Real Cyborgs? This is already possible today!

00:12:31
https://www.youtube.com/watch?v=fQQEQgugDD8

Summary

TLDRThe video delves into the merging of technology with human biology, showcasing advancements like brain-computer interfaces, biohacking, and prosthetics. From pop culture inspirations to real-life applications, it examines how cyborg technology is enhancing human capabilities. Key examples include Neil Harbison, a colorblind cyborg with an antenna that translates colors to sounds, and the work of Neuralink in developing brain-computer interfaces. It also highlights prosthetic innovations like the third thumb and exoskeletons like HAL, which assist paraplegics in regaining mobility. With growing interests in making such technology mainstream, it raises questions about the societal implications and accessibility of becoming cyborg-like.

Takeaways

  • 🤖 Cyborg technology is becoming a reality with enhancements like brain-computer interfaces and prosthetics.
  • 🧠 Brain-computer interfaces allow communication between the brain and technology, aiding people with disabilities.
  • 🎨 Neil Harbison is a real-life cyborg with a color-detecting antenna implant.
  • 📡 Neuralink, by Elon Musk, develops interfaces for mind-controlled devices.
  • 🦾 Prosthetics like the third thumb offer new abilities with technology.
  • 🎥 DuoSkin tattoos act as tech interfaces with touch or NFC technology.
  • ⚙️ Exoskeletons improve strength and aid workers and those with mobility issues.
  • 👟 Prosthetics controlled by foot pressure, like the third thumb, give users new capabilities.
  • 🏃 HAL exoskeleton assists paraplegics in relearning to walk using nerve signals.
  • 🔄 Neural feedback training helps the brain recover and regain motor functions.
  • 🌐 Society must consider inclusivity and accessibility as cyborg tech advances.
  • 🔬 The integration of tech in our lives is growing, blurring lines between human and machine.

Timeline

  • 00:00:00 - 00:05:00

    The video explores the concept of cyborgs, blending humans with technology, moving from sci-fi to reality with advancements in digital optimization. Real-life examples include Neil Harbison's antenna for color perception and Elon Musk's Neuralink, which demonstrated mind-controlled gaming. The focus is on how brain-computer interfaces can improve lives for those with disabilities. Bionic prosthetics, like third thumbs, enhance human capability beyond mere replacement. Gold leaf tattoos as communication interfaces and microchips for convenience are further blurring lines between human and machine.

  • 00:05:00 - 00:12:31

    Exoskeletons are being utilized in various industries to reduce physical strain and improve efficiency. Initially designed for medical and military use, these robotic suits are gaining traction in sectors like automotive and logistics. Countries like Japan are investing heavily in such technologies due to workforce shortages caused by aging populations. Devices like HAL, controlled by nerve impulses, offer rehabilitation for paraplegics, illustrating the potential of these technologies. As tech becomes more integrated into daily life, it sparks debate on access and societal impact as we edge closer to a cyborg reality.

Mind Map

Video Q&A

  • What is a cyborg?

    A cyborg is a being with biological and artificial parts, often seen in pop culture and now becoming a reality through technology.

  • How can brain-computer interfaces help humans?

    They allow direct communication between the brain and devices, helping those with disabilities control technology with their thoughts.

  • Who is Neil Harbison?

    Neil Harbison is a colorblind British cyborg with an antenna that converts colors into sounds, capable of detecting infrared and ultraviolet.

  • What is Neuralink?

    Neuralink is Elon Musk's startup working on brain-computer interface technology to facilitate communication with devices using the mind.

  • What are some real-life applications of prosthetics?

    Prosthetics can replace missing limbs and even add new abilities, like a third thumb controlled by foot pressure.

  • What is DuoSkin?

    DuoSkin is a communication interface developed by MIT, made from gold leaf, capable of functioning as a touch pad or using NFC technology.

  • How do exoskeletons benefit people?

    Exoskeletons enhance strength and agility, useful in industries and for aiding those with reduced mobility.

