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Perangkat
laser dapat mengakhiri pin pricks, meningkatkan kualitas hidup bagi penderita
diabetes
Para
peneliti telah mengembangkan cara untuk menggunakan laser untuk mengukur gula
darah , dan dengan lebih banyak pekerjaan untuk mengecilkan sistem laser untuk
ukuran portabel, teknik memungkinkan penderita diabetes untuk memeriksa kondisi
mereka .... Dalam
sebuah artikel baru, para peneliti menjelaskan bagaimana mereka diukur gula
darah dengan mengarahkan laser khusus mereka .............
Laser device may end pin pricks, improve quality of life for diabetics
Date:
August 21,
2014
Source:
Princeton University, Engineering
School
Summary:
Researchers have developed a way to
use a laser to measure people's blood sugar, and, with more work to shrink the
laser system to a portable size, the technique could allow diabetics to check
their condition without pricking themselves to draw blood. In a new article,
the researchers describe how they measured blood sugar by directing their
specialized laser at a person's palm.
...........................
Princeton University researchers have developed a way to use
a laser to measure people's blood sugar, and, with more work to shrink the
laser system to a portable size, the technique could allow diabetics to check
their condition without pricking themselves to draw blood.
"We are
working hard to turn engineering solutions into useful tools for people to use
in their daily lives," said Claire Gmachl, the Eugene Higgins Professor of
Electrical Engineering and the project's senior researcher. "With this
work we hope to improve the lives of many diabetes sufferers who depend on
frequent blood glucose monitoring."
In an
article published June 23 in the journal Biomedical Optics Express, the
researchers describe how they measured blood sugar by directing their
specialized laser at a person's palm. The laser passes through the skin cells,
without causing damage, and is partially absorbed by the sugar molecules in the
patient's body. The researchers use the amount of absorption to measure the
level of blood sugar.
Sabbir
Liakat, the paper's lead author, said the team was pleasantly surprised at the
accuracy of the method. Glucose monitors are required to produce a blood-sugar
reading within 20 percent of the patient's actual level; even an early version
of the system met that standard. The current version is 84 percent accurate,
Liakat said.
"It
works now but we are still trying to improve it," said Liakat, a graduate
student in electrical engineering.
When the
team first started, the laser was an experimental setup that filled up a
moderate-sized workbench. It also needed an elaborate cooling system to work.
Gmachl said the researchers have solved the cooling problem, so the laser works
at room temperature. The next step is to shrink it.
"This
summer, we are working to get the system on a mobile platform to take it places
such as clinics to get more measurements," Liakat said. "We are
looking for a larger dataset of measurements to work with."
The key to
the system is the infrared laser's frequency. What our eyes perceive as color
is created by light's frequency (the number of light waves that pass a point in
a certain time). Red is the lowest frequency of light that humans normally can
see, and infrared's frequency is below that level. Current medical devices
often use the "near-infrared," which is just beyond what the eye can
see. This frequency is not blocked by water, so it can be used in the body,
which is largely made up of water. But it does interact with many acids and
chemicals in the skin, so it makes it impractical to use for detecting blood
sugar.
Mid-infrared
light, however, is not as much affected by these other chemicals, so it works
well for blood sugar. But mid-infrared light is difficult to harness with standard
lasers. It also requires relatively high power and stability to penetrate the
skin and scatter off bodily fluid. (The target is not the blood but fluid
called dermal interstitial fluid, which has a strong correlation with blood
sugar.)
The
breakthrough came from the use of a new type of device that is particularly
adept at producing mid-infrared frequencies -- a quantum cascade laser.
In many
lasers, the frequency of the beam depends on the material that makes up the
laser -- a helium-neon laser, for example, produces a certain frequency band of
light. But in a quantum cascade laser, in which electrons pass through a
"cascade" of semiconductor layers, the beam can be set to one of a
number of different frequencies. The ability to specify the frequency allowed
the researchers to produce a laser in the mid-infrared region. Recent
improvements in quantum cascade lasers also provided for increased power and
stability needed to penetrate the skin.
To conduct
their experiment, the researchers used the laser to measure the blood sugar of
three healthy people before and after they each ate 20 jellybeans, which raise
blood sugar levels. The researchers also checked the measurements with a
finger-prick test. They conducted the measurements repeatedly over several
weeks.
The
researchers said their results indicated that the laser measurements readings
produced average errors somewhat larger than the standard blood sugar monitors,
but remained within the clinical requirement for accuracy.
"Because
the quantum cascade laser can be designed to emit light across a very wide
wavelength range, its usability is not just for glucose detection, but could
conceivably be used for other medical sensing and monitoring
applications," Gmachl said.
Story
Source:
The above
story is based on materials provided by Princeton University, Engineering
School. Note:
Materials may be edited for content and length.
Journal
Reference:
- Sabbir Liakat, Kevin A. Bors, Laura Xu, Callie M. Woods, Jessica Doyle, Claire F. Gmachl. Noninvasive in vivo glucose sensing on human subjects using mid-infrared light. Biomedical Optics Express, 2014; 5 (7): 2397 DOI: 10.1364/BOE.5.002397
