NEW MEDICAL DEVICE CONCEPT COULD REDUCE TIME TO DIAGNOSE INFECTIONS
When a patient arrives at a hospital with a
serious infection, doctors have precious few minutes to make an accurate
diagnosis and prescribe treatment accordingly. Doctors' ability to act quickly
and correctly not only makes a difference to the patient's outcome, it
determines whether the infection spreads to other patients in the clinic, and
can even contribute to the development of drug-resistant bacteria
Luckily
for patients and doctors alike, a new diagnostic device created by
collaborative team of UA engineers and scientists may significantly reduce the
amount of time necessary to diagnose tissue infections. The device's novel
approach to molecular diagnostics, called DOTS qPCR, is faster, more efficient
and less expensive than alternatives currently being used in clinics. The work
is described online in the journal Science Advances.
"We
have developed a completely different type of system than what exists out on
the market," said Dustin Harshman, a former graduate student in the
Biomedical Engineering Graduate Interdisciplinary Program, currently a
scientist at Ventana Medical Systems. "We want to see physicians get
diagnostic information more rapidly and prescribe better initial
therapies."
Pathogens
and infectious diseases are typically detected using a technique called
polymerase chain reaction, or PCR. The method involves rapidly heating and
cooling DNA molecules from a biological sample in a process called thermal
cycling. This results in the amplification of the target DNA into millions, and
even billions of copies. Scientists and physicians can then use the copies to
identify the type of pathogen causing the infection. The problem is that most
PCR tests can take up to an hour or more, and a physician's decision-making
window is typically less than ten minutes.
"With
DOTS qPCR we are able to detect amplification and identify the infection after
as few as 4 thermal cycles, while other methods are working with between 18 and
30," said Jeong-Yeol Yoon, a professor in the Department of Agricultural
and Biosystems Engineering and a joint appointment in the Department of
Biomedical Engineering. "We can get from sample to answer in as little as
3 minutes and 30 seconds."
DOTS
qPCR, invented by Yoon and his research group, stands for
droplet-on-thermocouple silhouette real-time PCR. The technology relies on the
measurement of subtle surface tension changes at the interface of a water
droplet suspended in an oil medium. The water droplet, which contains the
target DNA to be amplified, is moved along a heat gradient in the oil to begin
the chain reaction. As more copies of the target DNA are produced, they move
towards the oil-water interface, resulting in measurable changes in surface
tension. Remarkably, the size of the droplet can be measured using a smartphone
camera, providing a method to observe the course of the reaction in real time.
"What's
interesting about the way we approached this is that we've developed a deep
understanding of what's happening at a molecular level in our system,"
said Harshman, who initially struggled to determine how to monitor the course
of the reaction. "That kind of understanding gave us the ability to figure
out why it was failing, and then leverage that failure as an advantage to
create a completely new method."
In
addition to much faster diagnosis times, the system does not require samples to
be completely free of other contaminants. This can save valuable time otherwise
spent preparing samples for testing.
"The
system still works with relatively dirty samples," said Yoon. "We can
use very minimal processing and still make the detection in a short time."
Yoon
emphasized that DOTS qPCR is inexpensive compared to its counterparts, which
employ costly and time-intensive testing methods involving fluorescence
detection, lasers and dark chambers.
"It's
easy to use, smartphone-integrated and saves money and labor using expensive
equipment," explained Yoon. "This technology has a lot of commercial
potential, and we'd be happy to work with industry to bring it to market."
DOTS
qPCR also has major applications in biological research, where PCR is an
indispensable tool used in studying everything from hereditary disease to the
evolutionary tree. Ultimately, Harshman and Yoon hope the technology will
transform the operations of hospital emergency rooms, where saving time to
diagnosis translates into saving lives.
"We're
envisioning a device that will provide physicians with answers as soon as they
perform a biopsy, while they're still sitting with the patient," said
Harshman. "By saving diagnosis time, we can decrease complications for
patients, isolate infections to prevent spreading, and avoid creating selective
pressure for antibiotic-resistant bacteria, which is a huge burden on the
medical system."
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