  • What is HAL?

    HAL (Hybrid Assistive Limb) is an exoskeleton controlled by nerve impulses, aiding paraplegics in learning to walk again.

  • What is neural feedback training?

    It is a technique using the activation of muscle impulses to help the brain relearn control of body movements.

  • Who developed HAL?

    HAL was developed by Yoshiyuki Sankai, a Japanese roboticist and founder of Cyberdyne.

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  • 00:00:00
    getting stronger and smarter through
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    technology this sci-fi dream
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    is quickly becoming reality researchers
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    and developers
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    are driving forth the digital
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    optimization of humans with
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    mind-blowing results will we all soon
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    become cyborgs
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    today's topic on shift
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    [Music]
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    the cybernetic organism or cyborg for
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    short
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    has played a major role in pop culture
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    for example
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    in the movie robocop a police officer
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    with potentially fatal injuries
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    becomes a super cop with his high-tech
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    implants
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    tony stark from the marvel universe can
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    fly in his armor
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    and superman's colleague cyborg updates
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    his hardware
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    to gain new powers and skills these days
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    even real-life humans enhance their
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    bodies with artificial components
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    they call themselves cyborgs or
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    biohackers
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    neil harbison from britain is one of
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    them he is colorblind and has an antenna
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    that converts colors into sounds and
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    unlike the human eye
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    his antenna can even detect infrared and
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    ultraviolet
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    he has a chip implanted in his head to
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    make this work
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    pretty intense but actually there are
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    lots of scientists and companies working
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    on
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    brain computer interfaces they allow
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    direct communication between brain
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    and computer so you can control the
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    device
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    with your mind but it's not just a
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    gimmick it can fundamentally improve the
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    lives of people
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    with spinal injuries or neurological
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    disorders
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    us tech titan elon musk is developing a
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    brain computer interface at his startup
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    neuralink the team implanted ships in
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    both brain hemispheres of a macaque
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    pager
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    they then taught him to play a game with
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    a joystick and his nerve signals
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    were transmitted to a computer via
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    bluetooth pager
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    was fed banana smoothie through a tube
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    as a reward
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    when the researchers deactivated the
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    joystick pager controlled
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    the game with his thoughts alone the
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    computer had learned
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    to interpret the brain activity but
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    there are devices that humans can
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    control with the mind
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    even without a brain chip like bionic
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    prosthesis that replace missing body
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    parts
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    british gamer daniel melville even uses
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    one when he plays
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    video games but prosthesis can also give
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    people
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    brand new powers how would you like
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    a third thumb this prosthetic thumb
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    makes it possible to do things that
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    usually require two hands
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    the prosthesis is connected to a
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    wristband with a motor
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    which drives the thumb it receives
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    signals via bluetooth from pressure
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    sensors attached to the shoes
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    the user can control the prosthesis by
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    moving their big toe
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    [Music]
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    new zealand-born scientist danny claude
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    developed the third thumb in london she
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    wanted to show that prosthetics
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    don't always have to replace what's
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    missing they can also provide
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    an add-on an upgrade
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    [Music]
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    what's fascinating is after just five
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    days of training with the third thumb
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    new synapses had formed in the test
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    subject's brains
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    and the way they used their normal
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    fingers had changed
