Sensors
printed on spot smaller than dime
Provisional
patent filed on work by chemists that could transform sensor technology
By
ELLEN GOLDBAUM
Contributing Editor
By borrowing
a page from the genomics revolution, UB chemists have taken a major
step toward placing hundreds, and possibly even thousands, of reusable
chemical sensors in an area smaller than a dime.
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UB
researchers pinprinted a UB logo onto a light-emitting diode using
a new technique for making microsensors. |
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Their work,
published in the March 1 issue of Analytical Chemistry, which
currently is online, could transform sensor technology by providing
agricultural, clinical, environmental and pharmaceutical laboratories
with a small, fast and portable methodology for simultaneously detecting
numerous chemicals in a sample a hundred or a thousand times smaller
than a drop of water.
A provisional
patent has been filed.
The research
overcomes a key obstacle in exploiting high-tech materials, called xerogels,
into which the UB team has pioneered investigations as the basis of
new chemical sensors.
Xerogels
are porous glasses, developed through sol-gel processing techniques
in which a special solution reacts to form a porous polymer. The resulting
xerogel is a rigid material, like a glass, only it consists of an intricate
network of nanoscopic pores. In past work, the UB group has developed
innovative ways to stabilize and trap proteins within the xerogels.
These proteins then can be put to work to signal the presence of important
chemicals in a sample.
"We now
understand very well the chemistry involved in making good xerogels
that contain active proteins," said Frank V. Bright, co-author and associate
chair and professor in the Department of Chemistry in the College of
Arts and Sciences.
The problem
with traditional xerogel-based sensors, he explained, is that they are
large and designed to detect only one chemical species. The UB researchers
wanted to shrink down all of the sensor technology so they could place
multiple sensors in a small area and obtain information on the presence
of many chemicals in a single, small sample.
"The process
of having to analyze for different molecules one at a time is amazingly
time-consuming, and it turns out to waste a whole lot of the sample,"
said Bright.
Initially,
Bright and Eon Jeong Cho, lead author and doctoral candidate in the
Department of Chemistry, micromachined wells that were on the order
of 1/25,000th of an inch in diameter on top of a light-emitting diode
(LED), a tiny, inexpensive chip made of semiconducting materials that
can turn electrical energy into light.
"Using
our xerogels in these wells on a LED was a great idea on paper, but
the volume of a well turns out to be fairly small, about a billionth
of a quart," said Bright. "Trying to fill the wells turned out to be
a nightmare."
But then
Cho suggested pin-printing, a technology widely used in genomics in
which an extremely thin pin point sucks up by capillary action small
volumes of solution and deposits or prints them onto microscope slides.
Using a
commercial pin-printer, just like those hard at work in DNA microarray
facilities, the UB team suddenly had conquered the problem.
"Pin-printing
is like taking a tiny quill pen, dipping it into a solution and instead
of filling wells, we contact-print the sol-gel solution onto the surface
directly to form an array of xerogel-based sensors; we no longer need
wells at all," Bright said.
"Because
the volume delivered by these pin-printers is less than a trillionth
of a quart, the sensors are very small, so we can cram many different
sensors in a small footprint and, in principle, detect hundreds or even
thousands of chemical species simultaneously."
Bright
and his team now are working on pin-printing chemical sensors onto the
top of an LED to form a fully self-contained sensor-array platform.
The work
was funded by the National Science Foundation.
