 |
| Proton Beam Therapy Prostate Cancer |
Researchers have succeeded in making a model of breathing movement
that allows for the precise measurement of narrow beams to a dummy tumor
by simulating the motion and physical properties of the chest anatomy
in a model. This research was presented at the 3rd ESTRO (European
Society for Therapeutic Radiology and Oncology) Forum in Barcelona,
Spain.
Radiotherapy using protons can deliver more accurate treatment to a
tumor while reducing the dose to surrounding tissue. However, in mobile
organs such as the lung, precise targeting of the dose is difficult.
Rosalind Perrin, PhD, from the Centre for Proton Therapy at the Paul
Scherrer Institute, Villigen, Switzerland, described the method she and
colleagues have developed to test the application of proton therapy to lung cancer.
The method uses a delivery technique called rescanning, which helps to
mitigate the effect of motion. The researchers are also working to
develop practical ways to implement it in the clinic for patient
treatments.
"This involved experiments using an advanced breathing model of the patient, a so-called anthropomorphic phantom,
with integrated measurement devices to accurately measure the dose
distribution. We found that our rescanning technique worked well to
overcome the effect of motion on the dose delivered to the tumor, and
for tumor motions of up to 1 cm," she said.
The model developed by the researchers was made up of a sphere
representing a tumor moving within an inflating lung, enclosed in a rib
cage complete with surrounding muscle and skin layers. The model can be
programmed to move with breathing patterns specific to each patient.
Radiation dosage was measured during movement, and the researchers
found that the rescanning technique allowed the application of
clinically acceptable dose distribution to the tumor, and only a minimal
dose to surrounding tissues.
Scanning proton therapy is an emerging technology in cancer therapy,
in which a narrow particle beam, consisting of accelerated hydrogen
nuclei, is scanned through the tumor and administers highly targeted
radiation to the cancer cells. Because protons have a relatively large mass, the beam delivers most
of its radiation dose towards the end of its path in tissue, and thus
proton therapy can be designed to limit dose to surrounding tissues.
Furthermore, a proton beam only penetrates the tissue up to a given
depth, determined by its energy. So, compared with conventional
radiotherapy techniques, the therapy allows a maximal dose to the tumor,
while reducing the dose elsewhere.
However, for mobile tumors in the liver or lung, organ and tumor
motion deteriorates the dose distribution because there may be a rift
between the radiation delivery time-line and the time-line of the tumor
motion: the interplay effect. The researchers have worked to
overcome this problem by developing a new, state-of-the art delivery
system, and the technology required by these advanced motion mitigation
methods is now operational. The rescanning technique involves scanning
the tumor several times by the proton beam.
"This makes it possible to average out the dose to the moving tumor,
and also reduce the effect of motion on the dose delivered to it.
Because of the sensitivity of the lung to radiation, as well as the
proximity of the heart, esophagus, and spinal cord, it is particularly
important to keep the radiation dose to surrounding tissues as low as
possible in lung cancer," said Perrin.
Original source: http://www.oncologynurseadvisor.com/web-exclusives/proton-radiotherapy-delivers-more-accurate-cancer-treatment-with-less-collateral-damage/article/415035/
No comments :
Post a Comment
Note: Only a member of this blog may post a comment.