Dosimetric response of a glass dosimeter in proton beams: LET-dependence and correction factor

Abstract: A radiophotoluminescent glass dosimeter (RGD) is widely used in postal audit system for photon beams in Japan. However, proton dosimetry in RGDs is scarcely used owing to a lack of clarity in their response to beam quality. In this study, we investigated RGD response to beam quality for establishing a suitable linear energy transfer (LET)-corrected dosimetry protocol in a therapeutic proton beam.The RGD response was compared with ionization chamber measurement for a 100-225 MeV passive proton beam. LET of the … Show more

“…Because of the LET dependence of RGD, we observed a 15.2% under‐response compared with the IC dose. The LET dependence of the therapeutic proton beam was consistent with our previous study using a passive system 13 . We obtained from the linear fit between the RGD response and LET.…”

“…14 In our previous study, we established that LET changes depending on the irradiation conditions, specifically for low-energy proton beams, although R res is the same. 13 In this study, a scanning system indicated that the LET values varied by 10%-50% for the same R res . R res is a quality index primarily established for a passive system, and it is important to use LET for a spot scanning system.…”

“…Figure 4 shows the relationship between R res and LET obtained via MC simulation for proton beams with four maximum range energy patterns. The LET values for the 100–225 MeV passive proton beam have been reported to range from 10% to 30% for a similar R res 13 . In the scanning SOBP, the LET value suddenly increased for R res <20 mm and varied from 10% to 50% in the range of R res 40–80 mm.…”

“…(1) where Φ E (z) is the fluence of the proton beam with energy E at depth z, and LET (E) is the LET of the proton beam with energy E. Based on the MC calculations, we used the same parameters as in a previous report. 13 The physics lists G4mStandardPhysics_option4 and G4HadronPhysicsQGSP_BIC were used for simulating proton and nuclear interactions, respectively. The detection volume of the LET was 12 × 3 × 1.5 mm 3 , which corresponds to the actual RGD dimensions (diameter 1.5 mm, length 12 mm), although the lateral dimensions were expanded sufficiently to account for the uncertainty of MC calculation.…”

“…In our previous study, we used LET calculated through Monte Carlo (MC) simulation to correct the RGD response for the 100–225 MeV passive proton beam system 13 . A 15.7% dose reduction of RGD owing to LET was observed for passive proton beams, and the mean dose difference (±SD) was improved at 0.0 ±2.1% after LET‐based correction 13 . Previous studies have shown the response of RGD to proton beams with LET‐based corrections.…”

Evaluation of radiophotoluminescent glass dosimeter response for therapeutic spot scanning proton beam: suggestion of linear energy transfer‐based correction

“…Because of the LET dependence of RGD, we observed a 15.2% under‐response compared with the IC dose. The LET dependence of the therapeutic proton beam was consistent with our previous study using a passive system 13 . We obtained from the linear fit between the RGD response and LET.…”

“…14 In our previous study, we established that LET changes depending on the irradiation conditions, specifically for low-energy proton beams, although R res is the same. 13 In this study, a scanning system indicated that the LET values varied by 10%-50% for the same R res . R res is a quality index primarily established for a passive system, and it is important to use LET for a spot scanning system.…”

“…Figure 4 shows the relationship between R res and LET obtained via MC simulation for proton beams with four maximum range energy patterns. The LET values for the 100–225 MeV passive proton beam have been reported to range from 10% to 30% for a similar R res 13 . In the scanning SOBP, the LET value suddenly increased for R res <20 mm and varied from 10% to 50% in the range of R res 40–80 mm.…”

“…(1) where Φ E (z) is the fluence of the proton beam with energy E at depth z, and LET (E) is the LET of the proton beam with energy E. Based on the MC calculations, we used the same parameters as in a previous report. 13 The physics lists G4mStandardPhysics_option4 and G4HadronPhysicsQGSP_BIC were used for simulating proton and nuclear interactions, respectively. The detection volume of the LET was 12 × 3 × 1.5 mm 3 , which corresponds to the actual RGD dimensions (diameter 1.5 mm, length 12 mm), although the lateral dimensions were expanded sufficiently to account for the uncertainty of MC calculation.…”

“…In our previous study, we used LET calculated through Monte Carlo (MC) simulation to correct the RGD response for the 100–225 MeV passive proton beam system 13 . A 15.7% dose reduction of RGD owing to LET was observed for passive proton beams, and the mean dose difference (±SD) was improved at 0.0 ±2.1% after LET‐based correction 13 . Previous studies have shown the response of RGD to proton beams with LET‐based corrections.…”

Evaluation of radiophotoluminescent glass dosimeter response for therapeutic spot scanning proton beam: suggestion of linear energy transfer‐based correction

Relative efficiency of radiophotoluminescent glass detectors in low energy ion beams

Dosimetric response of radiophotoluminescent glass detectors in a scanning pencil proton beam