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Antiproton radiotherapy

Antiprotons are interesting as a possible future modality in radiation therapy for the following reasons: When fast antiprotons penetrate matter, protons and antiprotons have near identical stopping powers and exhibit equal radiobiology well before the Bragg-peak. But when the antiprotons come to re...

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Detalles Bibliográficos
Autores principales: Bassler, Niels, Alsner, Jan, Beyer, Gerd, DeMarco, John J., Doser, Michael, Hajdukovic, Dragan, Hartley, Oliver, Iwamoto, Keisuke S., Jakel, Oliver, Knudsen, Helge V., Kovacevic, Sandra, Møller, Søren Pape, Overgaard, Jens, Petersen, Jørgen B.à, Solberg, Timothy D., Sørensen, Brita S., Vranjes, Sanja, Wouters, Bradly G., Holzscheiter, Michael H.
Lenguaje:eng
Publicado: 2008
Materias:
Acceso en línea:https://dx.doi.org/10.1016/j.radonc.2007.11.028
http://cds.cern.ch/record/2046055
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author Bassler, Niels
Alsner, Jan
Beyer, Gerd
DeMarco, John J.
Doser, Michael
Hajdukovic, Dragan
Hartley, Oliver
Iwamoto, Keisuke S.
Jakel, Oliver
Knudsen, Helge V.
Kovacevic, Sandra
Møller, Søren Pape
Overgaard, Jens
Petersen, Jørgen B.à
Solberg, Timothy D.
Sørensen, Brita S.
Vranjes, Sanja
Wouters, Bradly G.
Holzscheiter, Michael H.
author_facet Bassler, Niels
Alsner, Jan
Beyer, Gerd
DeMarco, John J.
Doser, Michael
Hajdukovic, Dragan
Hartley, Oliver
Iwamoto, Keisuke S.
Jakel, Oliver
Knudsen, Helge V.
Kovacevic, Sandra
Møller, Søren Pape
Overgaard, Jens
Petersen, Jørgen B.à
Solberg, Timothy D.
Sørensen, Brita S.
Vranjes, Sanja
Wouters, Bradly G.
Holzscheiter, Michael H.
author_sort Bassler, Niels
collection CERN
description Antiprotons are interesting as a possible future modality in radiation therapy for the following reasons: When fast antiprotons penetrate matter, protons and antiprotons have near identical stopping powers and exhibit equal radiobiology well before the Bragg-peak. But when the antiprotons come to rest at the Bragg-peak, they annihilate, releasing almost 2 GeV per antiproton–proton annihilation. Most of this energy is carried away by energetic pions, but the Bragg-peak of the antiprotons is still locally augmented with ∼20–30 MeV per antiproton. Apart from the gain in physical dose, an increased relative biological effect also has been observed, which can be explained by the fact that some of the secondary particles from the antiproton annihilation exhibit high-LET properties. Finally, the weakly interacting energetic pions, which are leaving the target volume, may provide a real time feedback on the exact location of the annihilation peak. We have performed dosimetry experiments and investigated the radiobiological properties using the antiproton beam available at CERN, Geneva. Dosimetry experiments were carried out with ionization chambers, alanine pellets and radiochromic film. Radiobiological experiments were done with V79 WNRE Chinese hamster cells. The radiobiological experiments were repeated with protons and carbon ions at TRIUMF and GSI, respectively, for comparison. Several Monte Carlo particle transport codes were investigated and compared with our experimental data obtained at CERN. The code that matched our data best was used to generate a set of depth dose data at several energies, including secondary particle-energy spectra. This can be used as base data for a treatment planning software such as TRiP. Our findings from the CERN experiments indicate that the biological effect of antiprotons in the plateau region may be reduced by a factor of 4 for the same biological target dose in a spread-out Bragg-peak, when comparing with protons. The extension of TRiP to handle antiproton beams is currently in progress. This will enable us to perform planning studies, where the potential clinical consequences can be examined, and compared to those of other beam modalities such as protons, carbon ions, or IMRT photons.
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institution Organización Europea para la Investigación Nuclear
language eng
publishDate 2008
record_format invenio
spelling cern-20460552019-09-30T06:29:59Zdoi:10.1016/j.radonc.2007.11.028http://cds.cern.ch/record/2046055engBassler, NielsAlsner, JanBeyer, GerdDeMarco, John J.Doser, MichaelHajdukovic, DraganHartley, OliverIwamoto, Keisuke S.Jakel, OliverKnudsen, Helge V.Kovacevic, SandraMøller, Søren PapeOvergaard, JensPetersen, Jørgen B.àSolberg, Timothy D.Sørensen, Brita S.Vranjes, SanjaWouters, Bradly G.Holzscheiter, Michael H.Antiproton radiotherapyHealth Physics and Radiation EffectsAntiprotons are interesting as a possible future modality in radiation therapy for the following reasons: When fast antiprotons penetrate matter, protons and antiprotons have near identical stopping powers and exhibit equal radiobiology well before the Bragg-peak. But when the antiprotons come to rest at the Bragg-peak, they annihilate, releasing almost 2 GeV per antiproton–proton annihilation. Most of this energy is carried away by energetic pions, but the Bragg-peak of the antiprotons is still locally augmented with ∼20–30 MeV per antiproton. Apart from the gain in physical dose, an increased relative biological effect also has been observed, which can be explained by the fact that some of the secondary particles from the antiproton annihilation exhibit high-LET properties. Finally, the weakly interacting energetic pions, which are leaving the target volume, may provide a real time feedback on the exact location of the annihilation peak. We have performed dosimetry experiments and investigated the radiobiological properties using the antiproton beam available at CERN, Geneva. Dosimetry experiments were carried out with ionization chambers, alanine pellets and radiochromic film. Radiobiological experiments were done with V79 WNRE Chinese hamster cells. The radiobiological experiments were repeated with protons and carbon ions at TRIUMF and GSI, respectively, for comparison. Several Monte Carlo particle transport codes were investigated and compared with our experimental data obtained at CERN. The code that matched our data best was used to generate a set of depth dose data at several energies, including secondary particle-energy spectra. This can be used as base data for a treatment planning software such as TRiP. Our findings from the CERN experiments indicate that the biological effect of antiprotons in the plateau region may be reduced by a factor of 4 for the same biological target dose in a spread-out Bragg-peak, when comparing with protons. The extension of TRiP to handle antiproton beams is currently in progress. This will enable us to perform planning studies, where the potential clinical consequences can be examined, and compared to those of other beam modalities such as protons, carbon ions, or IMRT photons.oai:cds.cern.ch:20460552008
spellingShingle Health Physics and Radiation Effects
Bassler, Niels
Alsner, Jan
Beyer, Gerd
DeMarco, John J.
Doser, Michael
Hajdukovic, Dragan
Hartley, Oliver
Iwamoto, Keisuke S.
Jakel, Oliver
Knudsen, Helge V.
Kovacevic, Sandra
Møller, Søren Pape
Overgaard, Jens
Petersen, Jørgen B.à
Solberg, Timothy D.
Sørensen, Brita S.
Vranjes, Sanja
Wouters, Bradly G.
Holzscheiter, Michael H.
Antiproton radiotherapy
title Antiproton radiotherapy
title_full Antiproton radiotherapy
title_fullStr Antiproton radiotherapy
title_full_unstemmed Antiproton radiotherapy
title_short Antiproton radiotherapy
title_sort antiproton radiotherapy
topic Health Physics and Radiation Effects
url https://dx.doi.org/10.1016/j.radonc.2007.11.028
http://cds.cern.ch/record/2046055
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