Dr. Jonathan Cheng is investigating whether tying into residual nerves can serve as a bridge in re-establishing “feel” in the prosthetic hands of amputees.

Michael “Shawn” Findley, a 44-year-old amputee with a wiring harness emerging from his upper left arm, is working with a UT Southwestern team to help change the way robotic hand biofeedback occurs. Ultimately, he hopes this research may lead to the closest thing to feeling in the hands of every amputee.

A 2005 punch press accident in a Mount Pleasant, TX, fabrication shop left Mr. Findley with mangled and amputated fingers on his left hand. Over the next four years, the Dallas native underwent 13 restorative operations before he decided in 2009 to have an elective amputation at midforearm. He was then fitted with a functioning prosthetic hand.

After electrodes were temporarily implanted in his residual limb at UT Southwestern in late October 2017, Findley drove in weekly from his home in Mount Pleasant to make the most of a 90-day research window, part of Dr. Jonathan Cheng’s HAPTIX neural interfacing study. On a recent Friday, Findley relearned how much fingertip pressure it took to pick up different small weights, as these readings were fed into several electronic graphs monitored by the research team.

An Army veteran, Findley served from 1993 to 1999. His willingness to participate in this innovative research and complete numerous trips to Dallas is easily understood.

“I have a 19-year-old son in the Marines. You hope they all stay out of harm’s way, but you want to have done what you could,” Findley says. “If something did happen, well, you know you might have helped in some way. You’ve got to have someone willing to do this, and I’m here for as long as they want me.”

The federal government’s Hand Proprioception and Touch Interfaces (HAPTIX) program seeks to create a prosthetic hand system that moves and provides sensation like a natural hand. Dr. Cheng, an associate professor of plastic surgery at UT Southwestern, said he believes that the body’s natural neural communications pathway — even one that has been severed — can be tapped into using an artificial messaging bridge.

Dr. Cheng’s research, which has advanced from animal models to humans, focuses on communication of undamaged nerves remaining in the limb after amputation. Other research has employed electrodes inserted into the control areas of the brain. The UT Southwestern team, however, believes the singular workload of nerves in the forearm will provide the best functional pathway.

“The brain is complex and changes all the time,” Dr. Cheng says. “Nerves outside the brain, in contrast, are like living wire: one fiber connected to one thing.”

Robotic hand research for amputees has been underway for decades. While the hand can perform up to 22 different functions simultaneously, the most sophisticated commercially available robotic hands can only control three different functions — one at a time. Development of more advanced robotics and control systems has been funded by the U.S. Defense Advanced Research Projects Agency (DARPA) for over 15 years, Dr. Cheng says. From that, two technologically advanced research-grade robotic hands have emerged, both of which have 20 to 30 distinct functions.

Although technologically advanced, these newest robotic hands as yet have not demonstrated practical application in patients because the human-machine interface has not been mastered; patients using those advanced robotic hands cannot feel with them or control them naturally. Previous DARPA-sponsored studies have shown that implanting electrodes (electrical contacts) on the surface of the brain helps, but the technique has not been applicable to many patients due to the need for brain surgery and the extreme complexity of decoding brain signals. Dr. Cheng and other researchers are ultimately striving for the degree of dexterity and sensitivity needed to type on a keyboard or play a musical instrument.

“The problem is not the amputees or the robotic hands,” says Dr. Cheng. “The problem has been the biological interface between the two.”

DARPA support comes through Nerves Inc., of which Dr. Cheng is a founder. The company’s DEFT (Dexterous Hand Control Through Fascicular Targeting) study has five participating institutions, including UT Southwestern, and uses Nerve Inc.’s FAST-LIFE electrodes. Dr. Cheng has an investment interest in Nerves Inc.

The UT Southwestern team’s first two human participants – who were both hand amputees – had electrodes attached to the ulnar nerve. The ulnar nerve runs the length of the forearm, ending with 15 tiny muscles in the hand. The ulnar nerve controls every type of hand motion, plus touch and movement sensation.

“It is a very direct access,” Dr. Cheng says. “The organization of these nerves is quite predictable during peripheral nerve reconstructions, which are done in my everyday clinical practice.”

Findley is one of the four clinical trial participants that UT Southwestern researchers are continuing to work with on biological and physiological investigations. This group includes hand and forearm amputees, advancing the investigation to include both the median and ulnar nerves in the forearm. The goal is to restore sensation in patients with robotic hands.

“Feeling your hand is absolutely the purpose here,” Dr. Cheng says. “For all of my other patients, being able to feel with their hand is mandatory. It should be no different for patients using robotic hands.”

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