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Thought-controlled prosthesis is changing the lives of amputees
28 November 2012
Chalmers University of Technology
The world’s first implantable robotic arm controlled by thoughts is being developed by Chalmers researcher Max Ortiz Catalan. The first operations on patients will take place this winter.
Every year, thousands of people across the world lose an arm or a leg.
“Our technology helps amputees to control an artificial limb, in much the same way as their own biological hand or arm, via the person's own nerves and remaining muscles. This is a huge benefit for both the individual and to society”, says Max Ortiz Catalan, industrial doctoral student at Chalmers University of Technology in Sweden.
Ever since the 1960s, amputees have been able to use prostheses controlled by electrical impulses in the muscles. Unfortunately, however, the technology for controlling these prostheses has not evolved to any great extent since then. For example, very advanced electric hand prostheses are available, but their functionality is limited because they are difficult to control.
“All movements must by pre-programmed", says Max Ortiz Catalan. “It’s like having a Ferrari without a steering wheel. Therefore, we have developed a new bidirectional interface with the human body, together with a natural and intuitive control system.”
Today’s standard socket prostheses, which are attached to the body using a socket tightly fitted on the amputated stump, are so uncomfortable and limiting that only 50 percent of arm amputees are willing to use one at all.
This research project is using the world-famous Brånemark titanium implant instead (OPRA Implant System), which anchors the prosthesis directly to the skeleton through what is known as osseointegration.
“Osseointegration is vital to our success. We are now using the technology to gain permanent access to the electrodes that we will attach directly to nerves and muscles", says Max Ortiz Catalan.
Currently, in order to pick up the electrical signals to control the prosthesis, electrodes are placed over the skin. The problem is that the signals change when the skin moves, since the electrodes are moved to a different position. Additionally, the signals are also affected when we sweat, since the resistance on the interface changes.
In this project, the researchers are planning to implant the electrodes directly on the nerves and remaining muscles instead. Since the electrodes are closer to the source and the body acts as protection, the bio-electric signals become much more stable. Osseointegration is used to enable the signals inside the body to reach the prosthesis. The electrical impulses from the nerves in the arm stump are captured by a neural interface, which sends them to the prostheses through the titanium implant. These are then decoded by sophisticated algorithms that allow the patient to control the prosthesis using his or her own thoughts.
In existing prostheses, amputees use only visual or auditory feedback. This means, for example, that you have to look at or hear the motors in the prosthesis in order to estimate the grip force applied to a cup if you want to move it around. With the new method, patients receive feedback as the electrodes stimulate the neural pathways to the patient’s brain, in the same way as the physiological system. This means that the patient can control his or her prosthesis in a more natural and intuitive way. This has not been possible previously.
“Many of the patients that we work with have been amputees for more than 10 years, and have almost never thought about moving their missing hand during this time”, says Max Ortiz Catalan. “When they arrived here, they got to test our virtual-reality environment or our more advanced prostheses in order to evaluate the decoding algorithms. We placed electrodes on their amputation stumps, and after a few minutes, they were able to control the artificial limbs in ways that they didn’t know they could, most of the times. This made the patients very excited and enthusiastic.”
The first operations on patients will take place this winter.
“By testing the method on a few patients, we can show that the technology works and then hopefully get more grants to continue clinical studies and develop the technology further. This technology can then become a reality for lots of people. We want to leave the lab and become part of the patients’ everyday life. If the first operations this winter are successful, we will be the first research group in the world to make ‘thought-controlled prostheses’ a reality for patients to use in their daily activities, and not only inside research labs.”
Max Ortiz Catalan demonstrates how the system works with the aid of electrodes, which capture bio-electric signals from the surface of the arm. Amputees will, however, have the electrodes implanted directly on the nerves and muscles inside the body, which will be permanently accessible through the Brånemark osseointegrated implant (OPRA Implant System). Photo: Oscar Mattsson
When amputee patients have received their new prosthesis, it will be controlled with their own brain signals. The signals are transferred via the nerves through the arm stump and captured by electrodes. These will then transmit the signals through a titanium implant (OPRA Implant System) to be decoded by the prosthetic arm. The prosthesis is anchored directly to the skeleton by a process known as osseointegration. Photo: Integrum
Artificial hand repeats the entire movement pattern of the researcher´s living hand. Demonstration of simultaneous control.
The motors in each finger can be controlled individually, like in a biological hand.
Motion signals from the outside of a human arm control a virtual hand and arm on the computer screen.