Evaluation of measures for assessing time-saving of automatic organ-at-risk segmentation in radiotherapy

Vaassen, Femke; Hazelaar, Colien; Vaniqui, Ana; Gooding, Mark J.; Heyden, Brent van der; Canters, R.; Elmpt, Wouter van

doi:10.1016/j.phro.2019.12.001

Cited by 120 publications

(134 citation statements)

References 23 publications

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“…Although it was expected that DLC would stop contouring at this point, it was also expected that manual adjustment would occur here depending on the PTV extent. DLC might be improved by contouring the whole spinal cord, as it is generally easier to delete than add [22] . However, such analysis would still demonstrate adjustment is required here as the guidelines accept some variation in where to stop.…”

Section: Discussionmentioning

confidence: 99%

“…As other studies have shown, variability in contouring does not result in significant dosimetric differences for the majority of organs [4] , [24] . A threshold for meaningful contour adjustments could possibly be set [22] , and RTTs trained to accept contours in cases not exceeding this threshold. Practical tools to guide the user in this decision-making process will enable further automation of contouring practice.…”

Section: Discussionmentioning

confidence: 99%

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Assessment of manual adjustment performed in clinical practice following deep learning contouring for head and neck organs at risk in radiotherapy

Brouwer

Boukerroui

Oliveira

et al. 2020

Physics and Imaging in Radiation Oncology

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Background and purpose: Auto-contouring performance has been widely studied in development and commissioning studies in radiotherapy, and its impact on clinical workflow assessed in that context. This study aimed to evaluate the manual adjustment of auto-contouring in routine clinical practice and to identify improvements regarding the auto-contouring model and clinical user interaction, to improve the efficiency of auto-contouring. Materials and methods: A total of 103 clinical head and neck cancer cases, contoured using a commercial deeplearning contouring system and subsequently checked and edited for clinical use were retrospectively taken from clinical data over a twelve-month period (April 2019-April 2020). The amount of adjustment performed was calculated, and all cases were registered to a common reference frame for assessment purposes. The median, 10th and 90th percentile of adjustment were calculated and displayed using 3D renderings of structures to visually assess systematic and random adjustment. Results were also compared to inter-observer variation reported previously. Assessment was performed for both the whole structures and for regional sub-structures, and according to the radiation therapy technologist (RTT) who edited the contour. Results: The median amount of adjustment was low for all structures (<2 mm), although large local adjustment was observed for some structures. The median was systematically greater or equal to zero, indicating that the auto-contouring tends to under-segment the desired contour. Conclusion: Auto-contouring performance assessment in routine clinical practice has identified systematic improvements required technically, but also highlighted the need for continued RTT training to ensure adherence to guidelines.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Assessment of manual adjustment performed in clinical practice following deep learning contouring for head and neck organs at risk in radiotherapy

Brouwer

Boukerroui

Oliveira

et al. 2020

Physics and Imaging in Radiation Oncology

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“…It would be good to benchmark the measures, because while DSC is reasonably straightforward, HD results can be influenced substantially by the calculation algorithm. It would be good to include surface DSC [24] and/or Added Path Length [25] , as these measures are a surrogate for the potential time saving of DLC in comparison to manual delineation. Valentini et al [2] recommended to evaluate time saving, together with an assessment of dosimetric impact.…”

Section: Discussionmentioning

confidence: 99%

External validation of deep learning-based contouring of head and neck organs at risk

Brunenberg

Steinseifer

Bosch

et al. 2020

Physics and Imaging in Radiation Oncology

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“…Whilst some CIs used here are mathematically correlated, using them together does not impact upon a model’s ability to make predictions of new observations on unseen data [25] and helps increase model complexity to reduce the likelihood of underfitting. Alternatively, the use of other types of mathematical metrics, such as the surface DSC [26] and added path length [27] , could be investigated to determine their suitability for this purpose.…”

Section: Discussionmentioning

confidence: 99%

Automatic evaluation of contours in radiotherapy planning utilising conformity indices and machine learning

Terparia

Mir

Tsang

et al. 2020

Physics and Imaging in Radiation Oncology

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Background and purpose: Peer-review of Target Volume (TV) and Organ at Risk (OAR) contours in radiotherapy planning are typically conducted visually; this can be time consuming and subject to interobserver variation. This study investigated automatic evaluation of contouring using conformity indices and supervised machine learning. Methods: A total of 393 contours from 253 Stereotactic Ablative Body Radiotherapy (SABR) benchmark cases (adrenal gland, liver, pelvic lymph node and spine), delineated by 132 clinicians from 25 centres, were visually evaluated for conformity against gold standard contours. Contours were scored as "pass" or "fail" on visual peer review and six Conformity Indices (CIs) were applied. CI values were mapped to pass/fail scores for each contour and used to train supervised machine learning models. A 5-fold cross validation method was employed to determine the predictive accuracies of each model. Results: The stomach structure produced models with the highest predictive accuracy overall (96% using Support Vector Machine and Ensemble models), whilst the liver GTV produced models with the lowest predictive accuracy (76% using Logistic Regression). Predictive accuracies across all models ranged from 68-96% (68-87% for TV and 71-96% for OARs). Conclusions: Although a final visual review by an experienced clinician is still required, the automatic contour evaluation method could reduce the time for benchmark case reviews by identifying gross contouring errors. This method could be successfully implemented to support departmental training and the continuous assessment of outlining for clinical staff in the peer-review process, to reduce interobserver variability in contouring and improve interpretation of radiological anatomy.

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Evaluation of measures for assessing time-saving of automatic organ-at-risk segmentation in radiotherapy

Cited by 120 publications

References 23 publications

Assessment of manual adjustment performed in clinical practice following deep learning contouring for head and neck organs at risk in radiotherapy

Assessment of manual adjustment performed in clinical practice following deep learning contouring for head and neck organs at risk in radiotherapy

External validation of deep learning-based contouring of head and neck organs at risk

Automatic evaluation of contours in radiotherapy planning utilising conformity indices and machine learning

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