Deep Learning-based Auto-segmentation on CT and MRI for Abdominal Structures

Amjad, A.; Xu, Jiaofeng; Thill, D.; O’Connell, Nicolette; Buchanan, L.; Jones, Isabella; Hall, William A.; Erickson, Beth; Li, A.

doi:10.1016/j.ijrobp.2020.07.2276

Cited by 5 publications

(5 citation statements)

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“…Bobo et al 7 described their CNN for the multiorgan segmentation on abdominal MRI, with DSCs of 0.556 and 0.691 in the stomach and pancreas. Chen et al 8 and Amjad et al 9 reported similar results from their DL auto-segmentation solutions. These previous studies indicate that the DL auto-segmentation on MRI for complex organs (eg, bowels) is generally unacceptable for clinical use.…”

Section: Introductionmentioning

confidence: 55%

“…Although DL-based segmentation methods have enabled the organ auto-contouring and achieved great success in many clinical applications, the current auto-segmented contours of challenging organs, such as the bowels, can still be clinically unacceptable. 6 , 7 , 8 , 9 Inevitably, manual editing needs to be performed subsequently to make the contours acceptable. The manual editing is generally time-consuming and labor-intensive, especially for inaccurate contours with irregular shapes (eg, complex abdominal organs).…”

Section: Discussionmentioning

confidence: 99%

“…In recent years, deep learning (DL) techniques, particularly the convolutional neural networks (CNNs), have been successfully applied to automatically segment organs from medical images including MRI. 6 , 7 , 8 , 9 , 10 , 11 Although it has been well documented that such auto-segmentations can be more efficient compared with the time-consuming and labor-intensive manual delineations, available MRI-based auto-segmentation methods still have limited success, particularly for complex structures such as those in the abdomen. Fu et al 6 reported their DL auto-segmentation on MRI in the abdomen achieved average Dice similarity coefficients (DSCs) of 0.953, 0.931, 0.850, 0.866, and 0.655 for the liver, kidneys, stomach, bowels, and duodenum, respectively.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Automatic Contour Refinement for Deep Learning Auto-segmentation of Complex Organs in MRI-guided Adaptive Radiation Therapy

Ding

Zhang

Amjad

et al. 2022

Advances in Radiation Oncology

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Section: Introductionmentioning

confidence: 55%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Automatic Contour Refinement for Deep Learning Auto-segmentation of Complex Organs in MRI-guided Adaptive Radiation Therapy

Ding

Zhang

Amjad

et al. 2022

Advances in Radiation Oncology

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“…The proposed model can overcome such shortcomings by increasing the variability and heterogeneity of the training images, as well as by including images from a wider range of institutions. We used CT imaging to develop a deep learning model instead of using magnetic resonance imaging (MRI) or a combination of both, which might be more effective (46). The segmentation of small targets also remains a class of challenges to be solved.…”

Section: Discussionmentioning

confidence: 99%

A deep learning model based on the attention mechanism for automatic segmentation of abdominal muscle and fat for body composition assessment

Shen¹,

He²,

Ren³

et al. 2023

Quant Imaging Med Surg

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Background: Quantitative muscle and fat data obtained through body composition analysis are expected to be a new stable biomarker for the early and accurate prediction of treatment-related toxicity, treatment response, and prognosis in patients with lung cancer. The use of these biomarkers can enable the adjustment of individualized treatment regimens in a timely manner, which is critical to further improving patient prognosis and quality of life. We aimed to develop a deep learning model based on attention for fully automated segmentation of the abdomen from computed tomography (CT) to quantify body composition.Methods: A fully automatic segmentation deep learning model was designed based on the attention mechanism and using U-Net as the framework. Subcutaneous fat, skeletal muscle, and visceral fat were manually segmented by two experts to serve as ground truth labels. The performance of the model was evaluated using Dice similarity coefficients (DSCs) and Hausdorff distance at 95th percentile (HD95). Results:The mean DSC for subcutaneous fat and skeletal muscle were high for both the enhanced CT test set (0.93±0.06 and 0.96±0.02, respectively) and the plain CT test set (0.90±0.09 and 0.95±0.01, respectively).Nevertheless, the model did not perform well in the segmentation performance of visceral fat, especially for the enhanced CT test set. The mean DSC for the enhanced CT test set was 0.87±0.11, while the mean DSC for the plain CT test set was 0.92±0.03. We discuss the reasons for this result.Conclusions: This work demonstrates a method for the automatic outlining of subcutaneous fat, skeletal muscle, and visceral fat areas at L3.

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“…Additionally, DL models are being developed for fast segmentation of complex organs such as abdominal organs. The first DL model employing a voxel-wise label prediction CNN in conjunction with a correction network to segment liver, kidneys, stomach, bowel, and duodenum on TrueFISP 3D MRI was presented by Fu et al 62 For innovative techniques such as adaptive RT, multilayer learning including self -adaptive, active learning classification algorithm (SAALC) on T1w trueFISP, 63 DL architecture with short-and long-range residue and U-Net skip connection on T1w Dixon and T2w HASTE, 64 and 2D U-net and dense net on T1 VIBE MRIs, 65 have been proposed to deliver fast segmentation with high accuracy (dice > 0.8) for most of the abdominal organs.…”

Section: Automatic Segmentationmentioning

confidence: 99%

Multi‐parametric magnetic resonance imaging for radiation treatment planning

et al. 2022

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In recent years, multi-parametric magnetic resonance imaging (MpMRI) has played a major role in radiation therapy treatment planning. The superior soft tissue contrast, functional or physiological imaging capabilities, and the flexibility of site-specific image sequence development has placed MpMRI at the forefront. In this article, the present status of MpMRI for external beam radiation therapy planning is reviewed. Common MpMRI sequences, preprocessing, and quality assurance strategies are briefly discussed, and various image registration techniques and strategies are addressed. Image segmentation methods including automatic segmentation and deep learning techniques for organs at risk and target delineation are reviewed. Due to the advancement in MRI-guided online adaptive radiotherapy, treatment planning considerations addressing MRI only planning are also discussed. K E Y W O R D S MpMRI, MRI for treatment planning, MRI-guided radiotherapy 1 2 IMAGE SELECTION AND REGISTRATION Brief description of common MpMRI sequencesMpMRI sequences typically include multi-slice 2D and 3D images with T1 and T2 weighting and a variety of 2836

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Deep Learning-based Auto-segmentation on CT and MRI for Abdominal Structures

Cited by 5 publications

References 0 publications

Automatic Contour Refinement for Deep Learning Auto-segmentation of Complex Organs in MRI-guided Adaptive Radiation Therapy

Automatic Contour Refinement for Deep Learning Auto-segmentation of Complex Organs in MRI-guided Adaptive Radiation Therapy

A deep learning model based on the attention mechanism for automatic segmentation of abdominal muscle and fat for body composition assessment

Multi‐parametric magnetic resonance imaging for radiation treatment planning

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