Nanowires In Blood Vessels May Help Monitor, Stimulate Neurons In The

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From: "Basie" <>

Subject: Nanowires In Blood Vessels May Help Monitor, Stimulate Neurons In The 
Brain
Date: Tue, 19 Jul 2005 17:23:11 -0400

Nanowires In Blood Vessels May Help Monitor, Stimulate Neurons In The Brain
Working with platinum nanowires 100 times thinner than a human hair--and 
using blood vessels as conduits to guide the wires--a team of U.S. and 
Japanese researchers has demonstrated a technique that may one day allow 
doctors to monitor individual brain cells and perhaps provide new treatments 
for neurological diseases such as Parkinson's.
Neuroscientist Rudolfo Llinas and his colleagues envision an entire array of 
nanowires being connected to a catheter tube, which could then be guided 
through the circulatory system to the brain. Once there, the nanowires would 
spread into a kind of bouquet, branching out into tinier and tinier blood 
vessels until they reached specific locations. Each nanowire would then be 
used to record the electrical activity of a single nerve cells, or small 
groups of nerve cells. (Credit: Zina Deretsky, National Science Foundation)
 Writing in the July 5, 2005, online issue of The Journal of Nanoparticle 
Research, the researchers explain it is becoming feasible to create 
nanowires far thinner than even the tiniest capillary vessels. That means 
nanowires could, in principle, be threaded through the circulatory system to 
any point in the body without blocking the normal flow of blood or 
interfering with the exchange of gasses and nutrients through the 
blood-vessel walls.
The team describes a proof-of-principle experiment in which they first 
guided platinum nanowires into the vascular system of tissue samples, and 
then successfully used the wires to detect the activity of individual 
neurons lying adjacent to the blood vessels.

Following the same logic, the researchers envision connecting an entire 
array of nanowires to a catheter tube that could then be guided through the 
circulatory system to the brain. Once there, the wires would spread into a 
"bouquet," branching out into tinier and tinier blood vessels until they 
reached specific locations. Each nanowire would then be used to record the 
electrical activity of a single nerve cell or small groups of them.

If the technique works, the researchers say, it would be a boon to 
scientists who study brain function. Current technologies, such as positron 
emission tomography (PET) scans and functional magnetic resonance imaging 
(fMRI), have revealed a great deal about how neural circuits process, say, 
visual information or language. But the view is still comparatively fuzzy 
and crude. By providing information on the scale of individual nerve cells, 
or "neurons," the nanowire technique could bring the picture into much 
sharper focus.

"In this case, we see the first-ever application of nanotechnology to 
understanding the brain at the neuron-to-neuron interaction level with a 
non-intrusive, biocompatible and biodegradable nano-probe," said Roco. "With 
careful attention to ethical issues, it promises entirely new areas of 
study, and ultimately could lead to new therapies and new ways of treating 
diseases. This illustrates the new generations of nanoscale active devices 
and complex nanosystems."

Likewise, the nanowire technique could greatly improve doctors' ability to 
pinpoint damage from injury and stroke, localize the cause of seizures, and 
detect the presence of tumors and other brain abnormalities. Better still, 
Llin s and his coauthors point out, the nanowires could deliver electrical 
impulses as well as receive them. So the technique has potential as a 
treatment for Parkinson's and similar diseases.

According to researchers, it's long been known that people with Parkinson's 
disease can experience significant improvement from direct stimulation of 
the affected area of the brain. Indeed, that is now a common treatment for 
patients who do not respond to medication. But the stimulation is currently 
carried out by inserting wires through the skull and into the brain, a 
process that can cause scarring of the brain tissue. The hope is, by 
stimulating the brain with nanowires threaded through pre-existing blood 
vessels, doctors could give patients the benefits of the treatment without 
the damaging side effects.

One challenge is to precisely guide the nanowire probes to a predetermined 
spot through the thousands of branches in the brain's vascular system. One 
promising solution, the authors say, is to replace the platinum nanowires 
with new conducting polymer nanowires. Not only do the polymers conduct 
electrical impulses, conductive, they change shape in response to electric 
fields, which would allow the researchers to steer the nanowires through the 
brain's circulatory system. Polymer nanowires have the added benefit of 
being 20 to 30 times smaller than the platinum ones used in the reported 
laboratory experiments. They also will be biodegradable, and therefore 
suitable for short-term brain implants.

"This new class of materials is an attractive tool for nanotechnology," said 
MIT's Anquetil. "The large degrees of freedom that they offer synthetically 
allow the rational design of their properties."

http://www.sciencedaily.com/releases/2005/07/050718234252.htm

Basie

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