TY - JOUR
T1 - In vivo dosimetry in external beam photon radiotherapy
T2 - Requirements and future directions for research, development, and clinical practice
AU - Olaciregui-Ruiz, Igor
AU - Beddar, Sam
AU - Greer, Peter
AU - Jornet, Nuria
AU - McCurdy, Boyd
AU - Paiva-Fonseca, Gabriel
AU - Mijnheer, Ben
AU - Verhaegen, Frank
N1 - © 2020 The Authors.
PY - 2020/7
Y1 - 2020/7
N2 - External beam radiotherapy with photon beams is a highly accurate treatment modality, but requires extensive quality assurance programs to confirm that radiation therapy will be or was administered appropriately. In vivo dosimetry (IVD) is an essential element of modern radiation therapy because it provides the ability to catch treatment delivery errors, assist in treatment adaptation, and record the actual dose delivered to the patient. However, for various reasons, its clinical implementation has been slow and limited. The purpose of this report is to stimulate the wider use of IVD for external beam radiotherapy, and in particular of systems using electronic portal imaging devices (EPIDs). After documenting the current IVD methods, this report provides detailed software, hardware and system requirements for in vivo EPID dosimetry systems in order to help in bridging the current vendor-user gap. The report also outlines directions for further development and research. In vivo EPID dosimetry vendors, in collaboration with users across multiple institutions, are requested to improve the understanding and reduce the uncertainties of the system and to help in the determination of optimal action limits for error detection. Finally, the report recommends that automation of all aspects of IVD is needed to help facilitate clinical adoption, including automation of image acquisition, analysis, result interpretation, and reporting/documentation. With the guidance of this report, it is hoped that widespread clinical use of IVD will be significantly accelerated.
AB - External beam radiotherapy with photon beams is a highly accurate treatment modality, but requires extensive quality assurance programs to confirm that radiation therapy will be or was administered appropriately. In vivo dosimetry (IVD) is an essential element of modern radiation therapy because it provides the ability to catch treatment delivery errors, assist in treatment adaptation, and record the actual dose delivered to the patient. However, for various reasons, its clinical implementation has been slow and limited. The purpose of this report is to stimulate the wider use of IVD for external beam radiotherapy, and in particular of systems using electronic portal imaging devices (EPIDs). After documenting the current IVD methods, this report provides detailed software, hardware and system requirements for in vivo EPID dosimetry systems in order to help in bridging the current vendor-user gap. The report also outlines directions for further development and research. In vivo EPID dosimetry vendors, in collaboration with users across multiple institutions, are requested to improve the understanding and reduce the uncertainties of the system and to help in the determination of optimal action limits for error detection. Finally, the report recommends that automation of all aspects of IVD is needed to help facilitate clinical adoption, including automation of image acquisition, analysis, result interpretation, and reporting/documentation. With the guidance of this report, it is hoped that widespread clinical use of IVD will be significantly accelerated.
KW - In vivo dosimetry
KW - External beam radiotherapy
KW - Electronic portal imaging device
KW - Task group report
KW - Review
KW - PLASTIC SCINTILLATION DETECTORS
KW - TOTAL-BODY IRRADIATION
KW - PORTAL IMAGING DEVICE
KW - EPID DOSIMETRY
KW - RADIATION-THERAPY
KW - DOSE VERIFICATION
KW - QUALITY-ASSURANCE
KW - MOSFET DETECTORS
KW - ERROR-DETECTION
KW - IMRT
U2 - 10.1016/j.phro.2020.08.003
DO - 10.1016/j.phro.2020.08.003
M3 - (Systematic) Review article
C2 - 33458335
SN - 2405-6316
VL - 15
SP - 108
EP - 116
JO - Physics & Imaging in Radiation Oncology
JF - Physics & Imaging in Radiation Oncology
ER -