Deep learning model for automatic contouring of cardiovascular substructures on radiotherapy planning CT images: Dosimetric validation and reader study based clinical acceptability testing

Fernandes, Miguel Garrett; Bussink, Johan; Stam, Barbara; Wijsman, Robin; Schinagl, Dominic A.X.; Monshouwer, R.; Teuwen, Jonas

doi:10.1016/j.radonc.2021.10.008

Cited by 22 publications

(11 citation statements)

References 26 publications

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“…Two alternate auto-segmentation algorithms that use a neural network architecture have been published, subsequent to the development of the tool presented, trained using 3D-CT planning cases. The model published by Garrett Fernandes et al had DSC of 0.74–0.95 across the same set of substructures and the largest median absolute difference in mean doses in the range 0.1 Gy–1.0 Gy [35] . The model published by Van Velzen et al had a DSC of 0.76–0.88 and R 2 values for dosimetric parameters were 0.77–1.00 [53] .…”

Section: Discussionmentioning

confidence: 90%

“…In this study, a deep learning-based cardiac substructure auto-segmentation tool developed for use in 3D-CT scans was retrospectively evaluated in 20 patients that underwent 4D-CT planning. This particular tool was selected from the literature [35] , [36] , [37] , [38] , [39] , [40] , [41] , [42] , [43] , [44] , [45] , [46] due to its superiority in terms of structures included, performance metrics, applicability to lung cancer and availability. The cardiac substructure auto-segmentation available tools at the time of writing are compared in Supplementary Table 11 .…”

Section: Discussionmentioning

confidence: 99%

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Validation of an established deep learning auto-segmentation tool for cardiac substructures in 4D radiotherapy planning scans

Walls¹,

Giacometti²,

Apte

et al. 2022

Physics and Imaging in Radiation Oncology

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Section: Discussionmentioning

confidence: 90%

Section: Discussionmentioning

confidence: 99%

Validation of an established deep learning auto-segmentation tool for cardiac substructures in 4D radiotherapy planning scans

Walls¹,

Giacometti²,

Apte

et al. 2022

Physics and Imaging in Radiation Oncology

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“…Compared to many other studies presenting models for automatic segmentation of cardiac substructures, this work uses far less training data to achieve similar results, requiring only 10 images with manually contoured cardiac substructures compared to other approaches which used 41 [ 19 ], 127 [ 50 ], and 217 [ 14 ] cases for training. An overview of published tools for cardiac substructure segmentation can be found in a recent publication by Walls et al (Supplementary Table 11) [ 18 ].…”

Section: Discussionmentioning

confidence: 99%

“…This method has also been validated on an independent dataset [ 18 ], with results suggesting reduced accuracy when applied to new data as well as systematic variations. A DL model developed by Garrett Fernandes et al [ 50 ] to delineate these same cardiac substructures from a training dataset 127 CT scans was validated on an independent dataset and also achieved higher DSC values, however a substantial reduction in performance was observed on CT imaging acquired without contrast enhancement. A cascading deep learning model was recently proposed by van den Oever [ 19 ] which automatically segments the heart and chambers accurately, although this method was only tested on 6 patient CT scans.…”

Section: Discussionmentioning

confidence: 99%

Open-source, fully-automated hybrid cardiac substructure segmentation: development and optimisation

