ProstheticArm
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Monkeys control virtual arm with their brains, may herald breakthrough for paraplegics
Monkey mind-controlled arm: It sounds like the name of an awesomely terrible sci-fi film or a fledgling grindcore group, but it's a very real phenomenon, and one that could pay significant dividends for paraplegics everywhere. Neurobiology professor Miguel Nicolelis and his team of researchers at Duke University recently devised a method by which monkeys (and, perhaps one day, humans) can control a virtual arm using only their brains. It's a concept similar to what DARPA has been pursuing with its mind-controlled "Luke" arm, with one important difference: Nicolelis' system not only allows users to remotely execute motor functions, but provides them with near-instantaneous sensory feedback, as well. Most similar techniques use electrode implants to stimulate brain activity, but this can create confusion when a patient's brain sends and receives signals to and from a prosthetic arm. Nicolelis circumvented this problem with a new interface that can read and transmit brain signals to an artificial limb, before switching to a receptive mode in just milliseconds. After designing the technology, Nicolelis and his colleagues tested it on two, electrode-equipped rhesus monkeys. One set of electrodes was placed in the motor cortex of each animal, with the other implanted within their brains' sensory regions. They then trained the monkeys to look at a three identical objects on a computer screen and to "touch" each object with a virtual arm, controlled by signals sent from the brain electrodes. Only one of the three objects had a so-called "virtual texture," which, if selected with the on-screen arm, would send a sensory signal back to the monkey's brain (while triggering a tasty squirt of fruit juice for the lucky contestant). The two rhesus species ended up passing the test with flying colors, resulting in a "proof of principle" that Nicolelis' system can send tactile signals to the brain in almost real-time. The scientists have already developed a way for monkeys to control the arm wirelessly, and are now embedding their technology within a full-body, mind-controlled exoskeleton for paralyzed patients, as well. Of course, the technology still needs to be tested on actual humans, though Nicolelis seems confident that he and his team have already cleared the most difficult hurdle: "Since we cannot talk to the monkeys, I assume with human patients, it's going to be much easier."
AMO Arm pneumatic prosthetic does mind-control on the cheap
We're no strangers to amputees moving stuff with their minds -- for that matter, a thought-controlled prosthetic isn't really new to us, either -- but the pneumatic arm you see here isn't like other intelligent limbs. Unlike most mind-operated prosthesis, the Artificial Muscle-Operated (AMO) Arm doesn't require invasive surgery, and according to its inventors, it costs a quarter of the price to make. Here's how the thing works: the host human wears a headset that sends brain signals to a chip in the arm that then matches those signals to a database of related actions, triggering a series of pneumatic pumps and valves to move the limb. Thus, if the wearer thinks 'up,' the arm moves up. The AMO Arm's creators, a pair of undergraduate biomed students, say that not only is their invention a steal to produce, but it also takes just minutes to acclimate to, which has us wondering, do you have to be missing an arm to get a hold of one of these things? You know, we can always use an extra hand. Full PR after the break.
Man with bionic arms dies after car crash
Otto Bock's mind-controlled bionic arms let Austria's Christian Kandlbauer work, play and even drive, but it seems the latter passion may have lead to the 22-year-old's untimely demise. Two days after a road accident where the young man's specially-modified Subaru crashed into a tree, Kandlbauer was pronounced brain-dead and taken off life support late last week. It's not known whether the prosthetic arms themselves had anything to do with the crash -- one was found ripped from his body at the scene -- but both he and his vehicle were cleared to drive by local authorities after passing a number of tests. Honestly, it's a tragedy for science and humanity either way.
DARPA-funded prosthetic arm reaches phase three, would-be cyborgs celebrate
Last we heard from Johns Hopkins University's Applied Physics Laboratory, it wanted a neurally-controlled bionic arm by 2009. Needless to say, the school overshot that goal by a tiny bit, and have now been beaten (twice) to the punch. But DARPA sees $34.5 million worth of promise in their third and final prototype, which will enable the nine pound kit (with 22 degrees of freedom and sensory feedback) to begin clinical trials. Rechristened the Modular Prosthetic Limb, it will be grafted onto as many as five real, live persons, the first within the year. Using the targeted muscle reinnervation technique pioneered at the Rehabilitation Institute of Chicago, patients will control these arms directly with their thoughts, and for their sakes and the fate of humanity, hopefully not the other way around. Press release after the break.
