Automated Deep Learning-Based Detection and Segmentation of Lung Tumors at CT.

IF 12.1 1区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Radiology Pub Date : 2025-01-01 DOI:10.1148/radiol.233029

Mehr Kashyap, Xi Wang, Neil Panjwani, Mohammad Hasan, Qin Zhang, Charles Huang, Karl Bush, Alexander Chin, Lucas K Vitzthum, Peng Dong, Sandra Zaky, Billy W Loo, Maximilian Diehn, Lei Xing, Ruijiang Li, Michael F Gensheimer

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引用次数: 0

Abstract

"Just Accepted" papers have undergone full peer review and have been accepted for publication in Radiology: Artificial Intelligence. This article will undergo copyediting, layout, and proof review before it is published in its final version. Please note that during production of the final copyedited article, errors may be discovered which could affect the content. Background Detection and segmentation of lung tumors on CT scans are critical for monitoring cancer progression, evaluating treatment responses, and planning radiation therapy; however, manual delineation is labor-intensive and subject to physician variability. Purpose To develop and evaluate an ensemble deep learning model for automating identification and segmentation of lung tumors on CT scans. Materials and Methods A retrospective study was conducted between July 2019 and November 2024 using a large dataset of CT simulation scans and clinical lung tumor segmentations from radiotherapy plans. This dataset was used to train a 3D U-Net-based, image-multiresolution ensemble model to detect and segment lung tumors on CT scans. Model performance was evaluated on internal and external test sets composed of CT simulation scans and lung tumor segmentations from two affiliated medical centers, including single primary and metastatic lung tumors. Performance metrics included sensitivity, specificity, false positive rate, and Dice similarity coefficient (DSC). Model-predicted tumor volumes were compared with physician-delineated volumes. Group comparisons were made with Wilcoxon signed-rank test or one-way ANOVA. P < 0.05 indicated statistical significance. Results The model, trained on 1,504 CT scans with clinical lung tumor segmentations, achieved 92% sensitivity (92/100) and 82% specificity (41/50) in detecting lung tumors on the combined 150-CT scan test set. For a subset of 100 CT scans with a single lung tumor each, the model achieved a median model-physician DSC of 0.77 (IQR: 0.65-0.83) and an interphysician DSC of 0.80 (IQR: 0.72-0.86). Segmentation time was shorter for the model than for physicians (mean 76.6 vs. 166.1-187.7 seconds; p<0.001). Conclusion Routinely collected radiotherapy data were useful for model training. The key strengths of the model include a 3D U-Net ensemble approach for balancing volumetric context with resolution, robust tumor detection and segmentation performance, and the ability to generalize to an external site.

查看原文本刊更多论文

基于深度学习的肺肿瘤CT自动检测与分割。

“刚刚接受”的论文经过了全面的同行评审，并已被接受发表在《放射学：人工智能》杂志上。这篇文章将经过编辑，布局和校样审查，然后在其最终版本出版。请注意，在最终编辑文章的制作过程中，可能会发现可能影响内容的错误。背景：在CT扫描上检测和分割肺肿瘤对于监测癌症进展、评估治疗反应和规划放射治疗至关重要；然而，手工描绘是劳动密集型的，并受到医生的变化。目的建立并评估用于CT扫描肺肿瘤自动识别和分割的集成深度学习模型。材料与方法回顾性研究于2019年7月至2024年11月期间进行，使用CT模拟扫描和放疗计划临床肺肿瘤切分的大型数据集。该数据集用于训练基于三维u - net的图像多分辨率集成模型，以检测和分割CT扫描上的肺肿瘤。模型的性能在由CT模拟扫描和来自两个附属医疗中心的肺肿瘤分割组成的内部和外部测试集上进行评估，包括单个原发性和转移性肺肿瘤。性能指标包括灵敏度、特异性、假阳性率和Dice相似系数（DSC）。将模型预测的肿瘤体积与医生描述的体积进行比较。组间比较采用Wilcoxon sign -rank检验或单因素方差分析。P < 0.05为有统计学意义。结果该模型对1504个临床肺肿瘤分割CT扫描进行训练，在150-CT联合扫描测试集上检测肺肿瘤的灵敏度为92%(92/100)，特异性为82%（41/50）。对于100次CT扫描中单个肺肿瘤的子集，该模型的中位模型-医生DSC为0.77 (IQR: 0.65-0.83)，医生间DSC为0.80 （IQR: 0.72-0.86）。模型的分割时间比医生短(平均76.6秒vs. 166.1-187.7秒；p

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来源期刊

Radiology 医学-核医学

CiteScore

35.20

自引率

3.00%

发文量

596

审稿时长

3.6 months

期刊介绍： Published regularly since 1923 by the Radiological Society of North America (RSNA), Radiology has long been recognized as the authoritative reference for the most current, clinically relevant and highest quality research in the field of radiology. Each month the journal publishes approximately 240 pages of peer-reviewed original research, authoritative reviews, well-balanced commentary on significant articles, and expert opinion on new techniques and technologies. Radiology publishes cutting edge and impactful imaging research articles in radiology and medical imaging in order to help improve human health.