Towards offline PET monitoring at a cyclotron-based proton therapy facility [electronic resource] : experiments and Monte Carlo simulations / Matthias Würl.
2016
RC78.7.T62
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Title
Towards offline PET monitoring at a cyclotron-based proton therapy facility [electronic resource] : experiments and Monte Carlo simulations / Matthias Würl.
Author
ISBN
9783658131685 (electronic book)
3658131683 (electronic book)
9783658131678
3658131683 (electronic book)
9783658131678
Published
Wiesbaden : Springer Spektrum, 2016.
Language
English
Description
1 online resource (xv, 86 pages) : illustrations.
Call Number
RC78.7.T62
Dewey Decimal Classification
616.07/575
Summary
Matthias Würl presents two essential steps to implement offline PET monitoring of proton dose delivery at a clinical facility, namely the setting up of an accurate Monte Carlo model of the clinical beamline and the experimental validation of positron emitter production cross-sections. In the first part, the field size dependence of the dose output is described for scanned proton beams. Both the Monte Carlo and an analytical computational beam model were able to accurately predict target dose, while the latter tends to overestimate dose in normal tissue. In the second part, the author presents PET measurements of different phantom materials, which were activated by the proton beam. The results indicate that for an irradiation with a high number of protons for the sake of good statistics, dead time losses of the PET scanner may become important and lead to an underestimation of positron-emitter production yields. Contents Monte Carlo Modeling of a Clinical Proton Beam Low-Dose Envelope and Field Size Factor PET Activation Studies Target Groups Researchers and students in the field of medical physics with focus on particle therapy Medical physicists at proton therapy facilities The Author Matthias Würl wrote his Master's Thesis at the chair of Medical Physics at the Ludwig-Maximilians University Munich. He is now a PhD student at the same department, working on transmission imaging with laser-accelerated ions.
Bibliography, etc. Note
Includes bibliographical references.
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Access limited to authorized users.
Source of Description
Online resource; title from PDF title page (SpringerLink, viewed June 13, 2016).
Series
BestMasters.
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Table of Contents
Monte Carlo Modeling of a Clinical Proton Beam
Low-Dose Envelope and Field Size Factor
PET Activation Studies.
Low-Dose Envelope and Field Size Factor
PET Activation Studies.