Mind-controlled prosthetic arm moving to market in Europe
Germany-based Otto Bock Healthcare has announced that its prototype prosthetic arm which can be controlled by thought is ready to hit the market. The device has been in testing on Christian Kandlbauer -- who doesn't have any arms and has a conventional prosthetic on his right side -- for the past four years. He's the first person in Europe to have a thought-controlled prosthesis installed, but the research is complete and the finished product should soon be available to the public. The arm makes use of targeted muscle reinnervation (TMR), which uses nerves that controlled the lost arm to control the prosthesis. The nerves are transplanted to the chest in a six-hour operation and enable the prosthetic control. The full details of the arm's operation and controls have yet to be unveiled, but hit up the source link for more information.
DIY prosthesis all the rage in Tasmania
When the doctors told amputee Mark Lesek that the severity of his injury made him ineligible for a prosthesis, he refused to give up. Left with nothing but his own welding and engineering business, several hundred thousands of dollars, and an indomitable spirit, the Tasmanian gentleman began the quest for an artificial arm. First, he shopped around until he found a doctor who agreed to order an $80,000 prosthesis from Germany -- which eventually broke down (but not before he shelled out $6,000 for repairs on the thing). His next stop was the Branemark Osseointegration Centre in Sweden, where he was fitted with an $80,000 bolt that works as a sort of "artificial shoulder." Still unable to find a suitable arm, the guy teamed up with one of his employees to design and build his own lightweight magnesium "body powered" prosthesis. But that's not all -- he's also working with the University of Tasmania to develop a more agile computer-controlled arm, controlled with "a cap with electrodes which will be interfaced into the computer." Let's hope that all his hard work pays off -- and that he teaches those doctors a thing or two in the process.[Via Switched]
Rocket-powered mechanical arm might boost prosthetic tech
A group of researchers at Vanderbilt have built a mechanical arm that outperforms traditional battery-powered prosthetics the old-fashioned way: by strapping on a couple rocket motors. The arm, which the team built for DARPA's Revolutionizing Prosthetics 2009 program, relies on a modified miniature version of the same rocket motors the space shuttle uses to reposition itself in space: hydrogen peroxide is burned in the presence of a catalyst to produce pure steam, which is then used to move the arm. Unlike the batteries in traditional arms, which die quickly, a small canister of hydrogen peroxide concealed in the arm can last up to 18 hours, and provides about the same power and functionality of a human arm. Cooler still is the method the arm deals with waste heat and steam: just like a regular arm, it's allowed to filter up through a permeable skin, producing "sweat" -- the same amount of perspiration you'd get on a warm summer day, according to the team. Check a video of the arm in action at the read link -- it's even niftier than it sounds.
Elephant trunks inspire ISELLA robotic arm
It's not often you see a piece of tech touted by its developer as being inspired by something "long, gray, and soft," but that's exactly how the researchers at Germany's prolific Fraunhofer-Gesellschaft Institute are describing their ISELLA robotic arms. Inspired by the finesse and power of an elephant's trunk, the team developed a unique redundant motorized "muscle" called DOHELIX, consisting of dual drive shafts intertwined around each other in a double helix, resulting in a system that can be scaled from micrometer-scale muscles to cranes in container seaports. The protoype ISELLA unit (pictured) has ten DOHELIX muscles, enough to mimic the flexibility of the human arm, but the team expects even better results when the system is ready to ship in two years -- here's hoping some enterprising carnie rigs up the next generation of elephant rides.[Via MedGadget]
DARPA's prosthetic challenge nets first prototype
Less than a year after challenging researchers to develop a bionic arm that looks, feels, and works like a real arm by 2009, DARPA's Revolutionizing Prosthetics Program has now netted its first prototype, PhysOrg reports, with one patient already putting the arm through its paces. Developed by a team at Johns Hopkins University's Applied Physics Laboratory, the appropriately-dubbed Proto 1 system not only consists of a prosthetic arm, but a virtual environment that patients can use to get accustomed to it. Like other similar systems, the Proto 1 makes use of residual nerves in the patient to control the arm, which also allows for them to receive a sensation of grip strength and touch. That apparently makes the arm precise enough to remove a credit card from a pocket, with the arm also boasting a "free swing mode" that allows for a more natural movement when the patient is walking. While Proto 1 seems to have already been enough to attract interest from various government agencies, the researchers don't look to be resting on their laurels, with them already hard at work on Proto 2.
