Tag: amputees

Biomedical Breakthroughs: Bionerves and Restored Sensation

restoring_mobilityThese days, advances in prosthetic devices, bionic limbs and exoskeletons continue to advance and amaze. Not only are doctors and medical researchers able to restore mobility and sensation to patients suffering from missing limbs, they are now crossing a threshold where they are able to restore these abilities and faculties to patients suffering from partial or total paralysis.

This should come as no surprise, seeing as how the latest biomedical advances – which involve controlling robotic limbs with brain-computer interfacing – offer a very obvious solution for paralyzed individuals. In their case, no robotic limbs or bionic attachments are necessary to restore ambulatory motion since these were not lost. Instead, what is needed is to restore motor control to compensate for the severed nerves.

braingate1Thanks to researchers working at Case Western University in Ohio, a way forward is being proposed. Here, a biomedical team is gearing up to combine the Braingate cortical chip, developed at Brown University, with their own Functional Electric Stimulation (FES) platform. Through this combination, they hope to remove robots from the equation entirely and go right to the source.

It has long been known that electrical stimulation can directly control muscles, but attempts to do this in the past artificially has often been inaccurate (and therefore painful and potentially damaging) to the patient. Stimulating the nerves directly using precisely positioned arrays is a much better approach, something that another team at Case Western recently demonstrated thought their “nerve cuff electrode”.

cuff-electrodeThis electrode is a direct stimulation device that is small enough to be placed around small segments of nerve. The Western team used the cuff to provide an interface for sending data from sensors in the hand back to the brain using sensory nerves in the arm. With FES, the same kind of cuff electrode can also be used to stimulate nerves going the other direction, in other words, to the muscles.

The difficulty in such a scheme, is that even if the motor nerves can be physically separated from the sensory nerves and traced to specific muscles, the exact stimulation sequences needed to make a proper movement are hard to find. To achieve this, another group at Case Western has developed a detailed simulation of how different muscles work together to control the arm and hand.

braingate2-img_assist_custom-500x288Their model consists of 138 muscle elements distributed over 29 muscles, which act on 11 joints. The operational procedure is for the patient to watch the image of the virtual arm while they naturally generate neural commands that the BrainGate chip picks up to move the arm. In practice, this means trying to make the virtual arm touch a red spot to make it turn green.

Currently in clinical trials, the Braingate2 chip is being developed with the hope of not only stimulating muscles, but generating the same kinds of feedback and interaction that real muscle movement creates. The eventual plan is that the patient and the control algorithm will learn together in tandem so that a training screen will not be needed at all and a patient will be able to move on their own without calibrating the device.

bionic-handBut at the same time, biotech enhancements that are restoring sensation to amputee victims are also improving apace. Consider the bionic hand developed by Silvestro Micerna of the École Polytechnique Fédérale de Lausanne in Switzerland. Unlike previous bionic hands, which rely on electrodes to receive nerve signals to control the hand’s movement, his device sends electronic signals back to simulate the feeling of touch.

Back in February of 2013, Micerna and his research team began testing their bionic hand, and began clinical trials on a volunteer just last month. Their volunteer, a man named Dennis Aabo Sørensen from Denmark, lost his arm in a car accident nine years ago, and has since become the first amputee to experience artificially-induced sensation in real-time.

prosthetic_originalIn a laboratory setting wearing a blindfold and earplugs, Sørensen was able to detect how strongly he was grasping, as well as the shape and consistency of different objects he picked up with his prosthetic. Afterwards, Sørensen described the experience to reporters, saying:

The sensory feedback was incredible. I could feel things that I hadn’t been able to feel in over nine years. When I held an object, I could feel if it was soft or hard, round or square.

The next step will involve miniaturizing the sensory feedback electronics for a portable prosthetic, as well as fine-tuning the sensory technology for better touch resolution and increased awareness about the movement of fingers. They will also need to assess how long the electrodes can remain implanted and functional in the patient’s nervous system, though Micerna’s team is confident that they would last for many years.

bionic-hand-trialMicerna and his team were also quick to point out that Sørensen’s psychological strength was a major asset in the clinical trial. Not only has he been forced to adapt to the loss of his arm nine years ago, he was also extremely willing to face the challenge of having experienced touch again, but for only a short period of time. But as he himself put it:

I was more than happy to volunteer for the clinical trial, not only for myself, but to help other amputees as well… There are two ways you can view this. You can sit in the corner and feel sorry for yourself. Or, you can get up and feel grateful for what you have.

