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New Blood Test Could Detect Lung Cancer In Its Earliest
Stages
DURHAM, N.C. -- Lung cancer is often deadly
by the time doctors have detected it, but scientists at
Duke University Medical Center are developing a non-invasive
test that could detect lung cancer in its earliest stages,
while it is still treatable.
Their new diagnostic test employs an instrument called "MALDI-TOF
MS" to detect proteins in the blood that signal inflammatory
diseases and various cancers. Finding a disease-causing
protein is critical because it helps doctors diagnose the
disease and develop new ways to block its detrimental effects,
the researchers said.
Expanding on the MALDI-TOF MS technique, Duke radiologists
have identified a specific protein, serum amyloid A, which
is elevated in the blood of lung cancer patients but not
in the blood of normal patients. While serum amyloid A has
previously been shown to be elevated in cancers and other
diseases, the Duke team is the first to use MALDI-TOF MS
to identify this protein and others that may be involved
in lung cancer, said Edward Patz, M.D., professor of radiology
and pharmacology/cancer biology at Duke.
Based on his new findings, Patz plans to develop a blood
test that will measure serum amyloid A and other, more specific
proteins that can detect lung cancer in the blood before
a tumor is clinically apparent.
"Our technique is a new paradigm for identifying protein
targets in cancer, because we are zeroing in on the disease-causing
protein itself rather than searching for a defective gene
and then hunting down its relevant proteins," said
Patz.
Patz described his methods and results using MALDI-TOF MS
(matrix-assisted laser desorption/ionization time-of-flight
mass spectrometry) in two studies published in the September
2003 issue of the journal Proteomics.
The Duke studies are proof of principle that MALDI-TOF MS
can, in fact, pinpoint and identify proteins in blood that
are elevated in cancer and other diseases, said Patz. Moreover,
the Duke approach to MALDI-TOF is more sensitive than other
diagnostic techniques, he said. It generates more precise
information on protein expression because it can detect
proteins of low molecular mass, acidic or basic, and at
concentrations much lower than other methods.
"Using a MALDI-TOF MS platform is a particularly exciting
advance because current diagnostic tools -- such as PET
and CT scans -- have had no obvious impact on lung cancer
mortality rate over the last several decades," said
Patz. The overall five-year survival rate remains about
14 percent, despite major advances in genomics and drug
discovery.
Patz's approach is the reverse of how scientists generally
discover the genetics that underlie a disease. Typically,
researchers begin by isolating a defective gene, but a single
gene can produce many different proteins -- only one of
which may be the culprit in a particular disease process.
Identifying the relevant proteins in a disease puts scientists
much closer to developing novel diagnostic and therapeutic
targets, said Patz.
Once identified, the proteins can be used as biologic "markers"
to diagnose the earliest stages of cancer, possibly before
a PET scan or CT scan pick up the image of a tumor on the
lungs. Moreover, researchers can develop new drugs designed
to block a protein's unique role in causing cancer.
"The biology of lung cancer may have been played out
by the time we detect a tumor using imaging studies like
PET and CT scans," said Patz. "This is why we're
trying to develop very sensitive biomarkers that can detect
the disease in high-risk individuals early enough to treat
them successfully."
While MALDI-TOF MS is not unique to Duke, Patz has expanded
its use in novel ways. Not only does his team record the
protein "peaks" in blood samples, he then applies
a computer algorithm to each protein that identifies its
biologic role in the disease process. Patz calls it "fingerprinting"
the protein, and he will eventually use that information
to elucidate potential ways of blocking the protein's cancer-causing
effects in the cell.
The process begins by "fractionating" (dividing)
the sample, then feeding the samples into the mass spectrometer,
which electrically charges or "ionizes" the blood
proteins. The instrument then propels the proteins down
a flight tube at high velocity. The manner in which each
molecule lands determines its precise mass and hence its
level of "expression" in the blood.
Next, Patz's team performs an extra step: they take the
most significant protein peaks recorded by the instrument
and purify the samples repeatedly until they are able to
determine each protein's unique amino acid structure or
fingerprint.
"It is useful to know that you have a protein marker
for a disease, but it is far more useful to understand the
biology of that protein and use that knowledge to develop
strategies to combat the disease."
From a clinical perspective, the development of serum biomarkers
has benefits, as well. The technique requires only a blood
sample from the patient; hence, it is less invasive than
tissue biopsies. It is also more cost efficient and may
be much more accurate than CT and PET scans, said Patz.
http://www.dukemednews.org/
news/article.php?id=7037
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