Abstract
PurposeWe developed a compact and lightweight time-resolved mirrorless scintillation detector (TRMLSD) employing image processing techniques and a convolutional neural network (CNN) for high-resolution two-dimensional (2D) dosimetry.MethodsThe TRMLSD comprises a camera and an inorganic scintillator plate without a mirror. The camera was installed at a certain angle from the horizontal plane to collect scintillation from the scintillator plate. The geometric distortion due to the absence of a mirror and camera lens was corrected using a projective transform. Variations in brightness due to the distance between the image sensor and each point on the scintillator plate and the inhomogeneity of the material constituting the scintillator were corrected using a 20.0 × 20.0 cm2 radiation field. Hot pixels were removed using a frame-based noise-reduction technique. Finally, a CNN-based 2D dose distribution deconvolution model was applied to compensate for the dose error in the penumbra region and a lack of backscatter. The linearity, reproducibility, dose rate dependency, and dose profile were tested for a 6 MV X-ray beam to verify dosimeter characteristics. Gamma analysis was performed for two simple and 10 clinical intensity-modulated radiation therapy (IMRT) plans.ResultsThe dose linearity with brightness ranging from 0.0 cGy to 200.0 cGy was 0.9998 (R-squared value), and the root-mean-square error value was 1.010. For five consecutive measurements, the reproducibility was within 3% error, and the dose rate dependency was within 1%. The depth dose distribution and lateral dose profile coincided with the ionization chamber data with a 1% mean error. In 2D dosimetry for IMRT plans, the mean gamma passing rates with a 3%/3 mm gamma criterion for the two simple and ten clinical IMRT plans were 96.77% and 95.75%, respectively.ConclusionThe verified accuracy and time-resolved characteristics of the dosimeter may be useful for the quality assurance of machines and patient-specific quality assurance for clinical step-and-shoot IMRT plans.
Highlights
Two-dimensional (2D) dosimeters have been studied for many years
Each pixel value in the images captured by the time-resolved mirrorless scintillation detector (TRMLSD) was normalized to the pixel value of the radiation isocenter, and the inverse of each pixel value was saved as a 2D correction map
We studied the feasibility of using the TRMLSD for the measurement of the 2D dose distribution of a photon beam
Summary
Two-dimensional (2D) dosimeters have been studied for many years. Radiochromic films are used as absorbed dose dosimeters, and the most recent type, that is the Gafchromic EBT3 film (Ashland ISP Advanced Materials, NJ, USA), is widely applied clinically. The advantages of the EBT3 film are its high resolution and discoloration via a self-development process [1,2]. The EBT3 film must be managed extremely carefully [3,4,5], including its in-batch variation, film uniformity, and scanner dependency. Various background subtraction methods have been proposed [6,7]. The EBT3 film is a singlemeasurement dosimeter; multiple measurements require multiple films, and real-time dosimetry cannot be performed
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