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ITHACA,
N.Y. -- By using a device only six-millionths of a
meter long, researchers at Cornell University have
been able to detect the presence of as few as a half-dozen
viruses -- and they believe the device is sensitive
enough to notice just one.
The research could lead to
simple detectors capable of differentiating between
a wide variety of pathogens, including viruses, bacteria
and toxic organic chemicals.
The experiment, an extension
of earlier work in which similar devices were used
to detect the mass of a single bacterium, is reported
in a paper, "Virus detection using nanoelectromechanical
devices," in the September 27, 2004, issue of
Applied Physics Letters by Cornell research associate
Rob Ilic of the Cornell NanoScale Facility (CNF),
Yanou Yang, a Cornell graduate student in biomedical
engineering, and Harold Craighead, Cornell professor
of applied and engineering physics. The work was done
with the assistance of Michael Shuler, Cornell professor
of chemical and biological engineering, and microbiologist
Gary Blissard of the Boyce Thompson Institute for
Plant Research on the Cornell campus.
At
CNF, the researchers created arrays of tiny silicon
paddles from 6 to 10 micrometers (millionths of a
meter) long, half a micrometer wide, and about 150
nanometers (billionths of a meter) thick, with a one-micrometer
square pad at the end. Think of a tiny fly-swatter
mounted by its handle like a diving board. A large
array of paddles were mounted on a piezoelectric crystal
that can be made to vibrate at frequencies on the
order of 5 to 10 megaHertz (mHz). The experimenters
then varied the frequency of vibration of the crystal.
When it matched the paddles' resonant frequency, the
paddles began to vibrate, as measured by focusing
a laser on the paddles and noting the change in reflected
light, a process called optical interferometry.
The natural resonant frequency
at which something vibrates depends on, among other
things, its mass. A thick, heavy guitar string, for
example, vibrates at a lower tone than a thin, light
one. A single one of these silicon paddle weighs about
1.2 picograms, and vibrates at frequencies in the
neighborhood of 10 megaHertz.
The virus used in the experiment weighs about 1.5
femtograms. (A picogram is 1/1,000,000,000,000th of
a gram, and a femtogram is 1/1000th of a picogram.)
Adding just a few virus particles to a paddle turns
out to be enough to change its resonant frequency
by about 10 kiloHertz (kHz), which is easily observable.
To trap viruses, the researchers
coated the paddles with antibodies specific to Autographa
californica nuclear polyhedrosis virus, a nonpathogenic
insect baculovirus widely used in research. The paddle
arrays were then bathed in a solution containing the
virus, causing virus particles to adhere to the antibodies.
Because air damps the vibration and greatly reduces
the "Q," or selectivity, of the system,
the treated paddles were placed in a vacuum for testing.
From the frequency shift of about 10 kHz the researchers
calculated that an average of about six virus particles
had adhered to each paddle. It might be possible,
the researchers say, to demonstrate detection of single
particles by further diluting the virus solution.
The system also can differentiate between various
virus concentrations, they say.
As expected, the smallest paddles
were the most sensitive. The researchers calculated
that the minimum detectable mass for a six-micrometer
paddle would be .41 attograms (an attogram is 1/1000th
of a femtogram.) This opens the possibility that the
method could be used to detect individual organic
molecules, such as DNA or proteins.
Other
members of the Craighead Research Group at Cornell
have experimented with "nanofluidics," creating
microscopic channels on silicon chips through which
organic molecules can be transported, separated or
even counted. Ilic speculates that a simple field
detector for pathogens -- the much-heralded "laboratory
on a chip" -- could be built by combining a paddle
oscillator detector with a nanofluidic system that
would bathe the paddles in a suspect sample, then
automatically evacuate the chamber to a vacuum for
testing.
Arrays of paddles coated with various antibodies could
allow testing for a wide variety of pathogens at the
same time.
Related World Wide Web sites:
The following sites provide additional information
on this news release. Some might not be part of the
Cornell University community, and Cornell has no control
over their content or availability.
o The Craighead Research Group:
<http://www.hgc.cornell.edu>
o Previous Cornell news release
on detecting a single bacterium:
<http://www.news.cornell.edu/releases/April04/attograms.ws.html>
Cornell
University News Service
Surge 3
Cornell University
Ithaca, NY 14853
607-255-4206
cunews@cornell.edu
http://www.news.cornell.edu
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