Pentagon Research Could Make ‘Brain Modem’ a Reality
Pentagon Research Could Make ‘Brain Modem’ a Reality
02.26.16 9:05 PM ET
The tiny injectable machine could turn your noodle into a
remote control.
The Pentagon is attempting what was, until recently, an
impossible technological feat—developing a high-bandwidth neural interface that
would allow people to beam data from their minds to external devices and back.
That’s right—a brain modem. One that could allow a
soldier to, for example, control a drone with his mind.
This seemingly unlikely piece of technology has just
gotten a lot less unlikely. On Feb. 8, the Defense Advanced Research Projects
Agency (DARPA)—the U.S. military’s fringe-science wing—announced the first
successful tests, on animal subjects, of a tiny sensor that travels through
blood vessels, lodges in the brain and records neural activity.
The so-called “stentrode,” a combination stent and
electrode, is the size of a paperclip and flexible. The tiny, injectable
machine—the invention of neurologist Tom Oxley and his team at the University
of Melbourne in Australia—could help researchers solve one of the most vexing
problems with the brain modem: how to insert a transmitter into the brain
without also drilling a hole in the user’s head, a risky procedure under any
circumstances.
Based on existing stents that doctors use to clean blood
vessels, the stentrode includes sensors and a tiny transmitter. Entering the
bloodstream via a catheter, the stentrode swims in the bloodstream.
Doctors monitor the stentrode on its journey through the
circulatory system. When the device reaches the brain, the physicians command
it to expand against the blood vessels’ walls and hold station. There it
remains for potentially months at a time, recording and relaying the subtle
electrical signals that flow from the brain to the rest of the body.
“By reducing the need for invasive surgery, the stentrode
may pave the way for more practical implementations of those kinds of
life-changing applications of brain-machine interfaces,” Doug Weber, a DARPA
program manager, said in a statement.
With DARPA funding beginning four years ago, Oxley and
his team tested the stentrode on sheep, he and his teammates explained in an
academic paper published in the journal Nature Biotechnology in early February.
In other words, the neurologist injected tiny sensors
into some unwitting livestocks’ veins and, for six months, recorded the
electrical impulses that control the animals’ movements.
According to DARPA, Oxley and his fellow researchers plan
to test the stentrode on human patients as early as 2017 at the Royal Melbourne
Hospital. Military experimentation could follow.
There are some dangers associated with the technology,
Oxley told The Daily Beast. All stents run the risk of causing blood clots and
strokes. But Oxley said that injecting the stentrode into a vein (which carries
blood to the heart) rather than an artery (which carries blood from the heart)
minimizes the stroke risk.
Even if the stentrode is fairly safe, it’s not clear that
it will work the way the military wants it to. Oxley said he still doesn’t know
whether the stentrode will be able to record the kind of fine data that DARPA
would like its brain modem to handle.
Sensors resting directly on top of a brain during surgery
have proved recently that they can detect neural activity at the level of a
single brain cell. But a stent might not be able to achieve the same level of
precision.
“Because it is located within the blood vessels of the
brain, the stentrode will only be able to record electrical signals from large
groups of brain cells,” Bradley Greger, a neural engineer at Arizona State
University, told The Daily Beast.
But Oxley stressed that his stentrode is just a
prototype. It should get better, he said. “The field of stenting is rapidly progressing.”
And the military’s demographics could give the stentrode
a fertile testing ground. The human brain shrinks as it ages, increasing the
distance between the organ and surrounding blood vessels. It could be easier
for a stentrode to detect neural activity in a younger person with a “fuller”
brain.
As it happens, the military employs a disproportionate
number of young people.
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