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Super-small
nanoelectrodes can probe microscale environments
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[March 30, 2007]
CHAMPAIGN -- Investigating the composition and
behavior of microscale environments, including those within living
cells, could become easier and more precise with nanoelectrodes
being developed at the University of Illinois.
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"The individual nanotube-based probes can be used for
electrochemical and biochemical sensing," said Min-Feng Yu, a U of I
professor of mechanical science and engineering, and a researcher at
the university's Beckman Institute. "The position of the
nanoelectrodes can be controlled very accurately." To fabricate
the nanoelectrodes, Yu and graduate students Kyungsuk Yum, Jie Hu
and Han Na Cho begin by attaching a strong, rigid boron-nitride
nanotube to a much larger conductive probe. The nanotube will form
the insulating core of the nanoelectrode.
The researchers then coat the nanotube with a thin film of gold
about 10-50 nanometers thick (a nanometer is 1 billionth of a
meter.) The gold layer is then coated with an insulating polymer
coating about 10 nanometers thick. Lastly, the researchers use a
focused ion beam to slice off the end of the nanotube, exposing a
conducting ring of gold sandwiched between an insulating core and an
insulating outer ring.
The process yields nanoelectrodes with a diameter of 100
nanometers and a length of up to 30 microns.
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 Because the nanotube is attached to a much larger probe, the
researchers can manipulate the nanotube like a needle. They can
control precisely where the nanotube penetrates a cell, for example,
and even pinpoint smaller cell structures, such as the nucleus or
mitochondrion.
"Nanoelectrodes offer new opportunities for electrochemical
sensing in intracellular environments," said Yu, who described the
fabrication process and demonstrated the feasibility of
nanoelectrodes at the March meeting of the American Physical Society
in Denver. "By functionalizing the active area of the nanoelectrode
with an appropriate chemical, we can target the detection of
specific chemical species."
The researchers have demonstrated that their nanoelectrode can
sense the chemical environment within a droplet 10 microns in
diameter. Their next step is to show that the probe can penetrate
the cellular membrane of a living cell without damaging the cell.
The National Science Foundation and the University of Illinois
funded the work.
[Text from
news release from the University of Illinois at Urbana-Champaign]
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