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  • You know what will be cool about the future besides jetpaks and equality?

  • Robotic arms.

  • And surprisingly theyre not too far away.

  • Hey guys, Julia here for Dnews

  • Artificial limbs have come a long way since the days of Pirate Joe’s Peg Leg.

  • Today’s prosthetics are made of state of the art materials and cutting edge technology.

  • Theyre made of titanium, carbon fiber, and/or silicone.

  • These materials are tough, lighter and can even be designed to look life-like.

  • They stay on by a few different mechanisms like suspension or suction.

  • Suspension involves some type of straps or sleeves.

  • Suction works because the new limb might be custom made to perfectly fit to the remaining

  • natural limb.

  • Some devices can be controlled by the body, in a kind of pulley system, not surprisingly

  • called body powered.

  • Others can be controlled by switches or buttons.

  • While fit and materials get progressively more advanced, so does the technology.

  • Most new robotic limbs are myoelectric-controlled, meaning muscles in the remaining limb naturally

  • create electrical signals that are picked up by electrodes in the prosthetic.

  • For the past few decades medical technology allowed patients to control their device through

  • electrodes placed on the skin.

  • But that’s an imperfect design, moving or sweating might dislodge the electrodes.

  • So scientists are looking to the future.

  • Recently a report published in the journal Science Translational Medicine talked about

  • a robotic arm that uses what’s called a Brånemark titanium implant which attaches

  • the prosthetic directly to the skeleton in a process called osseointegration.

  • And just like it sounds, this process fuses the bone to a titanium piece which sits outside

  • of the limb, which the robotic arm attaches to.

  • To control the device, the technology goes a step beyond the current myoelectric types.

  • It uses Targeted Muscle Reinnervation or TMR to hook up the prosthetic to nerves INSIDE

  • the patient’s body.

  • The process takes nerves from the amputated limb and puts them on a spare muscle like

  • the pectoral, the target muscle.

  • Once these nerves start to regrow they can be activated by thought.

  • Electrodes surrounding the muscle and nerves can then control the prosthetic.

  • Sounds pretty futuristic right?

  • Yet something seems to be missing.

  • The sensation of touch.

  • Current techniques use sensory substitution to provide feedback, like a buzz or vibration

  • when the limb comes into contact with something.

  • In research presented in the journal Plastic and Reconstructive Surgery researchers look

  • for a way to restore a patient’s ability to feel.

  • The researchers say this would reduce thecognitive burden" of relying on vision

  • alone to navigate the environment.

  • A robotic hand with the ability tofeelwould have to be able to take a sensation

  • like hot or cold or pressure like firm or soft and translate that into electrical signals.

  • The different sensations could create a different signal like it could vary in strength, frequency

  • or duration.

  • The researchers suggested using TMR to restore some type of sensation for the patient.

  • Another idea is a sensory regenerative peripheral nerve interface (sRPNI), which would directly

  • hook up a nerve with some sort of biological interface on the prosthetic.

  • Or maybe light could brighten up the future.

  • Optogenics might enable different light waves to control nerve signalling.

  • Anything to make the electrical signalling devices smaller and more precise.

  • Robotic legs too are taking great leaps into the future.

  • Research published in the journal Science Translational Medicine explained recent advances

  • in powered joints.

  • Yeah that’s right.

  • Basically each joint in a robotic leg can have a little motor in it.

  • This way it detects pressure and angle and can send that information to the central nervous

  • system.

  • But more than that, the more advanced models can have a neural interface that enhances

  • integration with the brain.

  • This way they can sense a person’s intention like the desire to move from a flat surface

  • to climbing stairs.

  • Either way the future of artificial limbs is gonna be awesome.

  • Speaking of insane augmentations, Toyota has been doing some tinkering of their own with

  • the TRD line of Toyota Trucks.

  • Enhanced to rule the off-road!

  • Do you have an artificial limb or know anyone who does?

  • Tell us your story down in the comments below

You know what will be cool about the future besides jetpaks and equality?

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ロボット手足の未来とは? (What Is The Future Of Robotic Limbs?)

  • 89 6
    Kana kawai に公開 2021 年 01 月 14 日
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