he said. “It’s an engineering milestone. But from a neuroengineering standpoint, this validates this function. You can use this function to have an animal perform this very precise task, precisely identically.”

The U.S. Food and Drug Administration (FDA) is in the process of approving similar devices for human trials, and Bensmaia said he hopes such a system is implemented within the next year. Not only would producing a lifelike sense of touch help improve the dexterity and performance of prosthetic hands, but Bensmaia said it would also help bridge a mental divide for individuals with amputations or people who have lost the use of a limb.

“If every time you see your robotic arm touching something, you get a sensation that is projected to it, I think it’s very possible that in fact, you will consider this new thing as being part of your body,” he said.

Editor’s note: This story was adapted from materials provided by the University of Chicago Medical Center to Newswise.

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