In 2014 billions of viewers worldwide may remember the opening game of the World Cup in Brazil for more than just the goals scored by the Brazilian national team and the red cards given to its adversary. On that day my laboratory at Duke University, which specializes in developing technologies that allow electrical signals from the brain to control robotic limbs, plans to mark a milestone in overcoming paralysis.

If we succeed in meeting still formidable challenges, the first ceremonial kick of the World Cup game may be made by a paralyzed teenager, who, flanked by the two contending soccer teams, will saunter onto the pitch clad in a robotic body suit. This suit—or exoskeleton, as we call it—will envelop the teenager's legs. His or her first steps onto the field will be controlled by motor signals originating in the kicker's brain and transmitted wirelessly to a computer unit the size of a laptop in a backpack carried by our patient. This computer will be responsible for translating electrical brain signals into digital motor commands so that the exoskeleton can first stabilize the kicker's body weight and then induce the robotic legs to begin the back-and-forth coordinated movements of a walk over the manicured grass. Then, on approaching the ball, the kicker will visualize placing a foot in contact with it. Three hundred milliseconds later brain signals will instruct the exoskeleton's robotic foot to hook under the leather sphere, Brazilian style, and boot it aloft.

This scientific demonstration of a radically new technology, undertaken with collaborators in Europe and Brazil, will convey to a global audience of billions that brain control of machines has moved from lab demos and futuristic speculation to a new era in which tools capable of bringing mobility to patients incapacitated by injury or disease may become a reality. We are on our way, perhaps by the next decade, to technology that links the brain with mechanical, electronic or virtual machines. This development will restore mobility, not only to accident and war victims but also to patients with ALS (also known as Lou Gehrig's disease), Parkinson's and other disorders that disrupt motor behaviors that impede arm reaching, hand grasping, locomotion and speech production. Neuroprosthetic devices—or brain-machine interfaces—will also allow scientists to do much more than help the disabled. They will make it possible to explore the world in revolutionary ways by providing healthy human beings with the ability to augment their sensory and motor skills.

In this futuristic scenario, voluntary electrical brain waves, the biological alphabet that underlies human thinking, will maneuver large and small robots remotely, control airships from afar, and perhaps even allow the sharing of thoughts and sensations of one individual with another over what will become a collective brain-based network.

Thought Machines

The lightweight body suit intended for the kicker, who has not yet been selected, is still under development. A prototype, though, is now under construction at the lab of my great friend and collaborator Gordon Cheng of the Technical University of Munich—one of the founding members of the Walk Again Project, a nonprofit, international collaboration among the Duke University Center for Neuroengineering, the Technical University of Munich, the Swiss Federal Institute of Technology in Lausanne, and the Edmond and Lily Safra International Institute of Neuroscience of Natal in Brazil. A few new members, including major research institutes and universities all over the world, will join this international team in the next few months.

The project builds on nearly two decades of pioneering work on brain-machine interfaces at Duke—research that itself grew out of studies dating back to the 1960s, when scientists first attempted to tap into animal brains to see if a neural signal could be fed into a computer and thereby prompt a command to initiate motion in a mechanical device. Back in 1990 and throughout the first decade of this century, my Duke colleagues and I pioneered a method through which the brains of both rats and monkeys could be implanted with hundreds of hair-thin and pliable sensors, known as microwires. Over the past two decades we have shown that, once implanted, the flexible electrical prongs can detect minute electrical signals, or action potentials, generated by hundreds of individual neurons distributed throughout the animals' frontal and parietal cortices—the regions that define a vast brain circuit responsible for the generation of voluntary movements.

11 Comments

1. 1. wmatosscam 08:45 AM 8/29/12

   Mr. Nicolelis is someone who prides Brazilians. Unfortunately, most of the technology which he helps to develop isn't Brazilian owned. In the future, we'll have to pay high royalties to use it.

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2. 2. RSchmidt in reply to wmatosscam 11:10 AM 8/29/12

   Seems a small price to pay to regain mobility.

