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Engineering |
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Henry
Samueli School of Engineering and Applied Science |
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UCLA Engineers
Pioneer Lab-on-a-chip Blood Test
Handheld Unit Developed for Space Flight
Graduate student researchers Nan
Li and Charlotte Kwong with Professor Chih-Ming Ho |
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A team of mechanical and aerospace engineers at UCLA is developing
the tools needed to support NASA's vision of manned space flights
to the Moon and beyond.
Professor Chih-Ming Ho and graduate student researchers Nan Li and
Charlotte Kwong in the NASA-sponsored Institute for Cell Mimetic
Space Exploration are developing a system here on Earth for monitoring
astronauts' health on manned space flights.
"As we travel farther into space, the need for smaller, lighter
tools becomes even more critical," said Ho. "Current blood testing
systems are too bulky for space travel, so astronauts have to take
samples while still in space and bring them back to Earth for analysis."
The collaborative project, funded by the NASA National Space Biomedical
Research Institute is led by Ho, professor Yu-Chong Tai at the California
Institute of Technology, and Harvey Kasdan PhD '71, chief scientist
at IRIS International, Inc.
Current methods for analyzing blood chemistry require bulky equipment,
lab technicians and several milliliters of blood. None of which
are possible on board a space craft for routine health monitoring
or diagnosis of disease.
The size of a cell phone or PDA, the fully-automated testing system
under development will require only a drop of blood and provide
real-time clinical analysis. Such a lab-on-a-chip integrates all
of the required laboratory functions onto a single integrated circuit
that can be housed in a handheld unit.
The UCLA researchers are developing tools to measure the distribution
of white blood cells in humans-there are five different types-as
a way to gauge the health of astronauts during space travel. Members
of Ho's lab are developing a micromachine system, which includes
two main sub-systems, to manipulate the cells-one to remove ions
from the sample so that the fluid can be manipulated with an electrical
field and another to differentiate and count different groups of
blood cells.
"The prototype microdeionizer we have now is capable of removing
more than 90 percent of the ions in about 20 minutes," said Kwong.
"The two key elements in the device are a carbon aerogel electrode
and a dialysis membrane."
After a current is applied to the electrodes, an electric field
is created that forces the ions into the buffer channels along the
electric field. By developing an active method of ion extraction,
Kwong has substantially reduced the amount of time needed to remove
ions from a blood sample.
"Ion removal can be done solely by diffusion, which is passive,
but it will take hours, if not days, to reach the desired ion concentration,"
she noted. "And we chose carbon aerogel for our electrode material
because it allows us to design a compact deionizer instead of having
to build a huge tank."
Carbon aerogel offers a significantly increased surface area in
a compact system. For example, a 1.7 square millimeter of carbon
aerogel paper has an equivalent surface area of 12 square meters.
Her colleague Li is using hydrodynamics to move the cells into a
narrow channel so that only one cell at a time can move past an
integrated micro impedance detector to distinguish among the five
types of white blood cells in a sample.
In analyzing blood chemistry, cell counting and differentiation
of the various types of white blood cells is a useful tool. To limit
errors in analysis, however, the team needs to ensure that only
one cell is scanned at a time.
"We used a hydrodynamic focusing technique in our device to focus
the blood sample into a seven to 10 micrometer stream," explained
Li. "This is the dimension of white blood cells, and guarantees
that only one can pass through the detecting zone at a time."
Unlike conventional fluorescence-activated cell sorting (FACS) methods,
which require cell labeling and a complex optical system, the UCLA
system uses impedance spectroscopy, which applies a fast impedance
scan within a wide frequency range to differentiate the cells. It
is a non-invasive and label-free method that is compatible with
micromachining technology.
Having developed several working prototypes, the UCLA team is developing
a method to accurately differentiate between white blood cells with
very similar electrical properties.
"We also need to find a way to treat the surface of the microfluidic
device where the blood droplet is deposited to avoid contamination
and inaccurate results," added Ho.
To complete the lab-on-a-chip blood test system, Caltech is developing
microfluidic devices to separate red cells from white cells. Kasdan
is leading the IRIS team on system components and applying the company's
expertise to assemble the devices into a single working system.
Once developed, the system will have applications on Earth as well.
Because of the small quantity of blood required and system portability,
the unit may be used in neonatal units, as well as in remote locations.
The collaborators also are interested in developing other lab-on-a-chip
units for DNA analysis and other uses.
For more information on research in Ho's lab, please visit http://ho.seas.ucla.edu/.
- Marlys Amundson
Photos: Todd Cheney, UCLA Photography
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COPYRIGHT
2004 UCLA |
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