Using <i>in vivo</i> EPID images to detect and quantify patient anatomy changes with gradient dose segmented analysis

Steers, Jennifer M.; Bojorquez, Jorge Zavala; Moore, Kevin L.; Bojechko, C.

doi:10.1002/mp.14476

Cited by 6 publications

(16 citation statements)

References 20 publications

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“…Using the first fraction image, the high‐dose low‐gradient region of the images was selected using the gradient dose segmented analysis (GDSA) technique outlined in Steers et al. which demonstrated that the GDSA technique is able to identify patient anatomy changes 25 …”

Section: Methodsmentioning

confidence: 99%

“…Using the first fraction image, the high-dose low-gradient region of the images was selected using the gradient dose segmented analysis (GDSA) technique outlined in Steers et al which demonstrated that the GDSA technique is able to identify patient anatomy changes. 25 The dosimetric impacts of anatomy changes such as patient weight loss, tumor shrinkage, and changes in bowel filling have been studied. The change in the Anatomical changes will also affect the shape of the distribution of relative pixel values.…”

Section: In Vivo Epid Approachmentioning

confidence: 99%

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Assessment of predictive indicators of acute gastrointestinal toxicity using in vivo transmission images

et al. 2021

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For pelvic and abdominal treatments, excess dose to the bowel can result in acute toxicities. Current estimates of bowel toxicity are based on pretreatment dose-volume histogram data. However, the actual dose the bowel receives depends on interfraction variations, such as patient anatomy changes. We propose a method to model bowel toxicities, incorporating in vivo patient information using transit electronic portal imaging device (EPID) images. Methods and materials: For 63 patients treated to the lower thorax, abdomen, or pelvis on the Varian Halcyon, weekly chart review was performed to obtain incidences of grade 2 or higher toxicity, RTOG scale. Twenty patients presented with acute gastrointestinal (GI) toxicity. All patients were treated with conventional fractionation. For each treatment plan, the absolute volume dose-volume histogram of the bowel was exported and analyzed. Additionally, for each fraction of treatment, in vivo EPID images were collected and used to estimate the change in radiation transmission during the course of treatment.A logistic model was used to test correlations between acute GI toxicity and bowel dosimetric parameters as well as metrics obtained from in vivo image measurements. After performing the fit to the in vivo EPID data, the bootstrap resampling method was used to create confidence intervals. In vivo EPID image metrics from an additional 42 patients treated to the lower thorax, abdomen, or pelvis were used to validate the logistic model fit. Results:The incidence of toxicity versus the volume of 40 Gy to the bowel space was fitted with a logistic function, which was superior to an average model (p < 0.0001) and agrees with previously published models. For the initial in vivo EPID data, the incidence of toxicity versus the sum of in vivo transmission measurements showed marginal significance after 15 fractions (p = 0.10) of treatment and a significance of p = 0.038 is seen at the 20th fraction,when compared to an average model. For the validation data set, the logistic model of the in vivo transmission measurement after 20 fractions was superior to the average model (p = 0.043), with the model falling within the 68% confidence interval of the fit of the initial data set. Conclusions: Dose-volume constraints to reduce the incidence of acute GI toxicity have been validated. The presented novel EPID transmission-based metric can be used to identify GI toxicity as patients progress through treatment.

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Section: Methodsmentioning

confidence: 99%

Section: In Vivo Epid Approachmentioning

confidence: 99%

Assessment of predictive indicators of acute gastrointestinal toxicity using in vivo transmission images

et al. 2021

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“…Additionally, detecting changes in machine output can be achieved by averaging these metrics for all patients treated on a given day and tracking over time. 14 …”

Section: Introductionmentioning

confidence: 99%

“…This work illustrated the use of the GDSA method to provide a simple metric to compare transit EPID images to predict changes in mean PTV dose (PTV D mean ) for detecting treatment errors, as well as the patient changes over the course of treatment. Additionally, detecting changes in machine output can be achieved by averaging these metrics for all patients treated on a given day and tracking over time 14 …”

Section: Introductionmentioning

confidence: 99%

“…Additionally, detecting changes in machine output can be achieved by averaging these metrics for all patients treated on a given day and tracking over time. 14 The purpose of this work is to present an automated EPID QA framework for the Varian Halcyon. This approach neither requires a complex commissioning process nor intensive computing resources, making it easily portable to other clinics with a Halcyon.…”