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3. 3. davidmorgan 11:17 AM 8/29/12

   I sure would like to volunteer. C-7 incomplete SCI since 1/08. David Morgan, 424 North Tenth Street, Albemarle, NC 28001 davidmorgan@ctc.net

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4. 4. HowardB 12:55 PM 8/29/12

   A fantastic new technology with exciting exciting prospects for the disabled true enough.
   
   So ... "2014" ? oh no ... "perhaps by the next decade" ? .... or as the headline says ".....soon" ?
   
   All sounds a bit confused if you ask me.
   

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5. 5. ehanley12 08:02 PM 8/31/12

   The science is exciting, but this article is over the top. As with the much-ballyhooed DEKKA arm that appears frequently on TV, whatever is demonstrated at the World Cup (and I hope the developers meet their deadline) will not be available to the average amputee or brain-injured individual for at least a decade afterward. It turns out that the engineering is as difficult as the science. It's one thing to produce a prototype; it's another thing entirely to produce a supply of devices that are practical in daily life. I wish the scientists all the best, but I urge caution in making predictions. The many men and women who need this science get their hopes up only to find out that the whiz bang stuff is probably not going to be available to them in any meaningful timeframe.

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6. 6. dragon2 in reply to ehanley12 11:10 PM 9/2/12

   The article admits: "We are on our way, perhaps by the next decade, to technology that links the brain with mechanical, electronic or virtual machines.". Let's give those scientists and engineers credit for what they've achieved and wish them luck. DARPA is funding research in this area to help the amputees from Afganinstan gain mobility.

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7. 7. SoundAndFury 11:06 PM 9/3/12

   I would like to preface this by saying that I'm in full support of restoring the quality of life of the disabled. However, I am wary of some of these visions surrounding brain-machine interfaces. We have enough trouble protecting precious banking information that's stored on our computers today, so what would be keeping a skilled hacker from accessing my thoughts, dreams, and memories in the future? We're heading into an age that will be filled to the brim with ethical debates surrounding technological progress.
   
   Scientific progress is necessary for human survival, but sometimes we need to stop, take a breath, and look around us.
   
   "I hope we never fully understand the human brain because somebody will just abuse it." (to that effect) - Theodore Dalrymple.

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8. 8. Strangy 09:32 PM 9/10/12

   Technology is moving so fast that anything can happen. Throughtout history, men have been under pressure by the circumstances.And when such scenarios come along the way, we usually come with gib stuff. The cold war has proven this. We never know what event will happen and give emergence to higher technologies. We can even go above the expectations. I believe it's just a matter of time, though no one knows exactly when.

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9. 9. Strangy 09:33 PM 9/10/12

   Technology is moving so fast that anything can happen. Throughtout history, men have been under pressure by the circumstances.And when such scenarios come along the way, we usually come with big stuff. The cold war has proven this. We never know what event will happen and give emergence to higher technologies. We can even go above the expectations. I believe it's just a matter of time, though no one knows exactly when.

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10. 10. ehanley12 in reply to dragon2 08:03 AM 9/11/12

    DARPA funds lots of exciting research into science and technology to aid wounded soldiers, including the DEKKA arm and the work described in this article. I give them and the researchers they fund all the credit in the world -- my son is one of the soldiers waiting eagerly for their work to be deployed and has participated in DARPA funded trials. My problem with this overly optimistic report stems from watching him and other "wounded warriors" gradually and painfully come to grips with the reality that, despite wildly optimistic reports and claims and misleading Today Show appearances, the new technologies will not be available in any timeframe relevant to their recovery and reintegration into civilian life. I would contrast this over-the-top report with the more responsible caution shown by the scientists who recently unveiled their findings re: "junk" DNA.

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11. 11. Kendra#17 10:04 PM 3/6/13

    I'm the one. I look like the picture At top! I'm in top physical condition and have been a complete C6 quadriplegic for only a year and a half. I am determined like no one else and will fight till my last breath. I have real passion for the beautiful game; before my accident was on two soccer teams and won state in cross-country. I will make the world proud. Contact-801-864-1124 or 801-450-2803 kendra.jean17@gmail.com

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