Dosimetric characteristics of active solid state detectors in a 60 MeV proton radiotherapy beam

• Autorzy: Sowa U. , Nowak T. , Michalec B. , Mierzwińska G. , Swakoń J. , Olko P.
• Konferencja: Proceedings of the International Conference on Development and Applications of Nuclear Technologies NUTECH-2011, 11-14 September 2011, Kraków, Poland
• Języki publikacji: PL

Abstrakty

EN

Several solid state detectors, such as dosimetric diodes, MOSFET detectors or diamond detectors are used for quality control of radiotherapy beams. The goal of this work was to determine dosimetric properties of the PTW diamond detector (DD) and the PTW silicon diode in the 60 MeV therapeutic beam (practical range in water Rp = 29.17 mm) located at the Institute of Nuclear Physics, Polish Academy of Sciences (IFJ PAN, Kraków). A PTW Markus ionization chamber was used as a reference device. The empirical correction factor for diamond detector, kDD(Rresidual), introduced in the Technical Report Series of IAEA, TRS-398 [9] as a function of beam quality, Rresidual, was found to decrease from 1.12 for Rresidual = 1.5 mm to 1.04 for Rresidual = 26 mm. The reproducibility of response of DD and PTW diodes in the proton filed did not exceed 0.11%. Our results show that diamond detectors and dosimetric diodes are useful tools for quality assurance (QA) of therapeutic proton beam, but each type of detectors has specific properties which should be taken into account when choosing particular application.

Słowa kluczowe

EN

diamond dosimeter; diode Si; dosimetry; proton beam

• Wydawca: Institute of Nuclear Chemistry and Technology
• Czasopismo: Nukleonika
• Rocznik: 2012
• Tom: Vol. 57, No. 4
• Strony: 491--495
• Opis fizyczny: BIbliogr. 18 poz., rys.

Twórcy

autor

Sowa U.

autor

Nowak T.

autor

Michalec B.

autor

Mierzwińska G.

autor

Swakoń J.

autor

Olko P.

• Proton Radiotherapy Group, The Henryk Niewodniczański Institute of Nuclear Physics, Polish Academy of Sciences (IFJ PAN), 152 Radzikowskiego Str., 31-342 Kraków, Poland, Tel.: +48 12 662 8161, Fax: +48 12 662 8458,

Bibliografia

• 1. AAPM (2005) Diode in vivo dosimetry for patients receiving external beam radiotherapy. AAPM task Group 62 Report no. 87. American Association of Physics in Medicine
• 2. Bucciolini M, Banci Buonamici F, Mazzocchi S, De Angelis C, Onori S, Cirrone GAP (2003) Diamond detector versus silicon diode and ion chamber in photon beams of different energy and field size. Med Phys 30;8:2149–2154
• 3. Cirrone GAP, Cuttone G, Lo Nigro S, Mongelli V, Raffaele L, Sabini MG (2006) Dosimetric characterization of CVD diamonds in photon, electron and proton beams. Nucl Phys B (Proc Suppl) 150:330–333
• 4. Fidanzio A, Azario L, De Angelis C et al. (2002) A correction method for diamond detector signal dependence with proton energy. Med Phys 29;5:669–695
• 5. Fidanzio A, Azario L, Miceli R, Russo A, Piermattei A (2000) PTW-diamond detector: Dose rate and particle type dependence. Med Phys 27;11:2589–2593
• 6. Grusell E, Medin J (2000) General characteristics of the use of silicon diode detectors for clinical dosimetry in proton beams. Phys Med Biol 45:2573–2582
• 7. Hoban PW, Heydarian M, Beckham WA, Beddoe AH (1994) Dose rate dependence of a PTW diamond detector in the dosimetry of a 6 MV photon beam. Phys Med Biol 39:1219–1229
• 8. Huyskens DP, Bogaerts R, Verstraete J et al. (2001) Practical guidelines for the implementation of in vivo dosimetry with diodes in external radiotherapy with photon beams (entrance dose). ESTRO Physics booklet no. 5
• 9. IAEA (2000) Absorbed dose determination in external beam radiotherapy: An international code of practice for dosimetry based on standards of absorbed dose to water. IAEA Technical Reports Series no. 398. International Atomic Energy Agency, Vienna
• 10. ICRU (2007) Prescribing, recording, and reporting proton-beam therapy. ICRU Report no. 78. Oxford University Press, Journal of the ICRU 7;2 (doi:10.1093/jicru/ndn001)
• 11. Michalec B, Swakon J, Sowa U, Ptaszkiewicz M, Cywicka-Jakiel T, Olko P (2010) Proton radiotherapy facility for ocular tumors at the IFJ PAN in Kraków, Poland. Appl Radiat Isot 68;4/5:738–742
• 12. Onori S, De Angelis C, Fattibene P et al. (2000) Dosimetric characterization of silicon and diamond detectors in low-energy proton beams. Phys Med Biol 45:3045–3058
• 13. Pacilio M, De Angelis C, Onori S et al. (2002) Characteristics of silicon and diamond detectors in a 60 MeV proton beam. Phys Med Biol 47:N107–N112
• 14. Podgorsak EB (2005) Radiation dosimeters. In: Radiation oncology physics: A handbook for teachers and students. Chapter 3. International Atomic Energy Agency, Vienna
• 15. Rikner G, Grusell E (1983) Effects of radiation damage on p-type silicon detectors. Phys Med Biol 28;11:1261–1267
• 16. Sakama M, Kanai T, Kase Y, Komori M, Fukumura A, Kohno T (2005) Responses of diamond detector to high-LET charged particles. Phys Med Biol 50:2275–2289
• 17. Swakon J, Olko P, Adamczyk D et al. (2010) Facility for proton radiotherapy of eye cancer at IFJ PAN in Krakow. Radiat Meas 45:1469–1471
• 18. Vatnitsky SM, Khrunov VS, Fominych VI, Schuele E (1993) Diamond detector dosimetry for medical applications. Radiat Prot Dosim 47:515–518