DocumentCode
1139100
Title
Suppression of Random Coincidences During In-Beam PET Measurements at Ion Beam Radiotherapy Facilities
Author
Crespo, Paulo ; Barthel, Thomas ; Frais-Kölbl, Helmut ; Griesmayer, Erich ; Heidel, Klaus ; Parodi, Katia ; Pawelke, Jörg ; Enghardt, Wolfgang
Author_Institution
Inst. of Nucl. & Hadron Phys., Forschungszentrum Rossendorf, Dresden, Germany
Volume
52
Issue
4
fYear
2005
Firstpage
980
Lastpage
987
Abstract
In-beam positron emission tomography (PET) is currently the only method for an in-situ monitoring of charged hadron therapy. However, in-beam PET data, measured at beams with a sub-
s-microstructure due to the accelerator radio frequency (RF), are highly corrupted by random coincidences arising from prompt
rays following nuclear reactions as the projectiles penetrate the tissue. Since random-correction techniques from conventional PET cannot be applied, the clinical in-beam PET at the therapy facility at the Gesellschaft fÜr Schwerionenforschung (GSI), Darmstadt, Germany, merely reconstructs events registered in the pauses (
s) between the beam macropulses (
s). We have successfully tested two methods for suppressing the micropulse-induced random coincidences during beam extraction. Image statistics can be increased by about 90%. Both methods rely on the synchronization of the
coincidences measured by the positron camera with the time microstructure of the beam, either by using the RF signal from the accelerator or the signal of a thin diamond detector placed in the beam path in front of the target. Energy and triple-coincidence time-correlated spectra first measured during beam extraction, combined with the corresponding tomographic images of the
activity induced by the beam in a plastic phantom, clearly confirm the feasibility of the proposed random suppression methods. These methods provide the solution for applying in-beam PET at synchrotron and cyclotron radiotherapy facilities with optimal use of the annihilation photon flux.
s-microstructure due to the accelerator radio frequency (RF), are highly corrupted by random coincidences arising from prompt
rays following nuclear reactions as the projectiles penetrate the tissue. Since random-correction techniques from conventional PET cannot be applied, the clinical in-beam PET at the therapy facility at the Gesellschaft fÜr Schwerionenforschung (GSI), Darmstadt, Germany, merely reconstructs events registered in the pauses (
s) between the beam macropulses (
s). We have successfully tested two methods for suppressing the micropulse-induced random coincidences during beam extraction. Image statistics can be increased by about 90%. Both methods rely on the synchronization of the
coincidences measured by the positron camera with the time microstructure of the beam, either by using the RF signal from the accelerator or the signal of a thin diamond detector placed in the beam path in front of the target. Energy and triple-coincidence time-correlated spectra first measured during beam extraction, combined with the corresponding tomographic images of the
activity induced by the beam in a plastic phantom, clearly confirm the feasibility of the proposed random suppression methods. These methods provide the solution for applying in-beam PET at synchrotron and cyclotron radiotherapy facilities with optimal use of the annihilation photon flux.Keywords
avalanche photodiodes; biological tissues; cyclotrons; phantoms; positron emission tomography; radiation therapy; scintillation counters; synchrotrons; LSO; accelerator radio frequency; avalanche photodiode; charged hadron therapy; cyclotron radiotherapy; diamond detector; image statistics; in-beam positron emission tomography; ion therapy; nuclear reactions; plastic phantom; positron camera; proton therapy; random-correction techniques; synchrotron; tissue; tomographic images; Frequency measurement; Ion accelerators; Ion beams; Medical treatment; Monitoring; Nuclear measurements; Particle beam measurements; Particle beams; Positron emission tomography; Radio frequency; Avalanche photodiode (APD); LSO; ion therapy; positron emission tomography (PET); proton therapy;
fLanguage
English
Journal_Title
Nuclear Science, IEEE Transactions on
Publisher
ieee
ISSN
0018-9499
Type
jour
DOI
10.1109/TNS.2005.852637
Filename
1495794
Link To Document