Modeling the temporal–spatial nature of the readout of an electronic portal imaging device (EPID)

Abbasian, Parandoush; McCowan, Peter M.; Rickey, Daniel W.; Uytven, Eric Van; McCurdy, Boyd

doi:10.1002/mp.14440

Cited by 3 publications

(1 citation statement)

References 28 publications

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“…Abbasian et al [40] showed that one could measure the timing and amplitude of linac dose pulses and use this to modify a 2D EPID dose image prediction method to account for the spatialtemporal readout nature of the Varian EPID. Improved 2D image prediction for individual EPID frames was demonstrated, of interest for real-time image comparison applications.…”

Section: Infrastructure Workmentioning

confidence: 99%

EPID-based in vivo dosimetry – new developments and applications

McCurdy

2023

J. Phys.: Conf. Ser.

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In vivo dosimetry has been shown to be a powerful quality assurance method in modern radiation therapy. The most common tool used for in vivo dosimetry is the electronic portal imaging device (EPID) which can quantitatively image the therapeutic beam fluence exiting the patient during treatment delivery. Since the last major literature review on this topic was published five years ago, the radiation oncology community has shown continued strong interest in this subject. Commercial options have become more widely available, with a related increase in validation efforts and sensitivity testing, while new applications continue to be explored. Work has been done to understand and increase the accuracy of the EPID for dosimetric applications, as well as continued efforts to provide practical, quantitative experiences from clinical implementation of in vivo dosimetry systems. This review examines the published literature related to in vivo EPID dosimetry from January 2017 to February 2022. The literature is classified into three main topical areas: (1) new or improved algorithmic developments including validation work, (2) applications of the in vivo EPID dosimetry method, and (3) error identification and error sensitivity analyses.

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Section: Infrastructure Workmentioning

confidence: 99%

EPID-based in vivo dosimetry – new developments and applications

McCurdy

2023

J. Phys.: Conf. Ser.

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Review of real time 2D dosimetry in external radiotherapy: Advancements and techniques

Freitas Nascimento,

Gasparini

2025

Radiation Measurements

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Impact of a novel multilayer imager on metal artifacts in MV-CBCT

et al. 2023

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Objective: Megavoltage cone-beam CT (MV-CBCT) imaging offers several advantages including reduced metal artifacts and accurate electron density mapping for adaptive or emergent situations. However, MV-CBCT imaging is limited by the poor efficiency of current detectors. Here we examine a new MV imager and compare CBCT reconstructions under clinically relevant scenarios. Approach: A multilayer imager (MLI), consisting of four vertically stacked standard flat-panel imagers, was mounted to a clinical linear accelerator. A custom anthropomorphic pelvis phantom with replaceable femoral heads was imaged using MV-CBCT and kV-CBCT. Bone, aluminum, and titanium were used as femoral head inserts. 8MU 2.5MV scans were acquired for all four layers and (as reference) the top layer. Prostate and bladder were contoured on a reference CT and transferred to the other scans after rigid registration, from which the structural similarity index measure (SSIM) was calculated. Prostate and bladder were also contoured on CBCT scans without guidance, and Dice coefficients were compared to CT contours.Main results: kV-CBCT demonstrated the highest SSIMs with bone inserts (prostate:0.86, bladder:0.94) and lowest with titanium inserts (0.32, 0.37). 4-layer MV-CBCT SSIMs were preserved with bone (0.75, 0.80) as compared to titanium (0.67, 0.74), outperforming kV-CBCT when metal is present. 1-layer MV-CBCT consistently underperformed 4-layer results across all phantom configurations. Unilateral titanium inserts and bilateral aluminum insert results fell between the bone and bilateral titanium results. Dice coefficients trended similarly, with 4-layer MV-CBCT reducing metal artifact impact relative to KV-CBCT to provide better soft-tissue identification. Significance: MV-CBCT with a 4-layer MLI showed improvement over single-layer MV scans, approaching kV-CBCT quality for soft-tissue contrast. In the presence of artifact-producing metal implants, four-layer MV-CBCT scans outperformed kV-CBCT by eliminating artifacts and single-layer MV-CBCT by reducing noise. MV-CBCT with a novel multi-layer imager may be a valuable alternative to kV-CBCT, particularly in the presence of metal.

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Modeling the temporal–spatial nature of the readout of an electronic portal imaging device (EPID)

Cited by 3 publications

References 28 publications

EPID-based in vivo dosimetry – new developments and applications

EPID-based in vivo dosimetry – new developments and applications

Review of real time 2D dosimetry in external radiotherapy: Advancements and techniques

Impact of a novel multilayer imager on metal artifacts in MV-CBCT

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