First off, no, monkeys have not
developed telekinetic powers and then attempted to use them against the
disabled. That I know of. The
involvement of monkeys in scientific research seems to somehow generate absurd
situations that leave the casual observer bewildered and dubious. This is most
certainly the case for a recent study that sounds like something straight out
of a futuristic sci-fi novel.
Researchers at Duke Health have
recently created a brain-machine interface (BMI) that allows primates to move a
robotic wheelchair using only their thoughts. The experiments began in 2012,
when hundreds of microfilaments were implanted in the premotor and
somatosensory regions of the brains of two rhesus monkeys. The monkeys were trained by passively moving
the chair to the target, a bowl of grapes, while the researchers recorded the
large-scale electrical brain activity. The motions of the wheelchair where
correlated with signals from different neurons in the monkeys’ brains, creating
computational algorithms that mapped brain activity to different trajectories.
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| An overview of the experimental design |
The data from this initial experiment
was then used to create the interface system, which detects signals in the
monkeys’ brains, and then translates them into commands that move the
wheelchair. The monkeys’ skills at
moving the chair actually improved as the experiment continued, with one of the
monkeys going from completing the task in 43.1 seconds to 27.3 seconds. Other differences in brain activity were
noticed when the monkeys themselves were moving the chair, as opposed to when
they were merely passengers, and their neurons became better attuned to the distance
between the chair and the grape dispenser.
This shows promising evidence that the brain is able to adapt to and assimilate
the device. According to researchers, the next step in development will be to
record more neuronal signals in order to increase the accuracy and fidelity in
the primate model before beginning any trials with the device implanted in
humans.
 |
| A monkey successfully maneuvers the chair to the dish of grapes |
This is more than just simple
monkeyshines. For many individuals with disabilities that impair movement,
wheelchairs are still the primary mode of transportation. Currently, there is a large amount of focus
on the development of exoskeletons controlled by signals from external electroencephalography
(EEG), but these devices have been developed for paraplegic patients. ALS patients or those who are quadriplegic
would most likely not be able to use these devices, but removing the need for
someone else to move their wheelchair could give them more independence, autonomy,
and dignity. There is even evidence that
BMIs can lead to partial neurological recovery by triggering cortical plasticity. Though there is still much more work to be
done to increase the accuracy of intracranial interfaces, it is clear that BMIs
could be of great help to the physically disabled.
Sources:
Davis, Nicola.
"Monkeys Taught to Control Robotic Wheelchair by Thought
Alone." The Guardian. Guardian News and Media, 03 Mar. 2016.
Web. 17 Mar. 2016.
Rajangam, S. et al. Wireless Cortical
Brain-Machine Interface for Whole-Body Navigation in Primates. Sci.
Rep. 6, 22170; doi: 10.1038/srep22170 (2016).
I enjoyed reading your post very much. I wrote one similar to this, but bridges were created in the spinal cord instead of sensors in the brain. This topic interests me because I want to become an orthopedic surgeon but I also want to do research that helps amputees and paralyzed people use bio-mechanical limbs to use their extremities. Overall I really enjoyed your article.
ReplyDeleteThis is an incredible study! I am always amazed when they use monkeys in studies because they are so similiar to human beings. The fact that we could use these BMIs in individuals with disabilities so that they don't have to rely on someone else is just shocking to me. Technology has been coming so far in the medical field and it's incredible to see a study being put to work. I can't wait to see where this study goes!
ReplyDeleteI am still amazed that the capabilities of science and that they were able to apply the electrical impulses of the neurons to coordinate a robotic chair. This shows huge possibilities in terms of any sort of disability. Especially for those in wheel chairs. I also see these technologies being translated into prosthetics to give patients more independence and physical abilities.
ReplyDeleteWith all these advancements with helping paralyzed patients move their bodies without outside help, I would not be shocked to see any of the technologies created used on actual patients within the next decade. If the BMI are working this well with monkeys, human trials are not too far away hopefully since monkeys share almost an identical DNA sequence with humans. Also, since BMIs may lead to partial neurological recovery, this will probably further help paralyzed patients adapt to the sensors and utilize them better. I enjoyed reading your article very much and can't wait to see what is next for this study!
ReplyDeleteI feel like the use of this technology would be very beneficial in the creation of artificial legs and hands. If a person could control the movement of a mechanical object with the thoughts in their minds, it would allow them to move the fingers and grasp in object while using a mechanical arm. Either way, it is amazing how far technology has advanced just during my lifetime.
ReplyDeleteI hope that someday in the future, it is possible for people that are disabled to be able to live even more independent and normal lives than what they do now. Being confined to certain spaces or being able to only do limited tasks is not what it is worked up to be. Creating and then making that creation commercially available to others would bring about much needed positive change for disabled people. Things like mind-controlled movements, sensory-controlled robotics, can all improve the daily living of so many who are disabled. They go through a lot as it is. Making the lives of those who are disabled better would bring about positive change for everyone.
ReplyDeleteThis is interesting research, but, surgically implanting the brain-machine interface seems risky and expensive. I have just finished reading about treating spinal cord injury with a neural bridge. This seems currently a more effective treatment. It will only help a specific type spinal injury while the BMI will help more wide-spread neurological diseases. Hopefully, the implantation device can be simpler and more like a pacemaker.
ReplyDelete