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How we'll become cyborgs and extend human potential

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    I'm an MIT professor,
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    but I do not design buildings
    or computer systems.
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    Rather, I build body parts,
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    bionic legs that augment
    human walking and running.
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    In 1982, I was in
    a mountain-climbing accident,
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    and both of my legs had to be amputated
    due to tissue damage from frostbite.
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    Here, you can see my legs:
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    24 sensors, six microprocessors
    and muscle-tendon-like actuators.
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    I'm basically a bunch of nuts and bolts
    from the knee down.
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    But with this advanced bionic technology,
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    I can skip, dance and run.
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    (Applause)
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    Thank you.
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    (Applause)
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    I'm a bionic man,
    but I'm not yet a cyborg.
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    When I think about moving my legs,
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    neural signals from
    my central nervous system
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    pass through my nerves
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    and activate muscles
    within my residual limbs.
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    Artificial electrodes sense these signals,
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    and small computers in the bionic limb
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    decode my nerve pulses
    into my intended movement patterns.
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    Stated simply,
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    when I think about moving,
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    that command is communicated
    to the synthetic part of my body.
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    However, those computers can't input
    information into my nervous system.
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    When I touch and move my synthetic limbs,
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    I do not experience normal
    touch and movement sensations.
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    If I were a cyborg and could feel my legs
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    via small computers inputting information
    into my nervous system,
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    it would fundamentally change, I believe,
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    my relationship to my synthetic body.
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    Today, I can't feel my legs,
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    and because of that,
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    my legs are separate tools
    from my mind and my body.
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    They're not part of me.
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    I believe that if I were a cyborg
    and could feel my legs,
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    they would become
    part of me, part of self.
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    At MIT, we're thinking about
    NeuroEmbodied Design.
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    In this design process,
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    the designer designs human flesh and bone,
    the biological body itself,
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    along with synthetics to enhance
    the bidirectional communication
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    between the nervous system
    and the built world.
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    NeuroEmbodied Design is a methodology
    to create cyborg function.
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    In this design process,
    designers contemplate a future
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    in which technology
    no longer compromises separate,
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    lifeless tools from
    our minds and our bodies,
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    a future in which technology
    has been carefully integrated
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    within our nature,
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    a world in which
    what is biological and what is not,
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    what is human and what is not,
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    what is nature and what is not
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    will be forever blurred.
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    That future will provide
    humanity new bodies.
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    NeuroEmbodied Design
    will extend our nervous systems
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    into the synthetic world,
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    and the synthetic world into us,
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    fundamentally changing who we are.
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    By designing the biological body
    to better communicate
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    with the built design world,
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    humanity will end disability
    in this 21st century
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    and establish the scientific
    and technological basis
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    for human augmentation,
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    extending human capability
    beyond innate, physiological levels,
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    cognitively, emotionally and physically.
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    There are many ways
    in which to build new bodies across scale,
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    from the biomolecular
    to the scale of tissues and organs.
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    Today, I want to talk about
    one area of NeuroEmbodied Design,
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    in which the body's tissues
    are manipulated and sculpted
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    using surgical and regenerative processes.
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    The current amputation paradigm
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    hasn't changed fundamentally
    since the US Civil War
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    and has grown obsolete
    in light of dramatic advancements
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    in actuators, control systems
    and neural interfacing technologies.
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    A major deficiency is the lack
    of dynamic muscle interactions
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    for control and proprioception.
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    What is proprioception?
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    When you flex your ankle,
    muscles in the front of your leg contract,
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    simultaneously stretching muscles
    in the back of your leg.
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    The opposite happens
    when you extend your ankle.
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    Here, muscles in the back
    of your leg contract,
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    stretching muscles in the front.
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    When these muscles flex and extend,
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    biological sensors
    within the muscle tendons
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    send information
    through nerves to the brain.
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    This is how we're able to feel
    where our feet are
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    without seeing them with our eyes.
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    The current amputation paradigm
    breaks these dynamic muscle relationships,
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    and in so doing eliminates
    normal proprioceptive sensations.
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    Consequently, a standard artificial limb
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    cannot feed back information
    into the nervous system
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    about where the prosthesis is in space.
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    The patient therefore
    cannot sense and feel
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    the positions and movements
    of the prosthetic joint
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    without seeing it with their eyes.
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    My legs were amputated
    using this Civil War-era methodology.
