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Cherenkov Effect improves radiation therapy for patients with cancer

Date:
February 25, 2015
Source:
Norris Cotton Cancer Center Dartmouth-Hitchcock Medical Center
Summary:
The complex parts of the blue light known as the Cherenkov Effect can be measured and used in dosimetry to make therapies safer and more effective, scientists report.
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"The beauty of using the light from the Cherenkov Effect for dosimetry is that it's the only current method that can reveal dosimetric information completely non-invasively in water or tissue," said Glaser.
Credit: Image courtesy of Norris Cotton Cancer Center Dartmouth-Hitchcock Medical Center

The characteristic blue glow from a nuclear reactor is present in radiation therapy, too. Investigators from Dartmouth's Norris Cotton Cancer Center, led by Brian W. Pogue, PhD, and PhD candidates Adam K. Glaser and Rongxiao Zhang, published in Physics in Medicine and Biology how the complex parts of the blue light known as the Cherenkov Effect can be measured and used in dosimetry to make therapies safer and more effective.

"The beauty of using the light from the Cherenkov Effect for dosimetry is that it's the only current method that can reveal dosimetric information completely non-invasively in water or tissue," said Glaser.

Although the phenomenon has been constructively utilized for decades in high-energy particle and astrophysics, only recently has it been investigated during radiation therapy. In this study, investigators separately measured emissions of x-ray photons, protons, and electrons and they found widely varying utility.

Based on the findings of where dose correlates with Cherenkov emission, the Dartmouth team concluded that, for x-ray photons, the light emission would be optimally suited for: narrow beam stereotactic radiation therapy and surgery validation studies, verification of dynamic intensity-modulated and volumetric modulated arc therapy treatment plans in water tanks, near mono-energetic sources (e.g., Co-60 and brachy therapy sources), and also for entrance and exit surface imaging dosimetry of both narrow and broad beams. For electron use, Cherenkov emission was found to be only suitable for surface dosimetry applications. Finally, for proton dosimetry, there exists a fundamental lack of Cherenkov emission at the Bragg peak, making the technique of little use, although investigators say that post-irradiation detection of light emission from radioisotopes could prove to be useful.

"By detecting this light, we can pursue novel applications of Cherenkov light emission during radiation therapy to help clinicians improve the overall treatment outcome for patients," explained Pogue.

The collaborators intend to pursue further investigation at Norris Cotton Cancer Center to find other applications where this "free" light can be useful, such as continuing clinical trials in which the Cherenkov light from x-ray beams is imaged directly from a patient's tissue surface during radiation therapy.


Story Source:

Materials provided by Norris Cotton Cancer Center Dartmouth-Hitchcock Medical Center. Note: Content may be edited for style and length.


Journal Reference:

  1. Adam K Glaser, Rongxiao Zhang, David J Gladstone, Brian W Pogue. Optical dosimetry of radiotherapy beams using Cherenkov radiation: the relationship between light emission and dose. Physics in Medicine and Biology, 2014; 59 (14): 3789 DOI: 10.1088/0031-9155/59/14/3789

Cite This Page:

Norris Cotton Cancer Center Dartmouth-Hitchcock Medical Center. "Cherenkov Effect improves radiation therapy for patients with cancer." ScienceDaily. ScienceDaily, 25 February 2015. <www.sciencedaily.com/releases/2015/02/150225114100.htm>.
Norris Cotton Cancer Center Dartmouth-Hitchcock Medical Center. (2015, February 25). Cherenkov Effect improves radiation therapy for patients with cancer. ScienceDaily. Retrieved May 23, 2017 from www.sciencedaily.com/releases/2015/02/150225114100.htm
Norris Cotton Cancer Center Dartmouth-Hitchcock Medical Center. "Cherenkov Effect improves radiation therapy for patients with cancer." ScienceDaily. www.sciencedaily.com/releases/2015/02/150225114100.htm (accessed May 23, 2017).

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