The study was published in the February 5, 2014 edition of Science Translational Medicine, and represents a collaboration called Lifehand 2 between several European universities and hospitals. And although a commercially-available sensory-enhanced prosthetic may still be years away, the study provides the first step towards a fully-realizable bionic hand.

braingate_drinkassistYes, between implantable electronics that can read out brainwaves and nerve impulses, computers programs that are capable of making sense of it all, and robotic limbs that are integrated to these machines and our bodies, the future is looking very interesting indeed. In addition to restoring ambulatory motion and sensation, we could be looking at an age where there is no such thing as “permanent injury”.

And in the meantime, be sure to check out this video of Sørensen’s clinical trial with the EPFL’s bionic hand:


Sources: extremetech.com, actu.epfl.ch, neurotechnology.com

Top Stories of 2012

biotech_alienAs Dec. 31st fast approaches, I find myself thinking about New Years resolutions. And part of that is taking stock on what’s been accomplished in the past year. For me, one of those resolutions was to stay current and share all the new and exciting news from the field of science and tech all my followers people; to the best of my abilities, that is.

In keeping with this, I wanted to create a list of the most important developments of the last year. Many sites have produced a top 10, top 12, even a top 7, list of what they thought the most significant accomplishments were. Well, I wanted to do one of my own! Opinion varies as to what the biggest leaps and bounds were over the course of the last year, and I’ll be damned if I don’t get my say in. Lord knows I’ve spent enough time reading about them, so here’s my comprehensive list of the greatest inventions, developments and advances made during 2012.

I think you’ll all agree, the list packed with stories that are intriguing, awe-inspiring, and even a little scary! Here are the top 12, as selected by me, in alphabetical order:

3D Printing:
cartilage1As far as tech trends go, this one has been in the works for some time. However, 2012 will be remembered as the year that 3D printing truly became a reality. From tree-dimensional models to consumer products to even guns, 3D printers have been featured in the news many times over for their potential and frightening abilities.

However, one of the greatest potential uses will be in the field of artificial cartilage, organs, and even food. As the technology is refined and expands to the field of organic molecules, just about anything can and will be synthesized, leading to an era where scarcity is… well, scarce!

Bionic Implants:
mindcontrolledprostheticPerhaps the years biggest achievement came in the form of bionic prosthetics, artificial limbs which are calibrated to respond to the nerve impulses of the user. As a result, amputees, veterans and accident victims are able to receive artificial limbs that act like the real thing.

The most notable case was Zak Vawter who scaled the 103 flights of Chicago’s Willis Tower using an artificial leg. In addition, two men in Britain had their sight restored after undergoing the first ever case of retinal surgery where bionic implants were placed in their eyes.

Brain Implants:
digital-mind1In September of 2012, scientists grafted an implant onto the brain of Chimpanzee, enhancing its brain power by ten percent. This consisted of an electrode array that was attached to the cerebral cortex of several monkey subjects, researchers were able to restore and even improve their decision-making abilities.

The implications for possible therapies is far-reaching, such as with brain injuries and cognitive disorders. But additionally, it also heralds the beginning of an era where human beings will be able to enhance their intelligence, recall, and memory retention.

Commercial Space Flight:
skylonThough not yet fully realized, 2012 was a big year in terms of commercial space flight. For example, Richard Branson and Virgin Galactic announced the first successful fully-loaded “glide test” of SpaceShipTwo, the rocket craft that will be taking passengers into low orbit as soon as all the kinks are worked out of the design.

In addition, Reaction Engines announced a breakthrough with the design of their hypersonic engine, which they claim will be fitted to their proposed spaceship – the Skylon. Capable of achieving speeds of up to Mach 5, this new craft is expected to be able to take off from conventional airfields, propel itself into low orbit, and deliver supplies to the ISS and make commercial trips around the world. No telling when either company will be conducting its first real suborbital flights, but the clock is ticking down!

