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Scientists Develop New, Molecular
Approach to Early Cancer Detection
Scientists have pioneered a new approach to detecting
cancer cells, one that could eventually allow doctors
to discover many malignancies earlier than currently
possible.
The scientists at the University of Florida have successfully
tested the technique to find leukemia cells and believe
that it opens the door to the first systematic approach
to diagnosing cancer at the molecular level. Not only
that, but what they describe as a potentially new cancer
probe may one day offer a better method of targeting
individual cancer cells with drug therapies, reducing
side effects from chemotherapy treatments that today
affect both healthy and sickly cells.
“We can use this probe to recognize cancer cells,”
potentially discovering cancer earlier than often occurs
today, said Dihua Shangguan, a UF postdoctoral associate
in chemistry.
Contrary to popular perception, pathologists today diagnose
the vast majority of cancers based on the shape or other
characteristics of tumor tissue or diseased cells, said
Ying Li, one of nine UF faculty members and graduate
student co-authors of the paper. That’s a problem
because it often means that cancers may already be advanced
when detected.
“Normally, definitive diagnosis of cancer requires
a visual examination of the tumor, which is an invasive
and time-consuming process,” explained Weihong
Tan, a UF professor of chemistry and lead author of
the paper. “Most importantly, this process is
not suitable for early detection, when the cancer is
at its most treatable.”
Clinicians can sometimes use antibodies, proteins that
recognize and fight bodily intruders, to identify different
types of cancer. That’s the case, for example,
with the prostate-specific antigen test for prostate
cancer. Antibodies are preferable to diagnosis by appearance
because they are consistent and accurate, but they are
only available for a selected few cancers, Li said.
Tan, a member of the UF Shands Cancer Center and the
UF Genetics Institute, said that scientists know that
cancer tissue has a unique molecular fingerprint that
can distinguish it from healthy tissue. But attempts
to target cells via these fingerprints have largely
proved futile because there are few molecular tools
to recognize the fingerprints. The UF team sought to
create these tools in the form of aptamers, or short
strands of chemically synthesized DNA. These aptamers
exploit the differences on the surface of cells to discern
cancerous ones. Key to the approach is it does not require
prior knowledge of cancer indicators, Tan said.
“Using the cell-based aptamer selection strategy,
we can generate aptamers which can specifically recognize
any kind of cells without prior knowledge of molecular
changes associated with the disease,” he said.
In experiments, the researchers showed they could successfully
design sets of aptamers that would recognize leukemia
cells that had been mixed in with normal bone marrow
cells. The aptamers also successfully distinguished
leukemia T-cells from lymphoma B-cells. Both results
indicate that the aptamer method could be used to identify
many different types of cancer, researchers said.
Clinicians using such molecular probes should be able
to “find cancer in a much earlier stage when the
tumors are much smaller,” enabling doctors to
begin treatment earlier, Li said.
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