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Nanowire Arrays Can Detect Signals
Along Individual Neurons
Opening a whole new interface between
nanotechnology and neuroscience, scientists at Harvard
University have used slender silicon nanowires to detect,
stimulate, and inhibit nerve signals along the axons
and dendrites of live mammalian neurons.
Harvard chemist Charles M. Lieber and colleagues report
on this marriage of nanowires and neurons this week
in the journal Science.
"We describe the first artificial synapses between
nanoelectronic devices and individual mammalian neurons,
and also the first linking of a solid-state device --
a nanowire transistor -- to the neuronal projections
that interconnect and carry information in the brain,"
says Lieber, the Mark Hyman, Jr., Professor of Chemistry
in Harvard's Faculty of Arts and Sciences and Division
of Engineering and Applied Sciences. "These extremely
local devices can detect, stimulate, and inhibit propagation
of neuronal signals with a spa-tial resolution unmatched
by existing techniques."
Electrophysiological measurements of brain activity
play an important role in understanding signal propagation
through individual neurons and neuronal networks, but
existing technologies are relatively crude: Micropipette
electrodes poked into cells are invasive and harmful,
and microfabricated electrode arrays are too bulky to
detect activity at the level of individual axons and
dendrites, the neuronal projections responsible for
electrical signal propagation and inter-neuron communication.
By contrast, the tiny nanowire transistors developed
by Lieber and colleagues gently touch a neuronal projection
to form a hybrid synapse, making them noninvasive, and
are thousands of times smaller than the electronics
now used to measure brain activity.
Lieber's group has previously shown that nanowires can
detect, with great precision, molecular markers indicating
the presence of cancer in the body, as well as single
viruses. Their latest work takes advantage of the size
similarities between ultra-fine silicon nanowires and
the axons and dendrites projecting from nerve cells:
Nanowires, like neuronal offshoots, are just tens of
nanometers in width, making the thin filaments a good
match for intercepting nerve signals.
Because the nanowires are so slight -- their contact
with a neuron is no more than 20 millionths of a meter
in length -- Lieber and colleagues were able to measure
and manipulate electrical conductance at as many as
50 locations along a single axon.
The current work involves measurement of signals only
within single mammalian neurons; the researchers are
now working toward monitoring signaling among larger
networks of nerve cells. Lieber says the devices could
also eventually be configured to measure or detect neurotransmitters,
the chemicals that leap synapses to carry electrical
impulses from one neuron to another.
"This work could have a revolutionary impact on
science and technology," Lieber says. "It
provides a powerful new approach for neuroscience to
study and manipulate signal propagation in neuronal
networks at a level unmatched by other techniques; it
provides a new paradigm for building sophisticated interfaces
between the brain and external neural prosthetics; it
represents a new, powerful, and flexible approach for
real-time cellular assays useful for drug discovery
and other applications; and it opens the possibility
for hybrid circuits that couple the strengths of digital
nanoelectronic and biological computing components."
Visit http://cmliris.harvard.edu
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