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Technical Note: On maximizing Cherenkov emissions from medical linear accelerators.

Publication ,  Journal Article
Shrock, Z; Yoon, SW; Gunasingha, R; Oldham, M; Adamson, J
Published in: Med Phys
July 2018

PURPOSE: Cherenkov light during MV radiotherapy has recently found imaging and therapeutic applications but is challenged by relatively low fluence. Our purpose is to investigate the feasibility of increasing Cherenkov light production during MV radiotherapy by increasing photon energy and applying specialized beam-hardening filtration. METHODS: GAMOS 5.0.0, a GEANT4-based framework for Monte Carlo simulations, was used to model standard clinical linear accelerator primary photon beams. The photon source was incident upon a 17.8 cm3 cubic water phantom with a 94 cm source to surface distance. Dose and Cherenkov production was determined at depths of 3-9 cm. Filtration was simulated 15 cm below the photon beam source. Filter materials included aluminum, iron, and copper with thicknesses of 2-20 cm. Histories used depended on the level of attenuation from the filter, ranging from 100 million to 2 billion. Comparing average dose per history also allowed for evaluation of dose-rate reduction for different filters. RESULTS: Overall, increasing photon beam energy is more effective at improving Cherenkov production per unit dose than is filtration, with a standard 18 MV beam yielding 3.3-4.0× more photons than 6 MV. Introducing an aluminum filter into an unfiltered 2400 cGy/min 10 MV beam increases the Cherenkov production by 1.6-1.7×, while maintaining a clinical dose rate of 300 cGy/min, compared to increases of ~1.5× for iron and copper. Aluminum was also more effective than the standard flattening filter, with the increase over the unfiltered beam being 1.4-1.5× (maintaining 600 cGy/min dose rate) vs 1.3-1.4× for the standard flattening filter. Applying a 10 cm aluminum filter to a standard 18 MV, photon beam increased the Cherenkov production per unit dose to 3.9-4.3× beyond that of 6 MV (vs 3.3-4.0× for 18 MV with no aluminum filter). CONCLUSIONS: Through a combination of increasing photon energy and applying specialized beam-hardening filtration, the amount of Cherenkov photons per unit radiotherapy dose can be increased substantially.

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Published In

Med Phys

DOI

EISSN

2473-4209

Publication Date

July 2018

Volume

45

Issue

7

Start / End Page

3315 / 3320

Location

United States

Related Subject Headings

  • Water
  • Radiotherapy
  • Photons
  • Phantoms, Imaging
  • Particle Accelerators
  • Nuclear Medicine & Medical Imaging
  • Monte Carlo Method
  • Iron
  • Humans
  • Copper
 

Citation

APA
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ICMJE
MLA
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Shrock, Z., Yoon, S. W., Gunasingha, R., Oldham, M., & Adamson, J. (2018). Technical Note: On maximizing Cherenkov emissions from medical linear accelerators. Med Phys, 45(7), 3315–3320. https://doi.org/10.1002/mp.12927
Shrock, Zachary, Suk W. Yoon, Rathnayaka Gunasingha, Mark Oldham, and Justus Adamson. “Technical Note: On maximizing Cherenkov emissions from medical linear accelerators.Med Phys 45, no. 7 (July 2018): 3315–20. https://doi.org/10.1002/mp.12927.
Shrock Z, Yoon SW, Gunasingha R, Oldham M, Adamson J. Technical Note: On maximizing Cherenkov emissions from medical linear accelerators. Med Phys. 2018 Jul;45(7):3315–20.
Shrock, Zachary, et al. “Technical Note: On maximizing Cherenkov emissions from medical linear accelerators.Med Phys, vol. 45, no. 7, July 2018, pp. 3315–20. Pubmed, doi:10.1002/mp.12927.
Shrock Z, Yoon SW, Gunasingha R, Oldham M, Adamson J. Technical Note: On maximizing Cherenkov emissions from medical linear accelerators. Med Phys. 2018 Jul;45(7):3315–3320.

Published In

Med Phys

DOI

EISSN

2473-4209

Publication Date

July 2018

Volume

45

Issue

7

Start / End Page

3315 / 3320

Location

United States

Related Subject Headings

  • Water
  • Radiotherapy
  • Photons
  • Phantoms, Imaging
  • Particle Accelerators
  • Nuclear Medicine & Medical Imaging
  • Monte Carlo Method
  • Iron
  • Humans
  • Copper