NYU and MIT researchers have developed a flexible electrode that can send or receive signals from brain cells. The electrode can be inserted into the brain through blood vessels, eliminating the need to open a patient's skull for some neurological treatments. (Courtesy of Zina Deretsky, National Science Foundation.)
Nanowires could make brain-machine interfaces safer and cochlear implants more effective.
A new type of polymer nano electrode could make brain implants, including those used to treat severe cases of Parkinson's, far safer, and it could also make attempts to restore vision and movement with direct brain-machine interfaces more feasible. Rodolfo Llinas, professor of neuroscience at New York University, and researchers at MIT have developed a nanowire electrode just 600 nanometers wide that can send and receive signals to the brain.
The electrode developed by Llinas and coworkers is so small that it could be inserted through an artery, perhaps in the arm or groin, and threaded up to the brain. Because the electrode is a small fraction of the size of a red-blood cell and flexible, it can be snaked through the smallest blood vessels, getting close enough to neurons deep in the brain to detect and deliver electrical signals.
[Click here for images of the electrode in blood vessels.]
One current treatment for severe cases of Parkinson's, called deep brain stimulation, involves implanting electrodes that deliver high-frequency electrical pulses which shut down parts of the brain responsible for the disease's symptoms (see "Brain Pacemakers"). Such treatments, however, are risky and expensive, in part, because they require that a patient's skull be opened to surgically insert electrodes into brain tissue.
The conventional electrodes, which now measure in millimeters, can also damage blood vessels in the brain, says Joseph Pancrazio, program director for neural engineering projects at the National Institute of Neurological Disorders and Stroke (NINDS), one of the National Institutes of Health. "By taking advantage of the nanodimensions to thread the electrodes through the vasculature, you may reduce the risk of stroke," he says. "This is a completely out-of-the box way to think about enabling deep-brain stimulation. I think there may be payoffs in terms of safety, efficacy, robustness, and biocompatibility. It certainly is an area that we need to look at seriously."
"Not having to open the skull would be a clear benefit over what we're now doing," says Jeff Bronstein, neurologist at the UCLA Medical School, who says thousands of Parkinson's patients have undergone the deep brain stimulation procedures.
John Heiss, a neurosurgeon at NINDS, cautions that it will first be necessary to demonstrate that the nanowires do not cause complications, such as blood clots. He also notes that, although the head would not need to be opened, such a procedure would still require some invasive surgery. Heiss says, however, that if the procedure proves to be safe, it could make deep brain stimulation a more attractive alternative at earlier stages of Parkinson's.
A patient has received the first ear implant to treat a balance disorder; researchers hope it leads to similar devices that are even more complex.
A new kind of sensor could allow for long-term medical monitoring--without direct skin contact.
Guest (nanotechbuzz.com)
Now the question is, where will we draw the line? Few people will argue against nanoelectrode implants for treating parkinson's, but what about implants for human enhancement? Our brains are good at some things and computers are good at others. The temptation to employ nanotechnologies like this one to enhance our mental and phsical capabilities will be great. But is it the right thing to do?
Guest (ddb)
This sort of technology has "existed" in the sci-fi world for a long time. For some it seems like a logical next step, for others an abomination. Advances such as these are always seen as different ends of an extreme, I only hope the decision is left up to individuals and not mandated by society.
Guest (turnstyle)
This leads to another theme in Sci-Fi of the divide between human & post human. We are only seeing the very start of this. Will you be a new Quaker? or do you want to surf the web by bitting your lip?
Guest (Purushotham)
Treatments for Diffuse Cerebral injury and post traumatic hydrocephalus.
Hi,
My father met an accident in 2002 and he is still in medication. doctors found his situation as Diffuse Cerebral injury, post traumatic hydrocephalus. Can anyone please tell me what are the good treatments available for his improvement?
my mail id is arpurush@yahoo.com
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Guest (Tom Schaefer)
Wired? I doubt it.
Dollars to donuts that a nano scale wireless solution will be found and overtake this. Just consider the impedance of a very thin wire multiple centimeters in length. I thin tis tech will have applications, but only locally within the brain, not to carry signals in and out of it.
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Guest (Treehorn)
Wireless
The issue with a completely wireless instrument is how you supply the power. You would have to have an internal power source (battery) or external power source (a wire delivering current). Another option would be to have a device that was inductively charged (such as an RFID chip), however without knowing the details of the voltage/current delivered for this treatment, I would think that a nano-scale instrument would not be able to provide the required power or would need an antenna that would be too big for this type of application in the brain.
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