Curiosity Rover:
Curiosity_selfportraitOne of the years biggest announcement was the deployment of the Curiosity Rover on the Martian surface. Since it landed, the rover has provided a constant stream of scientific updates and news on the Red Planet. Though the Mars Science Team did not find the “earthshaking” proof organic molecules, it did make a number of important discoveries.

Amongst them was solid evidence that Mars was once home to large rivers and bodies of water. Furthermore, the x-ray lab on board the rover conducted studies on several rock and soil samples, determining what the chemical and mineral composition of Mars surface is.

Faster-Than-Light Travel:
alcubierre-warp-drive-overviewIn the course of speaking at the 100 Year Starship, scientists at NASA began working on the first FTL travel system ever. Long considered to be the stuff of science fiction, physicist Harold White announced that not only is the math sound, but that his team at NASA had actually started working on it.

Relying on the concept of the Alcubierre Drive, the system involves expanding and contracting space time around the ship, allowing it to move faster than the speed of light without violating the Law of Relativity.

Geo-engineering:
converted PNM fileIn October, the world’s first – and illegal – act of geo-engineering took place off Canada’s West Coast. The product of a “rogue geohacker” named Russ George, who was backed by a private company, the project involved the dumping of around 100 tonnes of oron sulphate into the Pacific Ocean. This technique, known as ocean fertilization, was meant to stimulate the growth of algae which metabolize carbon and produce oxygen.

The experiment, which is in violation of two United Nations moratoria, outraged many environmental, legal, and civic groups, many of whom hail from Haida Gwaii, the traditional territory of the Haida nation, who had enlisted by George as part of a proposed “salmon enhancement project”. Though illegal and abortive, the act was the first in what may very well become a series of geoengineering efforts which will be performed the world over in order to stay the progress of Climate Change.

Google’s Project Glass:
google_glasses2012 was also the year that augmented reality became… well, a reality (oh dear, another bad pun). Back in April, Google unveiled its latest concept device for wireless and portable computing, known as Project Glass. Combining an active display matrix, a wireless internet connection and a pair of shades, Google managed to create a device that looks like something straight out of cyberpunk novel.

HIV and Flu Vaccines:
HIV-budding-ColorWhen it comes to diseases, HIV and the Flu have two things in common. Until 2012, both were considered incurable, but sometime in the near future, both could be entirely preventable. In what could be the greatest medical breakthroughs in history, 2012 saw scientists and researchers experiment with antibodies that have been known to fight off HIV and the flu, and to good effect.

In the former case, this involved using a new process known as Vectored ImmunoProphylaxis (VIP), an inversion of the traditional vaccination method, where antibodies were introduced to mice. After allowing the antibodies to reproduce, researchers at Caltec found that the mice were able to fight off large quantities of the virus. In the latter, researchers at the Friedrich-Loeffler Institute in Riems Island, Germany used a new RNA-based vaccine that appeared to be able to fight off multiple strains of flu, not just the latest mutation.

Taken together, these vaccines could bring an end to a common, but potentially deadly ailment, and signal the end of the plague of the 20th century. In addition, this could be the first in a long series of developments which effectively brings all known diseases under our control.

Medical Implants:
enhancement2012 also saw the culmination of several breakthroughs in terms of biomedical research. In addition to the world’s first medimachine, there were also breakthroughs in terms of dissolving electronics, subdermal implants that dispense drugs, and health monitoring patches.

Little wonder then that Cambridge University announced the creation of the Center for the Study of Existential Risk to evaluate future technologies, or that Human Rights Watch and Harvard University teamed up to release a report calling for the ban of “killer robots”. With all the potential for enhancement, it could be just a matter of time before non-medical enhancements are a reality.

Mind-controlled prostheses:
woman-robotic-arm_650x366Researchers at BrainGate created a brain-machine interface that allows users to control an external device with their minds. The first person to use this revolutionary new system was Cathy Hutchinson, a stroke victim who has been paralyzed from the neck down for 15 years, who used the robotic arm to drink a cup of coffee.

