4.6 Article

Radio-luminescent imaging for rapid, high-resolution eye plaque loading verification

Journal

MEDICAL PHYSICS
Volume 50, Issue 1, Pages 142-151

Publisher

WILEY
DOI: 10.1002/mp.16003

Keywords

eye plaque brachytherapy; gamma evaluation; Monte Carlo simulation; quality assurance; radioluminescent imaging

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In this study, a fast and low-cost radio-luminescent imaging and dose calculating system was developed to verify the seed activity distribution for differential loading. The results showed that possible errors could be detected using this system.
Background Eye plaque brachytherapy is currently an optimal therapy for intraocular cancers. Due to the lack of an effective and practical technique to measure the seed radioactivity distribution, current quality assurance (QA) practice according to the American Association of Physicists in Medicine TG129 only stipulates that the plaque assembly be visually inspected. Consequently, uniform seed activity is routinely adopted to avoid possible loading mistakes of differential seed loading. However, modulated dose delivery, which represents a general trend in radiotherapy to provide more personalized treatment for a given tumor and patient, requires differential activities in the loaded seeds. Purpose In this study, a fast and low-cost radio-luminescent imaging and dose calculating system to verify the seed activity distribution for differential loading was developed. Methods A proof-of-concept system consisting of a thin scintillator sheet coupled to a camera/lens system was constructed. A seed-loaded plaque can be placed directly on the scintillator surface with the radioactive seeds facing the scintillator. The camera system collects the radioluminescent signal generated by the scintillator on its opposite side. The predicted dose distribution in the scintillator's sensitive layer was calculated using a Monte Carlo simulation with the planned plaque loading pattern of I-125 seeds. Quantitative comparisons of the distribution of relative measured signal intensity and that of the relative predicted dose in the sensitive layer were performed by gamma analysis, similar to intensity-modulated radiation therapy QA. Results Data analyses showed high gamma (3%/0.3 mm, global, 20% threshold) passing rates for correct seed loadings and low passing rates with distinguished high gamma value area for incorrect loadings, indicating that possible errors may be detected. The measurement and analysis only required a few extra minutes, significantly shorter than the time to assay the extra verification seeds the physicist already must perform as recommended by TG129. Conclusions Radio-luminescent QA can be used to facilitate and assure the implementation of intensity-modulated, customized plaque loading.

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