Irradiation methods and nozzle design for the advanced proton therapy facility

SHU Hang; FANG Shou-Xian; GUAN Xia-Ling; TANG Jing-Yu; LIU De-Kang; FU Shi-Nian; LI Gang; LIU Li; CHEN Yuan; JIAO Yi; QIU Jing

doi:10.1088/1674-1137/34/4/020

Chinese Physics C> 2010, Vol. 34> Issue(4) : 516-520 DOI: 10.1088/1674-1137/34/4/020

Irradiation methods and nozzle design for the advanced proton therapy facility

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Abstract：
A conception design of the Advanced Proton Therapy Facility (APTF) has been carried out. The system intentionally employs a slow-cycling synchrotron with a maximum energy of 250 MeV, two rotating gantries and two fixed beam nozzles for the treatment. In this paper, we try to compare the strength and weaknesses between the two treatment methods: the beam spreading and the pencil beam scanning. The application of the pencil beam scanning method and the double-scattering method together with the related nozzle design at APTF is also given. The simulation results of employing the double-scattering method have been given during the preliminary design.

References

[1]

. Larsson B. Radiol Br. J., 1961, 34: 1432. Gra man B, Jung B, Nohrman B A, Bergstrom R. ActaRadiol., 1967, 6: 3613. Koehler A M, Preston W M. Radiology, 1972, 104: 1914. CHU W T, Ludewigt B A, Renner T R. Rev. Sci. Instrum.,1993, 64: 20555. Takada Y. Jpn. J. Appl. Phys., 1994, 33: 3536. Torikoshi M, Minohara S, Kanematsu N et al. Journal ofRadiation Research, 2007, 48(Suppl.): A15-A257. Pedroni E, Bacher R, Blattmann H et al. Med. Phys., 1995,21: 378. FANG S X, GUAN X L, TANG J Y et al. ATPF-a Dedicated Proton Therapy Facility, to be published (submitted to Chinese Physics C)9. FANG S X et al. Conceptual Design Report of Advanced Proton Therapy Facility. IHEP-AC-IP-Note/2009-110. Badano L et al. Proton-Ion Medical Machine Study(PIMMS). Part I, CERN/PS 1999-010 DI. Geneva11. Pedroni E, Blattmann H, Bohringer T et al. Proc. of the NIRS International Workshop on Heavy Charged ParticleTherapy and Related Subjects. Chiba, Japan, 1991. 94-10912. Haberer Th, Becher W, Schardt D et al. Nucl. Instrum.Methods in Phys. Res., 1993, 330: 29613. Yonai S, Kanematsu N, Komori M, Kanai T et al. Med.Phys., 2008, 35: 92714. Delaney T F, Kooy H M. Proton and Charged Particle Radiotherapy.Lippincott Williams n Wilkins, 2008. 4115. Pedroni E, Enge H. Med. Biol. Eng. Comput., 1995,33: 27116. Haberre T, Becher W, Schardt D et al. Nucl. Instrum.Methods Phys. Res. A, 1993, 330: 29617. Pedroni E, Scheib S, Bohringer T et al. Phys. Med. Biol.,2005, 50: 54118. Philipps M, Pedroni E, Blattmann H et al. Phys. Med.Biol., 1992, 37: 22319. Pedroni E. Status of Hadrontherapy Facilities Worldwide.EPAC 200820. JIAO Y, GUAN X L, Satogata T. Design of Scanning Gantry for the Advanced Proton Therapy Facility, to be published (submitted to Chinese Physics C)

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SHU Hang, FANG Shou-Xian, GUAN Xia-Ling, TANG Jing-Yu, LIU De-Kang, FU Shi-Nian, LI Gang, LIU Li, CHEN Yuan, JIAO Yi and QIU Jing. Irradiation methods and nozzle design for the advanced proton therapy facility[J]. Chinese Physics C, 2010, 34(4): 516-520. doi: 10.1088/1674-1137/34/4/020

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Received: 2009-05-07
Revised: 2009-07-03

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通讯作者: 陈斌, bchen63@163.com

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沈阳化工大学材料科学与工程学院沈阳 110142

Irradiation methods and nozzle design for the advanced proton therapy facility

Corresponding author: SHU Hang,

Received Date: 2009-05-07

Accepted Date: 2009-07-03

Available Online: 2010-04-05

Abstract:

A conception design of the Advanced Proton Therapy Facility (APTF) has been carried out. The system intentionally employs a slow-cycling synchrotron with a maximum energy of 250 MeV, two rotating gantries and two fixed beam nozzles for the treatment. In this paper, we try to compare the strength and weaknesses between the two treatment methods: the beam spreading and the pencil beam scanning. The application of the pencil beam scanning method and the double-scattering method together with the related nozzle design at APTF is also given. The simulation results of employing the double-scattering method have been given during the preliminary design.

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Irradiation methods and nozzle design for the advanced proton therapy facility

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通讯作者: 陈斌, bchen63@163.com

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