et al. 2023

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Radiotherapy for thoracic and breast tumours is associated with a range of cardiotoxicities. Emerging evidence suggests cardiac substructure doses may be more predictive of specific outcomes, however, quantitative data necessary to develop clinical planning constraints is lacking. Retrospective analysis of patient data is required, which relies on accurate segmentation of cardiac substructures. In this study, a novel model was designed to deliver reliable, accurate, and anatomically consistent segmentation of 18 cardiac substructures on computed tomography (CT) scans. Thirty manually contoured CT scans were included. The proposed multi-stage method leverages deep learning (DL), multi-atlas mapping, and geometric modelling to automatically segment the whole heart, cardiac chambers, great vessels, heart valves, coronary arteries, and conduction nodes. Segmentation performance was evaluated using the Dice similarity coefficient (DSC), mean distance to agreement (MDA), Hausdorff distance (HD), and volume ratio. Performance was reliable, with no errors observed and acceptable variation in accuracy between cases, including in challenging cases with imaging artefacts and atypical patient anatomy. The median DSC range was 0.81–0.93 for whole heart and cardiac chambers, 0.43–0.76 for great vessels and conduction nodes, and 0.22–0.53 for heart valves. For all structures the median MDA was below 6 mm, median HD ranged 7.7–19.7 mm, and median volume ratio was close to one (0.95–1.49) for all structures except the left main coronary artery (2.07). The fully automatic algorithm takes between 9 and 23 min per case. The proposed fully-automatic method accurately delineates cardiac substructures on radiotherapy planning CT scans. Robust and anatomically consistent segmentations, particularly for smaller structures, represents a major advantage of the proposed segmentation approach. The open-source software will facilitate more precise evaluation of cardiac doses and risks from available clinical datasets. Graphical abstract

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“…All patients had a spiral CT scan taken of 3 mm slice thickness (voxel dimensions 1 mm × 1 mm × 3 mm). The majority of CT scans are non-contrast scans, as per a recently published study that provided a quantitative analysis which classifies scans from this dataset as contrast or non-contrast 29 . At the time of initiation of the study (October 2018 to January 2019), radiotherapy structure sets were not available for 92 patients on the TCIA website and these were manually contoured at Peter MacCallum Cancer Centre (PMCC) by a radiation oncologist (GK) with additional review by a lung radiologist (BW) as required.…”

Section: Methodsmentioning

confidence: 99%

The impact of inter-observer variation in delineation on robustness of radiomics features in non-small cell lung cancer

Kothari

Woon

Patrick

et al. 2022

Sci Rep

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Artificial intelligence and radiomics have the potential to revolutionise cancer prognostication and personalised treatment. Manual outlining of the tumour volume for extraction of radiomics features (RF) is a subjective process. This study investigates robustness of RF to inter-observer variation (IOV) in contouring in lung cancer. We utilised two public imaging datasets: ‘NSCLC-Radiomics’ and ‘NSCLC-Radiomics-Interobserver1’ (‘Interobserver’). For ‘NSCLC-Radiomics’, we created an additional set of manual contours for 92 patients, and for ‘Interobserver’, there were five manual and five semi-automated contours available for 20 patients. Dice coefficients (DC) were calculated for contours. 1113 RF were extracted including shape, first order and texture features. Intraclass correlation coefficient (ICC) was computed to assess robustness of RF to IOV. Cox regression analysis for overall survival (OS) was performed with a previously published radiomics signature. The median DC ranged from 0.81 (‘NSCLC-Radiomics’) to 0.85 (‘Interobserver’—semi-automated). The median ICC for the ‘NSCLC-Radiomics’, ‘Interobserver’ (manual) and ‘Interobserver’ (semi-automated) were 0.90, 0.88 and 0.93 respectively. The ICC varied by feature type and was lower for first order and gray level co-occurrence matrix (GLCM) features. Shape features had a lower median ICC in the ‘NSCLC-Radiomics’ dataset compared to the ‘Interobserver’ dataset. Survival analysis showed similar separation of curves for three of four RF apart from ‘original_shape_Compactness2’, a feature with low ICC (0.61). The majority of RF are robust to IOV, with first order, GLCM and shape features being the least robust. Semi-automated contouring improves feature stability. Decreased robustness of a feature is significant as it may impact upon the features’ prognostic capability.

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Deep learning model for automatic contouring of cardiovascular substructures on radiotherapy planning CT images: Dosimetric validation and reader study based clinical acceptability testing

Cited by 22 publications

References 26 publications

Validation of an established deep learning auto-segmentation tool for cardiac substructures in 4D radiotherapy planning scans

Validation of an established deep learning auto-segmentation tool for cardiac substructures in 4D radiotherapy planning scans

Open-source, fully-automated hybrid cardiac substructure segmentation: development and optimisation

The impact of inter-observer variation in delineation on robustness of radiomics features in non-small cell lung cancer

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