With more than 15 million endoscope
procedures done on patients each year in the U.S. alone, scientists have
reported evidence that a new version of these flexible instruments for
diagnosing and treating disease shows promise for helping surgeons more
completely remove cancerous tumors.
Their
report on technology that combines the endoscope with the phenomenon
responsible for the eerie blue glow in the cooling water of nuclear reactors
was part of the 243rd National Meeting & Exposition of the American
Chemical Society (ACS).
"The
advance marries endoscopes to one of the newest and most exciting fields of
medical imaging," said Zhen Cheng, Ph.D., who led the research.
"Endoscopes are medical devices consisting of a long, thin, flexible tube
of optical fibers fitted with a light and a video camera. Doctors can insert
them through natural openings in the body or small surgical incisions to
diagnose and treat a wide range of diseases.
The new
approach expands the use of those fibers to include molecular-guided surgery to
remove more of a cancerous tumor than is currently possible."
Conventional
endoscopic methods allow doctors to see inside the stomach or colon, for
instance, and take biopsy samples for tests. The new imaging technology --
called Cerenkov Luminescence Endoscopy (CLE) -- has advantages over both
traditional endoscopic and imaging techniques, like MRI, in also providing
information about the functioning of the tissue, Cheng added.
Cheng,
who is with Stanford University, explained that CLE relies on the same
phenomenon responsible for the soft blue glow in the cooling water in the core
of nuclear power reactors. It results from interactions that occur when
invisible particles from the nuclear reaction in the core zip through the water
faster than the speed of light in water. The glow was named for its discoverer,
a Russian scientist, who won the 1958 Nobel Prize.
Cerenkov
Luminescence Imaging (CLI) emerged just a few years ago when scientists
discovered ways to harness the effect in devices that do not involve nuclear
power reactors. Excitement grew when laboratory experiments established that
CLI could produce images of organs and guide surgery in laboratory animals to
remove remaining cancer cells that otherwise would have been invisible to
surgeons.
Scientists
also found that CLI could dramatically improve the resolution of PET scans,
enabling PET scanners to detect smaller objects than previously possible.
Cerenkov luminescence was especially exciting because the light used to reveal
diseased tissue is visible light that can be detected with simple optical
sensors. It also is compatible with commercially available optical imaging
instruments and a wide selection of the nuclear imaging agents that doctors use
to make structures in the body visible.
"One
drawback however, is that the weak blue light -- unlike the X-rays in other
medical scans -- barely penetrates through deep tissues," Cheng said.
"This limits the usefulness of the technology in humans, where many tumors
develop in areas deep inside the body. Our marriage of Cerenkov luminescence
with the endoscope may be the perfect solution. With endoscopy, we can get
close enough to the diseased tissue to take advantage of this technology."
Cheng
pointed out that CLE's transition from laboratory to operating room, which may
occur during the next few years, should be relatively smooth because of its
similarity to traditional endoscopy. "Since the CLE system is an upgraded
version of endoscopy, it is highly compatible with conventional endoscopic
imaging requirements," he said.
The
scientists acknowledged funding from the National Institutes of Health, the
Department of Defense, the Canary Foundation, the Center for Biomedical Imaging
at Stanford and the Friends for an Earlier Breast Cancer Test.
ScienceDaily
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