Section: Introductionmentioning

confidence: 99%

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Using eclipse scripting to fully automate in‐vivo image analysis to improve treatment quality and safety

Chalise

Bojechko

2022

J Applied Clin Med Phys

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Purpose An automated, in‐vivo system to detect patient anatomy changes and machine output was developed using novel analysis of in‐vivo electronic portal imaging device (EPID) images for every fraction of treatment on a Varian Halcyon. In‐vivo approach identifies errors that go undetected by routine quality assurance (QA) to compliment daily machine performance check (MPC), with minimal physicist workload. Methods Images for all fractions treated on a Halcyon were automatically downloaded and analyzed at the end of treatment day. For image analysis, compared to first fraction, the mean difference of high‐dose region of interest is calculated. This metric has shown to predict changes in planning treatment volume (PTV) mean dose. Flags are raised for: (Type‐A) treatment fraction whose mean difference exceeds 10%, to protect against large errors, and (Type‐B) patients with three consecutive fractions with mean exceeding ±3%, to protect against systematic trends. If a threshold is exceeded, a physicist is e‐mailed, a report for flagged patients, for investigation. To track machine output changes, for all patients treated on a day, the average and standard deviations are uploaded to a QA portal, along with the reviewed MPC, ensuring comprehensive QA for the Halcyon. To guide clinical implementation, a retrospective study from November 2017 till December 2020 was conducted, which grouped errors by treatment site. This framework has been used prospectively since January 2021. Results From retrospective data of 1633 patients (35 759 fractions), no Type‐A errors were found and only 45 patients (2.76%) had Type‐B errors. These Type‐B deviations were due to head‐and‐neck weight loss. For 6 months of prospective use (345 patients), 13 patients (3.7%) had Type‐B errors and no Type‐A errors. Conclusions This automated system protects against errors that can occur in vivo to provide a more comprehensive QA. This fully automated framework can be implemented in other centers with a Halcyon, requiring a desktop computer and analysis scripts.

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The application of gradient dose segmented analysis of in‐vivo EPID images for patients undergoing VMAT in a resource‐constrained environment

Reenen

Trauernicht

Bojechko

2023

J Applied Clin Med Phys

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The gamma analysis metric is a commonly used metric for VMAT plan evaluation. The major drawback of this is the lack of correlation between gamma passing rates and DVH values. The novel GDSAmean metric was developed by Steers et al. to quantify changes in the PTV mean dose (Dmean) for VMAT patients. The aim of this work is to apply the GDSA retrospectively on head‐and‐neck cancer patients treated on the newly acquired Varian Halcyon, to assess changes in GDSAmean, and to evaluate the cause of day‐to‐day changes in the time‐plot series. In‐vivo EPID transmission images of head‐and‐neck cancer patients treated between August 2019 and July 2020 were analyzed retrospectively. The GDSAmean was determined for all patients treated. The changes in patient anatomy and rotational errors were quantified using the daily CBCT images and added to a time‐plot with the daily change in GDSAmean. Over 97% of the delivered treatment fractions had a GDSAmean < 3%. Thirteen of the patients received at least one treatment fraction where the GDSAmean > 3%. Most of these deviations occurred for the later fractions of radiotherapy treatment. Additionally, 92% of these patients were treated for malignancies involving the larynx and oropharynx. Notable deviations in the effective separation diameters were observed for 62% of the patients where the change in GDSAmean > 3%. For the other five cases with GDSAmean < 3%, the mean pitch, roll, and yaw rotational errors were 0.90°, 0.45°, and 0.43°, respectively. A GDSAmean > 3% was more likely due to a change in separation, whereas a GDSAmean < 3% was likely caused by rotational errors. Pitch errors were shown to be the most dominant. The GDSAmean is easily implementable and can aid in scheduling new CT scans for patients before significant deviations in dose delivery occur.

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Using in vivo EPID images to detect and quantify patient anatomy changes with gradient dose segmented analysis

Cited by 6 publications

References 20 publications

Assessment of predictive indicators of acute gastrointestinal toxicity using in vivo transmission images

Assessment of predictive indicators of acute gastrointestinal toxicity using in vivo transmission images

Using eclipse scripting to fully automate in‐vivo image analysis to improve treatment quality and safety

The application of gradient dose segmented analysis of in‐vivo EPID images for patients undergoing VMAT in a resource‐constrained environment

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