Anatomically consistent CNN-based segmentation of organs-at-risk in cranial radiotherapy

Mlynarski, Pawel; Delingette, Hervé; Alghamdi, Hamza; Bondiau, Pierre‐Yves; Ayache, Nicholas

doi:10.1117/1.jmi.7.1.014502

Cited by 28 publications

(31 citation statements)

References 63 publications

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“…19,20 Researchers have used these networks to autosegment many anatomic sites using computed tomography, magnetic resonance imaging, positron emission tomography, x-rays, and ultrasound images resulting in rapid development and quick translation to the field of radiation oncology. Several studies have focused on normal tissue [21][22][23][24][25][26][27][28][29][30][31][32][33][34][35][36] and CTV [37][38][39][40] autosegmentation for HNC radiation therapy. In previous deep learning-based CTV autosegmentation work, researchers developed algorithms to autodelineate targets based on their risk (high-risk 37,38 or low-risk 37,39,40 CTVs) but lacked the ability to autodelineate individual lymph node levels.…”

Section: Introductionmentioning

confidence: 99%

Generating High-Quality Lymph Node Clinical Target Volumes for Head and Neck Cancer Radiation Therapy Using a Fully Automated Deep Learning-Based Approach

Cárdenas

Beadle

Garden

et al. 2021

International Journal of Radiation Oncology*Biology*Physics

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Purpose: To develop a deep learning model that generates consistent, high-quality lymph node clinical target volumes (CTV) contours for head and neck cancer (HNC) patients, as an integral part of a fully automated radiation treatment planning workflow. Methods and Materials: Computed tomography (CT) scans from 71 HNC patients were retrospectively collected and split into training (n Z 51), cross-validation (n Z 10), and test (n Z 10) data sets. All had target volume delineations covering lymph node levels Ia through V (Ia-V), Ib through V (Ib-V), II through IV (II-IV), and retropharyngeal (RP) nodes, which were previously approved by a radiation oncologist specializing in HNC. Volumes of interest (VOIs) about nodal levels were automatically identified using computer vision techniques. The VOI (cropped CT image) and approved contours were used to train a U-Net autosegmentation model. Each lymph node level was trained independently, with model parameters optimized by assessing performance on the cross-validation data set. Once optimal model parameters were identified, overlap and distance metrics were calculated between ground truth and autosegmentations on the test set. Lastly, this final model was used

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Section: Introductionmentioning

confidence: 99%

Generating High-Quality Lymph Node Clinical Target Volumes for Head and Neck Cancer Radiation Therapy Using a Fully Automated Deep Learning-Based Approach

Cárdenas

Beadle

Garden

et al. 2021

International Journal of Radiation Oncology*Biology*Physics

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“…Several planning studies have underlined the benefit of incorporating MR images in the planning process to delineate tumor and OARs, by significantly improving the imaging contrast compared to CT 21–24 . In the domain of MRI‐based HN organ automatic segmentation, there have been several studies on the single organ segmentation such as parotid 25 and multi‐organs including brainstem, eyes, lens, optic nerves, chiasm, and brain 26 . Promising segmentation results in terms of DSC can be found in the MRI‐based organ segmentation.…”

Section: Introductionmentioning

confidence: 99%

Head and neck multi‐organ auto‐segmentation on CT images aided by synthetic MRI

Liu

Lei

et al. 2020

Medical Physics

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Purpose: Because the manual contouring process is labor-intensive and time-consuming, segmentation of organs-at-risk (OARs) is a weak link in radiotherapy treatment planning process. Our goal was to develop a synthetic MR (sMR)-aided dual pyramid network (DPN) for rapid and accurate head and neck multi-organ segmentation in order to expedite the treatment planning process. Methods: Forty-five patients' CT, MR, and manual contours pairs were included as our training dataset. Nineteen OARs were target organs to be segmented. The proposed sMR-aided DPN method featured a deep attention strategy to effectively segment multiple organs. The performance of sMRaided DPN method was evaluated using five metrics, including Dice similarity coefficient (DSC), Hausdorff distance 95% (HD95), mean surface distance (MSD), residual mean square distance (RMSD), and volume difference. Our method was further validated using the 2015 head and neck challenge data. Results: The contours generated by the proposed method closely resemble the ground truth manual contours, as evidenced by encouraging quantitative results in terms of DSC using the 2015 head and neck challenge data. Mean DSC values of 0.

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“…Machine Vision has been a superior method for advancing many fields like Agriculture [21], biomedical engineering [23,19], industry [13] and others. Implementation of machine vision methods on the deep neural networks, especially using the convolution layers, has resulted in extremely accurate performing.…”

Section: Deep Convolutional Neural Networkmentioning

confidence: 99%

A Fully Automated Deep Learning-based Network For Detecting COVID-19 from a New And Large Lung CT Scan Dataset

Rahimzadeh

Attar

Sakhaei

2020

Preprint

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COVID-19 is a severe global problem, and one of the primary ways to decrease its casualties is the infected person's identification at the proper time. AI can play a significant role in these cases by monitoring and detecting infected persons in early-stage. In this paper, we aim to propose a high- speed and accurate fully-automated method to detect COVID-19 from the patient's CT scan. We introduce a new dataset that contains 48260 CT scan images from 282 normal persons and 15589 images from 95 patients with COVID-19 infection. Our proposed automated system takes all the CT scan image sequences of a patient as the input and determines if the patient is infected with COVID-19. At the first stage, this system runs the proposed image processing algorithm to discard those CT images that inside the lung is not properly visible in them. This helps to reduce the number of images that shall be processed, so it reduces the processing time. Also, running this algorithm makes the deep network at the next stage to analyze only the proper images and thus reduces false detections. At the next stage, we propose a new modified deep convolutional network that is based on ResNet50V2 and is enhanced by the feature pyramid network for classifying the selected CT images into COVID-19 or normal. After running these two phases, if enough number of chosen CT scan images of a patient be identified as COVID-19, the system considers that patient, infected to this disease. In the single image classification stage, the ResNet50V2 with feature pyramid network achieved 98.49% accuracy on more than 7996 validation images. At the fully automated phase, the automated system correctly identified almost 237 patients from 245 patients on average between five-folds with high speed. In the end, we also investigate the classified images with a feature visualization algorithm to indicate the area of infections in each image. We are implementing these materials on some medical centers in Iran, and we hope that it would be a great help in Intelligence disease detection anywhere.

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Anatomically consistent CNN-based segmentation of organs-at-risk in cranial radiotherapy

Cited by 28 publications

References 63 publications

Generating High-Quality Lymph Node Clinical Target Volumes for Head and Neck Cancer Radiation Therapy Using a Fully Automated Deep Learning-Based Approach

Generating High-Quality Lymph Node Clinical Target Volumes for Head and Neck Cancer Radiation Therapy Using a Fully Automated Deep Learning-Based Approach

Head and neck multi‐organ auto‐segmentation on CT images aided by synthetic MRI

A Fully Automated Deep Learning-based Network For Detecting COVID-19 from a New And Large Lung CT Scan Dataset

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