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    I can feel my feet,
    I can feel them right now
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    as a phantom awareness.
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    But when I try to move them, I cannot.
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    It feels like they're stuck
    inside rigid ski boots.
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    To solve these problems,
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    at MIT, we invented the agonist-antagonist
    myoneural interface,
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    or AMI, for short.
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    The AMI is a method to connect nerves
    within the residuum
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    to an external, bionic prosthesis.
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    How is the AMI designed,
    and how does it work?
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    The AMI comprises two muscles
    that are surgically connected,
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    an agonist linked to an antagonist.
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    When the agonist contracts
    upon electrical activation,
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    it stretches the antagonist.
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    This muscle dynamic interaction
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    causes biological sensors
    within the muscle tendon
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    to send information through the nerve
    to the central nervous system,
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    relating information on the muscle
    tendon's length, speed and force.
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    This is how muscle tendon
    proprioception works,
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    and it's the primary way we, as humans,
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    can feel and sense the positions,
    movements and forces on our limbs.
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    When a limb is amputated,
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    the surgeon connects these opposing
    muscles within the residuum
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    to create an AMI.
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    Now, multiple AMI
    constructs can be created
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    for the control and sensation
    of multiple prosthetic joints.
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    Artificial electrodes are then placed
    on each AMI muscle,
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    and small computers within the bionic limb
    decode those signals
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    to control powerful motors
    on the bionic limb.
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    When the bionic limb moves,
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    the AMI muscles move back and forth,
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    sending signals through
    the nerve to the brain,
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    enabling a person wearing the prosthesis
    to experience natural sensations
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    of positions and movements
    of the prosthesis.
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    Can these tissue-design principles
    be used in an actual human being?
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    A few years ago, my good friend
    Jim Ewing -- of 34 years --
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    reached out to me for help.
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    Jim was in an a terrible
    climbing accident.
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    He fell 50 feet in the Cayman Islands
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    when his rope failed to catch him
    hitting the ground's surface.
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    He suffered many, many injuries:
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    punctured lungs and many broken bones.
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    After his accident, he dreamed
    of returning to his chosen sport
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    of mountain climbing,
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    but how might this be possible?
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    The answer was Team Cyborg,
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    a team of surgeons,
    scientists and engineers
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    assembled at MIT to rebuild Jim
    back to his former climbing prowess.
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    Team member Dr. Matthew Carty
    amputated Jim's badly damaged leg
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    at Brigham and Women's Hospital in Boston,
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    using the AMI surgical procedure.
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    Tendon pulleys were created
    and attached to Jim's tibia bone
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    to reconnect the opposing muscles.
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    The AMI procedure
    reestablished the neural link
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    between Jim's ankle-foot
    muscles and his brain.
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    When Jim moves his phantom limb,
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    the reconnected muscles
    move in dynamic pairs,
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    causing signals of proprioception
    to pass through nerves to the brain,
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    so Jim experiences normal sensations
    with ankle-foot positions and movements,
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    even when blindfolded.
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    Here's Jim at the MIT laboratory
    after his surgeries.
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    We electrically linked Jim's AMI muscles,
    via the electrodes,
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    to a bionic limb,
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    and Jim quickly learned
    how to move the bionic limb
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    in four distinct ankle-foot
    movement directions.
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    We were excited by these results,
    but then Jim stood up,
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    and what occurred was truly remarkable.
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    All the natural biomechanics
    mediated by the central nervous system
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    emerged via the synthetic limb
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    as an involuntary, reflexive action.
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    All the intricacies of foot placement
    during stair ascent --
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    (Applause)
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    emerged before our eyes.
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    Here's Jim descending steps,
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    reaching with his bionic toe
    to the next stair tread,
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    automatically exhibiting natural motions
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    without him even trying to move his limb.
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    Because Jim's central nervous system
    is receiving the proprioceptive signals,
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    it knows exactly how to control
    the synthetic limb in a natural way.
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    Now, Jim moves and behaves
    as if the synthetic limb is part of him.
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    For example, one day in the lab,
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    he accidentally stepped
    on a roll of electrical tape.
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    Now, what do you do
    when something's stuck to your shoe?
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    You don't reach down like this;
    it's way too awkward.
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    Instead, you shake it off,
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    and that's exactly what Jim did
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    after being neurally connected to the limb
    for just a few hours.
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    What was most interesting to me
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    is what Jim was telling us
    he was experiencing.
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    He said, "The robot became part of me."
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    Jim Ewing: The morning after the first
    time I was attached to the robot,
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    my daughter came downstairs
    and asked me how it felt to be a cyborg,
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    and my answer was
    that I didn't feel like a cyborg.
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    I felt like I had my leg,
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    and it wasn't that I was
    attached to the robot
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    so much as the robot was attached to me,
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    and the robot became part of me.
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    It became my leg pretty quickly.
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    Hugh Herr: Thank you.
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    (Applause)
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    By connecting Jim's
    nervous system bidirectionally
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    to his synthetic limb,
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    neurological embodiment was achieved.
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    I hypothesized that because Jim
    can think and move his synthetic limb,
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    and because he can feel those movements
    within his nervous system,
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    the prosthesis is no longer
    a separate tool,
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    but an integral part of Jim,
    an integral part of his body.
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    Because of this neurological embodiment,
    Jim doesn't feel like a cyborg.
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    He feels like he just has his leg back,
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    that he has his body back.
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    Now I'm often asked
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    when I'm going to be neurally linked
    to my synthetic limbs bidirectionally,
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    when I'm going to become a cyborg.
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    The truth is, I'm hesitant
    to become a cyborg.
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    Before my legs were amputated,
    I was a terrible student.
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    I got D's and often F's in school.
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    Then, after my limbs were amputated,
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    I suddenly became an MIT professor.
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    (Laughter)
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    (Applause)
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    Now I'm worried that once I'm neurally
    connected to my limbs once again,
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    my brain will remap
    back to its not-so-bright self.
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    (Laughter)
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    But you know what, that's OK,
    because at MIT, I already have tenure.
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    (Laughter)
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    (Applause)
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    I believe the reach
    of NeuroEmbodied Design
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    will extend far beyond limb replacement
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    and will carry humanity into realms
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    that fundamentally
    redefine human potential.
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    In this 21st century,
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    designers will extend the nervous system
    into powerfully strong exoskeletons
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    that humans can control
    and feel with their minds.
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    Muscles within the body
    can be reconfigured
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    for the control of powerful motors,
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    and to feel and sense
    exoskeletal movements,
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    augmenting humans' strength,
    jumping height and running speed.
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    In this 21st century, I believe humans
    will become superheroes.
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    Humans may also extend their bodies
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    into non-anthropomorphic
    structures, such as wings,
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    controlling and feeling each wing movement
    within the nervous system.
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    Leonardo da Vinci said,
    "When once you have tasted flight,
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    you will forever walk the earth
    with your eyes turned skyward,
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    for there you have been
    and there you will always long to return."
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    During the twilight years of this century,
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    I believe humans will be unrecognizable
    in morphology and dynamics
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    from what we are today.
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    Humanity will take flight and soar.
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    Jim Ewing fell to earth
    and was badly broken,
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    but his eyes turned skyward,
    where he always longed to return.
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    After his accident,
    he not only dreamed to walk again,
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    but also to return to his chosen sport
    of mountain climbing.
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    At MIT, Team Cyborg built Jim
    a specialized limb for the vertical world,
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    a brain-controlled leg with full position
    and movement sensations.
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    Using this technology,
    Jim returned to the Cayman Islands,
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    the site of his accident,
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    rebuilt as a cyborg
    to climb skyward once again.
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    (Crashing waves)
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    (Applause)
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    Thank you.
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    (Applause)
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    Ladies and gentlemen, Jim Ewing,
    the first cyborg rock climber.
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    (Applause)
Title:
How we'll become cyborgs and extend human potential
Speaker:
Hugh Herr
Description:

Humans will soon have new bodies that forever blur the line between the natural and synthetic worlds, says bionics designer Hugh Herr. In an unforgettable talk, he details "NeuroEmbodied Design," a methodology for creating cyborg function that he's developing at the MIT Media Lab, and shows us a future where we've augmented our bodies in a way that will redefine human potential -- and, maybe, turn us into superheroes. "During the twilight years of this century, I believe humans will be unrecognizable in morphology and dynamics from what we are today," Herr says. "Humanity will take flight and soar."
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Video Language:
English
Team:
closed TED
Project:
TEDTalks
Duration:
15:13

English subtitles

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