"This is the first time in neuro-prosthetics that sensory feedback has been restored and used by an amputee in real-time to control an artificial limb, says Micera."
Dennis Aabo Sorensen is the first amputee in the world to feel sensory rich information - in real-time - with a prosthetic hand wired to nerves in his upper arm; Sorensen could grasp objects intuitively and identify what he was touching while blindfold.
Nine years after an accident caused the loss of his left hand, Dennis Aabo Sorensen from Denmark became the first amputee in the world to feel - in real-time - with a sensory-enhanced prosthetic hand that was surgically wired to nerves in his upper arm. Silvestro Micera and his team at EPFL (Switzerland) and SSSA (Italy) developed the revolutionary sensory feedback that allowed Sorensen to feel again while handling objects. A prototype of this bionic technology was tested in February 2013 during a clinical trial in Rome under the supervision of Paolo Maria Rossini at Gemelli Hospital (Italy). The study is published in the February 5, 2014 edition of Science Translational Medicine, and represents a collaboration called Lifehand 2 between several European universities and hospitals.
"The sensory feedback was incredible," reports the 36 year-old amputee from Denmark. "I could feel things that I hadn't been able to feel in over nine years." In a laboratory setting wearing a blindfold and earplugs, Sorensen was able to detect how strongly he was grasping, as well as the shape and consistency of different objects he picked up with his prosthetic. "When I held an object, I could feel if it was soft or hard, round or square."From Electrical Signal to Nerve Impulse
Micera and his team enhanced the artificial hand with sensors that detect information about touch. This was done by measuring the tension in artificial tendons that control finger movement and turning this measurement into an electrical current. But this electrical signal is too coarse to be understood by the nervous system. Using computer algorithms, the scientists transformed the electrical signal into an impulse that sensory nerves can interpret. The sense of touch was achieved by sending the digitally refined signal through wires into four electrodes that were surgically implanted into what remains of Sorensen's upper arm nerves.
"This is the first time in neuro-prosthetics that sensory feedback has been restored and used by an amputee in real-time to control an artificial limb," says Micera.
"We were worried about reduced sensitivity in Dennis' nerves since they hadn't been used in over nine years," says Stanisa Raspopovic, first author and scientist at EPFL and SSSA. These concerns faded away as the scientists successfully reactivated Sorensen's sense of touch.
Connecting Electrodes to Nerves
On January 26, 2013, Sorensen underwent surgery in Rome at Gemelli Hospital. A specialized group of surgeons and neurologists, led by Paolo Maria Rossini, implanted so-called trans-neural electrodes into the ulnar and median nerves of Sorensen's left arm. After 19 days of preliminary tests, Micera and his team connected their prosthetic to the electrodes - and to Sorensen - every day for an entire week. The ultra-thin, ultra-precise electrodes, developed by Thomas Stieglitz's research group at Freiburg University (Germany), made it possible to relay extremely weak electrical signals directly into the nervous system. A tremendous amount of preliminary research was done to ensure that the electrodes would continue to work even after the formation of post-surgery scar tissue. It is also the first time that such electrodes have been transversally implanted into the peripheral nervous system of an amputee.
The First Sensory-Enhanced Artificial Limb
The clinical study provides the first step towards a bionic hand, although a sensory-enhanced prosthetic is years away from being commercially available and the bionic hand of science fiction movies is even further away. The next step involves miniaturizing the sensory feedback electronics for a portable prosthetic. In addition, the scientists will fine-tune the sensory technology for better touch resolution and increased awareness about the angular movement of fingers. The electrodes were removed from Sorensen's arm after one month due to safety restrictions imposed on clinical trials, although the scientists are optimistic that they could remain implanted and functional without damage to the nervous system for many years.
Psychological Strength an Asset
Sorensen's psychological strength was an asset for the clinical study. He says, "I was more than happy to volunteer for the clinical trial, not only for myself, but to help other amputees as well." Now he faces the challenge of having experienced touch again for only a short period of time.
Sorensen lost his left hand while handling fireworks during a family holiday. He was rushed to the hospital where his hand was immediately amputated. Since then, he has been wearing a commercial prosthetic that detects muscle movement in his stump, allowing him to open and close his hand, and hold onto objects.
"It works like a brake on a motorbike," explains Sorensen about the conventional prosthetic he usually wears. "When you squeeze the brake, the hand closes. When you relax, the hand opens."
Without sensory information being fed back into the nervous system, though, Sorensen cannot feel what he's trying to grasp and must constantly watch his prosthetic to avoid crushing the object. Just after the amputation, Sorensen recounts what the doctor told him. "There are two ways you can view this. You can sit in the corner and feel sorry for yourself. Or, you can get up and feel grateful for what you have. I believe you'll adopt the second view."
"He was right," says Sorensen.