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    there are other developments like this
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    that blur the line between human and
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    machine
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    sometimes on the skin sometimes under
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    the skin
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    it might look like a temporary tattoo
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    but this is actually a communication
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    interface made from gold leaf
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    duo skin was invented by the
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    massachusetts institute of technology
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    one version works like a touch pad while
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    another uses near-field communication
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    or nfc technology to communicate with
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    other interfaces in the future when you
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    walk into a tattoo parlor
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    you would come out with a tattoo like
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    this they will not only
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    be very sophisticated technically but
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    they become an extension of yourself
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    [Music]
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    often forget your keys eric frisk can
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    open his door in sweden with a microchip
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    implanted
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    under his skin it's the size of a grain
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    of rice
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    and works like a room card in a hotel
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    it's estimated that 50
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    000 people around the world already wear
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    one of these implants
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    they can even be ordered online the
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    interesting thing is
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    when the chips start getting smarter
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    and start having you know sensors and
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    things like that so
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    instead of just opening a door maybe i
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    can have continuously record my
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    my body temperature my blood sugar
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    levels you know etc etc
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    and actually give me useful information
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    about my body
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    but technology that literally gets under
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    your skin isn't for everyone
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    implants are just one way to become a
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    cyborg there are also
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    robotic suits called exoskeletons they
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    promise more strength
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    and better agility heavy lifting
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    uncomfortable work exoskeletons could
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    someday help people
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    reduce the strain on their backs
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    originally developed for medical and
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    military use
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    they're now increasingly deployed in the
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    automotive industry and logistics
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    many see it as win-win employees stay
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    healthier
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    and companies profit from the increased
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    efficiency in production
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    robotic technology that makes work more
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    ergonomic is under intensive development
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    predominantly in the us and germany but
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    also in china and japan
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    we want to create devices that help
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    people in their workplace
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    and to make these tools more accessible
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    and easy to use
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    i don't think humans will ever become
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    dispensable
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    there are only a few companies that are
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    designing completely automated systems
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    because they require considerate
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    investment so i think we'll always have
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    human workers
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    the exoskeleton created by japanese
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    company ataun
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    has been in use for years in production
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    the care sector and in japan's biggest
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    airports
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    [Music]
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    the four and a half kilogram suit is
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    worn like a rucksack
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    it has a sensor that detects the
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    wearer's movements so when lifting two
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    motors in the suit automatically support
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    the user's movement
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    the motors deactivate when the user is
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    walking
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    countries like japan are increasingly
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    relying on robotics
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    because with an aging population
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    workforces are becoming depleted
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    right now we mainly make support devices
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    but in the future we want to create
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    products that enhance people's abilities
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    and add physical functions
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    like a third arm we want to cater to a
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    society in which people of all ages can
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    work without physical limits
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    and it could get much more spectacular