This news, combined with other advances in terms of bionic prostheses, could signal the end of disability as we know it. Henceforth, people with severe injuries, amputations and strokes could find themselves able to make full recoveries, albeit through the use of robotic limbs.

Self-driving cars:
googlecar2012 marked an important year as three states (California, Nevada, and Florida) made autonomous vehicles legal. Self-driving cars, once perfected and produced en masse, will help with traffic congestion and significantly reduce the chance of auto accidents through the use of GPS, radar, and other technologies.

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All in all, it’s been an exciting year. And with all that’s been accomplished, the future is certainly looking a lot more interesting and even frightening. What is clear is that predictions made for some time now are becoming realizable, including replication, a cure for all known diseases, advanced robotics, implants, cybernetics, and even post-humanism. Regardless of where one sits on these developments, be you pro, con, or neutral, I think we can all agree that it is an exciting time to be alive!

Happy New Year to all, and here’s hoping 2013 proves just as interesting, and hopefully a lot more peaceful and sound. And may we ALL find ourselves able to keep our New Years resolutions and build upon all we’ve accomplished so far. And of course, with all the potential for medical and technological enhancements that are coming, I sincerely hope we can find ways to improve ourselves on a personal level too!

The Future Is Here: Bionic Hands!

Behold, the latest in bionic technology! The bebionic 3 model prosthetic hand, by the RSL Steeper company! Encased in an aluminum chassis, boasting improved electronics, a redesigned thumb, and new motors that increase the power grip, this hand was first unveiled at the American Orthotic Prosthetic Association (AOPA) Conference in Boston this past September. Since that time, amputees have been obtaining the hand and incorporating it into their daily lives. And the results are quite encouraging!

In addition to being able to do delicate work, like handle eggs and fine china without breaking them, the hand is also capable of performing a power grip that is capable of generating 31.5 pounds of force. That’s quite the Kung Fu grip, just in case you were wondering. And in “hook” mode, the hand is able to bear a load of 99 pounds. So, though it doesn’t have quite the same dexterity or free range of motion as an organic hand, the bebionic is capable of performing all the basic tasks, and is pretty powerful to boot!

Much like the bionic leg which was popularized by Zak Vawter’s historic climb last weekend, the bebionic works by reading the nerve impulses from the wearer’s arm skin. These are amplified by the arm’s electronics and translated into one of 14 possible grip configurations. These different grips are uploaded to the hands internal memory and users are able to cycle through them to determine which grip they want for which purpose. For instance, a mouse-clicking action makes the thumb grip a mouse, while the index finger clicks the left button. The “precision open grip” can be used to grab small objects and the “tripod grip” can be used to write with a pen.

Currently, and depending on its configuration, the hand costs clinical centers between $25,000 and $35,000. In time, and as it becomes available for public purchase, the price is likely to come down somewhat. Still, such a revolutionary device will not come cheap for many years to come. It also comes available in a range of colors and designs, including snow and jungle camouflage and tiger stripes, as well as realistic silicone skin coverings. See the video below for some examples.

Combined with other advances in the field of bionics and prosthetic devices, the bionic hand presents some new and very exciting possibilities. For one, technologies like ReWalk and other exoskeletons are making it possible for paraplegics to walk again, while sophisticated wheelchairs like the wheelchairbot are making stairs and obstacles passable. Coupled with bionic limbs that are giving full ambulatory motion back to amputees, we could be looking at a future where robotic enhancements can restore any and all ability to accident victims, combat veterans and people born with physical deformities.

In addition, the most audacious developments, such as bionic enhancements or robot chairs that read brain waves directly, giving full motion to quadriplegics and the ability to communicate fully to people with degenerative conditions is still yet to come! Once such technologies are readily available and commercially viable, we might even be seeing the emergence of a cybernetics industry, where people can receive enhancements that not only restore abilities, but greatly enhance them. Artificial limbs the enhance strenght and speed, artificial eyes that enhance vision and provide projected images and augmented reality displays, and even silicate implants that enhance brain function and make people smarter.

Homo Superior people… I just got goosebumps!

And while we’re waiting on all that to happen, check out this promo video for the latest bebionic model:


And here’s a video of the bebionic going through a battery grip pattern tests: