DEVICE IDENTIFIES DRUGS THAT WILL WORK BEST FOE EACH PATIENT
More than 100 drugs
have been approved to treat cancer, but predicting which ones will help a
particular patient is an inexact science at best.
A new device developed at MIT may
change that. The implantable device, about the size of the grain of rice, can
carry small doses of up to 30 different drugs. After implanting it in a tumor
and letting the drugs diffuse into the tissue, researchers can measure how
effectively each one kills the patient's cancer cells.
Such a device could eliminate much
of the guesswork now involved in choosing cancer treatments, says Oliver Jonas,
a postdoc at MIT's Koch Institute for Integrative Cancer Research and lead
author of a paper describing the device in the April 22 issue of Science
Translational Medicine.
"You can use it to test a
patient for a range of available drugs, and pick the one that works best,"
Jonas says.
The paper's senior authors are
Robert Langer, the David H. Koch Professor at MIT and a member of the Koch
Institute, the Institute for Medical Engineering and Science, and the
Department of Chemical Engineering; and Michael Cima, the David H. Koch
Professor of Engineering at MIT and a member of the Koch Institute and the
Department of Materials Science and Engineering.
Putting the lab in the patient
Most of the commonly used cancer
drugs work by damaging DNA or otherwise interfering with cell function.
Recently, scientists have also developed more targeted drugs designed to kill
tumor cells that carry a specific genetic mutation. However, it is usually
difficult to predict whether a particular drug will be effective in an
individual patient.
In some cases, doctors extract tumor
cells, grow them in a lab dish, and treat them with different drugs to see
which ones are most effective. However, this process removes the cells from
their natural environment, which can play an important role in how a tumor
responds to drug treatment, Jonas says.
"The approach that we thought
would be good to try is to essentially put the lab into the patient," he
says. "It's safe and you can do all of your sensitivity testing in the
native microenvironment."
The device, made from a stiff,
crystalline polymer, can be implanted in a patient's tumor using a biopsy
needle. After implantation, drugs seep 200 to 300 microns into the tumor, but
do not overlap with each other. Any type of drug can go into the reservoir, and
the researchers can formulate the drugs so that the doses that reach the cancer
cells are similar to what they would receive if the drug were given by typical
delivery methods such as intravenous injection.
After one day of drug exposure, the
implant is removed, along with a small sample of the tumor tissue surrounding
it, and the researchers analyze the drug effects by slicing up the tissue
sample and staining it with antibodies that can detect markers of cell death or
proliferation.
Ranking cancer drugs
To test the device, the researchers
implanted it in mice that had been grafted with human prostate, breast, and
melanoma tumors. These tumors are known to have varying sensitivity to
different cancer drugs, and the MIT team's results corresponded to those
previously seen differences.
The researchers then tested the
device with a type of breast cancer known as triple negative, which lacks the
three most common breast cancer markers: estrogen receptor, progesterone
receptor, and Her2. This form of cancer is particularly aggressive, and none of
the drugs used against it are targeted to a specific genetic marker.
Using the device, the researchers
found that triple negative tumors responded differently to five of the drugs
commonly used to treat them. The most effective was paclitaxel, followed by
doxorubicin, cisplatin, gemcitabine, and lapatinib. They found the same results
when delivering these drugs by intravenous injection, suggesting that the
device is an accurate predictor of drug sensitivity.
In this study, the researchers
compared single drugs to each other, but the device could also be used to test
different drug combinations by putting two or three drugs into the same
reservoir, Jonas says.
"This device could help us
identify the best chemotherapy agents and combinations for every tumor prior to
starting systemic administration of chemotherapy, as opposed to making choices
based on population-based statistics. This has been a longstanding pursuit of
the oncology community and an important step toward our goal of developing
precision-based cancer therapy," says Jose Baselga, chief medical officer
at Memorial Sloan Kettering Cancer Center and an author of the paper.
The researchers are now working on
ways to make the device easier to read while it is still inside the patient,
allowing them to get results faster. They are also planning to launch a
clinical trial in breast cancer patients next year.
Another possible application for
this device is to guide the development and testing of new cancer drugs.
Researchers could create several different variants of a promising compound and
test them all at once in a small trial of human patients, allowing them to
choose the best one to carry on to a larger clinical trial.
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