The goal of conformal radiation therapy is to deliver a curative radiation dose to the tumor while sparing nearby healthy tissue. In intensity modulated proton therapy (IMPT), this is accomplished by delivering many proton pencil beams of different sizes and ranges throughout the target volume, and in intensity modulated [photon] radiation therapy (IMRT) and related modalities, this is accomplished by shaping the radiation beam using a multi-leaf collimator. The resulting dose distributions can be highly complex, and must be verified by detailed 3D measurements. Current 2D dose measuring devices may miss vital differences between the planned and delivered doses because they cannot measure the full 3D dose distribution. At this time there are no suitable detectors available for accurate, high resolution, and efficient 3D dose measurement for verification of complex photon and proton dose distributions. Our long-term goal is to reduce radiation treatment errors and improve dose verification accuracy by developing a new fast, reusable 3D detector for patient treatment verification. The objective of the proposed research is to develop a 3D detector based on the measurement of light emission from a large volume of scintillator, and use this detector to obtain quality assurance measurements for IMPT and IMRT treatments. On the basis of our preliminary work, we hypothesize that a volumetric scintillation detector can measure 3D dose distributions in real time with an accuracy of ?3% or better. The rationale for this project is that it will enable complete on-line high-resolution 3D dose measurements as a part of routine QA for each patient, while decreasing considerably the time required for treatment verification. To reach this goal, we aim to: a) develop instrumentation and reconstruction techniques to measure 3D light distributions in a volumetric scintillator detector, b) develop quenching correction methods for scintillation dosimetry of proton beams, and c) validate the 3D scintillation detector for radiotherapy treatment verification. The proposed research is significant because it will produce a fully three-dimensional dosimetry system for radiotherapy quality assurance. The system will be efficient and cost effective and will improve confidence in dose distributions delivered to patients. It will also decrease the time required for verification measurements, removing a major workflow bottleneck and allowing more patients to benefit from IMPT and other complex radiotherapy modalities. This is particularly important with the rapid increase in the number of proton therapy centers nationwide and worldwide. The proposed project is highly innovative in the sense that it will lead to a first-of-its-kind dosimetry system capable of instantaneously measuring complex 3D dose distributions. In addition, we expect this detector to be valuable for 3D dosimetry of other treatment modalities, including stereotactic body radiation therapy, passive scattering proton therapy, and even high-dose rate brachytherapy.

Public Health Relevance

The proposed research will develop a first-of-its-kind dosimetry system capable of instantaneously mapping complex 3D radiation dose distributions used for cancer treatments. This system will make it possible to measure the full 3D dose distribution of complex radiation therapy treatment plans, significantly improving confidence in the dose delivered to patients. This novel system will also decrease the time required for verification measurements of treatment plans, removing a major workflow bottleneck and allowing more cancer patients to benefit from intensity modulated proton therapy.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
1R01CA182450-01A1
Application #
8761493
Study Section
Radiation Therapeutics and Biology Study Section (RTB)
Program Officer
Deye, James
Project Start
2014-08-01
Project End
2017-07-31
Budget Start
2014-08-01
Budget End
2015-07-31
Support Year
1
Fiscal Year
2014
Total Cost
Indirect Cost
Name
University of Texas MD Anderson Cancer Center
Department
Radiation-Diagnostic/Oncology
Type
Hospitals
DUNS #
City
Houston
State
TX
Country
United States
Zip Code
77030
Alsanea, Fahed; Wootton, Landon; Sahoo, Narayan et al. (2018) Exradin W1 plastic scintillation detector for in vivo skin dosimetry in passive scattering proton therapy. Phys Med 47:58-63
Therriault-Proulx, F; Wen, Z; Ibbott, G et al. (2018) Effect of Magnetic Field Strength on Plastic Scintillation Detector Response. Radiat Meas 116:10-13
Darne, Chinmay D; Alsanea, Fahed; Robertson, Daniel G et al. (2017) Performance characterization of a 3D liquid scintillation detector for discrete spot scanning proton beam systems. Phys Med Biol 62:5652-5667
Kertzscher, Gustavo; Beddar, Sam (2017) Inorganic scintillation detectors based on Eu-activated phosphors for 192Ir brachytherapy. Phys Med Biol 62:5046-5075
Kertzscher, Gustavo; Beddar, Sam (2016) Ruby-based inorganic scintillation detectors for 192Ir brachytherapy. Phys Med Biol 61:7744-7764
Hui, CheukKai; Robertson, Daniel; Alsanea, Fahed et al. (2015) Fast range measurement of spot scanning proton beams using a volumetric liquid scintillator detector. Biomed Phys Eng Express 1:
Ingram, W Scott; Robertson, Daniel; Beddar, Sam (2015) Calculations and measurements of the scintillator-to-water stopping power ratio of liquid scintillators for use in proton radiotherapy. Nucl Instrum Methods Phys Res A 776:15-20
Therriault-Proulx, Francois; Wootton, Landon; Beddar, Sam (2015) A method to correct for temperature dependence and measure simultaneously dose and temperature using a plastic scintillation detector. Phys Med Biol 60:7927-39
Wootton, Landon; Holmes, Charles; Sahoo, Narayan et al. (2015) Passively scattered proton beam entrance dosimetry with a plastic scintillation detector. Phys Med Biol 60:1185-98
Robertson, Daniel; Hui, Cheukkai; Archambault, Louis et al. (2014) Optical artefact characterization and correction in volumetric scintillation dosimetry. Phys Med Biol 59:23-42

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