UNLABELLED: An object-oriented software system is described for estimating internal emitter absorbed doses using a set of computer modules operating within a personal computer environment. The system is called the Radionuclide Treatment Planning and Absorbed Dose Estimation System (RTDS). It is intended for radioimmunotherapy applications, although other forms of internal emitter therapy may also be considered. METHODS: Four software modules interact through a database backend. Clinical, demographic and image data are directly entered into the database. Modules include those devoted to clinical imaging (nuclear, CT and MR), activity determination, organ compartmental modeling and absorbed dose estimation. RESULTS: Both standard phantom (Medical Internal Radiation Dose [MIRD]) and patient-specific absorbed doses are estimated. All modules interact with the database backend so that changes in one process do not influence other operations. Results of the modular operations are written to the database as computations are completed. Dose-volume histograms are an intrinsic part of the output for patient-specific absorbed dose estimates. A sample dose estimate for a potential 90Y monoclonal antibody is described. CONCLUSION: A four-module software system has been implemented to estimate MIRD phantom and patient-specific absorbed doses. Computations of the doses and their statistical distribution for a pure beta emitter such as 90Y take approximately 1 min on a 300 MHz personal computer.
UNLABELLED: An object-oriented software system is described for estimating internal emitter absorbed doses using a set of computer modules operating within a personal computer environment. The system is called the Radionuclide Treatment Planning and Absorbed Dose Estimation System (RTDS). It is intended for radioimmunotherapy applications, although other forms of internal emitter therapy may also be considered. METHODS: Four software modules interact through a database backend. Clinical, demographic and image data are directly entered into the database. Modules include those devoted to clinical imaging (nuclear, CT and MR), activity determination, organ compartmental modeling and absorbed dose estimation. RESULTS: Both standard phantom (Medical Internal Radiation Dose [MIRD]) and patient-specific absorbed doses are estimated. All modules interact with the database backend so that changes in one process do not influence other operations. Results of the modular operations are written to the database as computations are completed. Dose-volume histograms are an intrinsic part of the output for patient-specific absorbed dose estimates. A sample dose estimate for a potential 90Y monoclonal antibody is described. CONCLUSION: A four-module software system has been implemented to estimate MIRD phantom and patient-specific absorbed doses. Computations of the doses and their statistical distribution for a pure beta emitter such as 90Y take approximately 1 min on a 300 MHz personal computer.
Authors: Eric Visser; Ernst Postema; Otto Boerman; Jeroen Visschers; Wim Oyen; Frans Corstens Journal: Eur J Nucl Med Mol Imaging Date: 2006-11-15 Impact factor: 9.236
Authors: Abigail E Besemer; You Ming Yang; Joseph J Grudzinski; Lance T Hall; Bryan P Bednarz Journal: Cancer Biother Radiopharm Date: 2018-04-25 Impact factor: 3.099
Authors: Sara St James; Bryan Bednarz; Stanley Benedict; Jeffrey C Buchsbaum; Yuni Dewaraja; Eric Frey; Robert Hobbs; Joseph Grudzinski; Emilie Roncali; George Sgouros; Jacek Capala; Ying Xiao Journal: Int J Radiat Oncol Biol Phys Date: 2020-08-14 Impact factor: 7.038