002929868 001__ 2929868
002929868 003__ SzGeCERN
002929868 005__ 20250417230610.0
002929868 0247_ $$2DOI$$9CERN$$a10.23730/CYRSP-2024-003.1841
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002929868 035__ $$9Inspire$$a2901994
002929868 041__ $$aeng
002929868 100__ $$aSchippers, Jacobus Maarten$$uPSI, Villigen$$uUMCG$$vUniversity Medical Center, Groningen, the Netherlands, https://ror.org/03cv38k47
002929868 245__ $$9CERN$$aII.17 - Physics and accelerators for particle therapy
002929868 260__ $$c2024
002929868 300__ $$a12 p
002929868 520__ $$9CERN$$aAt the Paul Scherer Institute (PSI) radiation therapy is performed by means of proton beams. Proton therapy is one of the particle therapies, in which energetic ions (mostly protons and carbon ions) are used to treat cancer patient by irradiating the tumor with high precision. At PSI the radiation dose is applied by a proton beam of max 250 MeV. In this chapter, the interactions of energetic ions with matter (tissue) and the way particle therapy is applied are discussed, followed by a description of the PSI’s medical proton cyclotron and the treatment rooms in which the dose is applied to the patient.
002929868 540__ $$aCC-BY-4.0$$bCERN$$uhttps://creativecommons.org/licenses/by/4.0/
002929868 542__ $$dCERN$$g2024
002929868 65017 $$2SzGeCERN$$aAccelerators and Storage Rings
002929868 690C_ $$aARTICLE
002929868 690C_ $$aCERN
002929868 690C_ $$aYELLOWREPCONTRIB
002929868 690C_ $$aBookChapter
002929868 773__ $$c1841-1852$$pCERN Yellow Rep. School Proc.$$v3$$wC24-11-27$$y2024
002929868 8564_ $$82726146$$s20265060$$uhttps://cds.cern.ch/record/2929868/files/document.pdf$$yFulltext
002929868 960__ $$a13
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002929868 980__ $$aBookChapter