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    than that the developers at artun
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    have been working for more than 10 years
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    on this mega exosuit called
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    neo i was even allowed to try it out
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    during my visit to japan i felt like
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    lieutenant ripley and the sci-fi classic
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    aliens with
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    supernatural powers the developers claim
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    that one arm alone
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    can lift up to 50 kilograms it's hoped
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    that neo will soon aid the construction
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    industry
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    or in disaster management exoskeletons
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    have a growing role in the medical
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    sector as well
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    what's special about this model from
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    japan is that it's controlled by nerve
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    impulses
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    hell is its name that stands for hybrid
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    assistive limb
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    as an ultimate goal even paraplegics
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    could train with hal
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    and learn to walk again my colleague
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    cassandra beau went to test the
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    exoskeleton
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    at the company's cyberdyne in japan so
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    these electrodes here will detect my
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    brain signals
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    and send it to this machine so that it
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    will move
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    for me so now i'm going to try
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    to flex and move my arm
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    it detects pretty well and now i'm going
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    to try
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    to lock my arm in place and
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    it will still move for me
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    did you see that it's pretty cool
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    but i do wonder um does this kind of
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    is this safe does this go out of control
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    sometimes
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    no awesome
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    electrodes translate cassandra's brain
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    signals into a command for the
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    exoskeleton
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    her brain sends the command move to the
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    muscles
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    via the spine the signal is detected by
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    hal's built-in sensors
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    the motor receives the signal and pal
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    starts moving
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    this is more difficult for patients with
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    paraplegia because the nerve connections
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    are disrupted
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    but if there are any remaining impulses
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    hal could provide beneficial treatment
  • 00:09:14
    time for a little test walk cassandra is
  • 00:09:17
    allowed to wear the exoskeleton herself
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    it's attached to a bracket since it's
  • 00:09:22
    designed for people with impaired
  • 00:09:23
    mobility
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    it's a very intimate um
  • 00:09:28
    setting it's actually really light
  • 00:09:32
    starting training right now
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    okay i feel a little bit
  • 00:09:40
    mechanic with my movement
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    but i think it's just getting used to
  • 00:09:46
    the machine because now i feel a little
  • 00:09:48
    more comfortable
  • 00:09:49
    in it so now he's increasing the speed
  • 00:09:52
    [Music]
  • 00:09:56
    the monitor displays cassandra and her
  • 00:09:58
    nerve signals as a waveform
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    hal works together with other ai systems
  • 00:10:03
    to analyze the
  • 00:10:04
    signals and evaluate user data
  • 00:10:08
    so how do paralyzed people actually
  • 00:10:10
    learn to walk again with hal
  • 00:10:13
    the activation of muscle impulses
  • 00:10:15
    creates a feedback effect
  • 00:10:16
    that enables the brain to learn how to
  • 00:10:18
    make the body walk again from scratch
  • 00:10:21
    it's called neural feedback training it
  • 00:10:23
    only works for about 20 to 30 percent of
  • 00:10:26
    paraplegic patients
  • 00:10:27
    but the results are still impressive
  • 00:10:32
    so with other exoskeletons the movements
  • 00:10:34
    are pre-programmed
  • 00:10:36
    so patients wearing the suit will have
  • 00:10:39
    to rely on it
  • 00:10:40
    permanently however with hell it teaches
  • 00:10:43
    you
  • 00:10:44
    how to walk again basically making the
  • 00:10:46
    connections from your brain
  • 00:10:47
    to your broken synapses so basically
  • 00:10:51
    these
  • 00:10:51
    patients they go through these trainings
  • 00:10:54
    and at the end of the training they're
  • 00:10:57
    able to walk again without
  • 00:10:59
    the technology without the suit hell
  • 00:11:02
    was developed by japanese roboticist
  • 00:11:04
    yoshiyuki sankai
  • 00:11:05
    he is the founder and ceo of cyberdyne
  • 00:11:08
    and
  • 00:11:08
    a professor at the university of tsukuba
  • 00:11:11
    he believes these bionic aids and cyborg
  • 00:11:13
    technologies
  • 00:11:14
    are a step into a new age
  • 00:11:19
    we're constantly wearing technology or
  • 00:11:21
    strongly connected to it
  • 00:11:22
    in that sense we're born cyborgs don't
  • 00:11:24
    you think as technology becomes more
  • 00:11:29
    accessible we'll be able to use it
  • 00:11:31
    without even being aware of it
  • 00:11:33
    this phenomenon is the fusion of humans
  • 00:11:35
    and technology
  • 00:11:36
    and this symbiotic relationship will
  • 00:11:38
    continue to develop
  • 00:11:40
    are we all becoming cyborgs or are we
  • 00:11:42
    already
  • 00:11:43
    and if the technology becomes available
  • 00:11:45
    soon won't people get left behind who
  • 00:11:48
    don't want to be enhanced or
  • 00:11:49
    who can't afford it what are your views
  • 00:11:52
    on cyborg technology
  • 00:11:54
    is this the chance for us all to upgrade
  • 00:11:56
    or are you skeptical
  • 00:11:58
    let us know for example on youtube there
  • 00:12:00
    you'll also find more videos about elon
  • 00:12:03
    musk's new ruling project
  • 00:12:04
    and a paralyzed man who controls an
  • 00:12:06
    exoskeleton with his mind
  • 00:12:09
    take care bye
  • 00:12:31
    you
Tags
  • cyborg
  • technology
  • brain-computer interfaces
  • prosthetics
  • Neuralink
  • biohacking
  • exoskeleton
  • HAL
  • Neural feedback
  • cybernetic enhancement