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基于超声图像的列线图,结合临床、影像组学和深度迁移学习特征,用于根据卵巢影像报告和数据系统(O-RADS)对卵巢肿块进行自动分类。

Ultrasound image-based nomogram combining clinical, radiomics, and deep transfer learning features for automatic classification of ovarian masses according to O-RADS.

作者信息

Liu Lu, Cai Wenjun, Tian Hongyan, Wu Beibei, Zhang Jing, Wang Ting, Hao Yi, Yue Guanghui

机构信息

Department of Ultrasound Medicine, South China Hospital, Medical School, Shenzhen University, Shenzhen, China.

Department of Ultrasound, Shenzhen University General Hospital, Medical School, Shenzhen University, Shenzhen, China.

出版信息

Front Oncol. 2024 May 15;14:1377489. doi: 10.3389/fonc.2024.1377489. eCollection 2024.

DOI:10.3389/fonc.2024.1377489
PMID:38812784
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11133542/
Abstract

BACKGROUND

Accurate and rapid discrimination between benign and malignant ovarian masses is crucial for optimal patient management. This study aimed to establish an ultrasound image-based nomogram combining clinical, radiomics, and deep transfer learning features to automatically classify the ovarian masses into low risk and intermediate-high risk of malignancy lesions according to the Ovarian- Adnexal Reporting and Data System (O-RADS).

METHODS

The ultrasound images of 1,080 patients with 1,080 ovarian masses were included. The training cohort consisting of 683 patients was collected at the South China Hospital of Shenzhen University, and the test cohort consisting of 397 patients was collected at the Shenzhen University General Hospital. The workflow included image segmentation, feature extraction, feature selection, and model construction.

RESULTS

The pre-trained Resnet-101 model achieved the best performance. Among the different mono-modal features and fusion feature models, nomogram achieved the highest level of diagnostic performance (AUC: 0.930, accuracy: 84.9%, sensitivity: 93.5%, specificity: 81.7%, PPV: 65.4%, NPV: 97.1%, precision: 65.4%). The diagnostic indices of the nomogram were higher than those of junior radiologists, and the diagnostic indices of junior radiologists significantly improved with the assistance of the model. The calibration curves showed good agreement between the prediction of nomogram and actual classification of ovarian masses. The decision curve analysis showed that the nomogram was clinically useful.

CONCLUSION

This model exhibited a satisfactory diagnostic performance compared to junior radiologists. It has the potential to improve the level of expertise of junior radiologists and provide a fast and effective method for ovarian cancer screening.

摘要

背景

准确快速地区分卵巢良性和恶性肿块对于患者的最佳管理至关重要。本研究旨在建立一种基于超声图像的列线图,该列线图结合临床、影像组学和深度迁移学习特征,根据卵巢附件报告和数据系统(O-RADS)将卵巢肿块自动分类为低风险和中高风险恶性病变。

方法

纳入1080例患有1080个卵巢肿块患者的超声图像。由683例患者组成的训练队列在深圳大学附属华南医院收集,由397例患者组成的测试队列在深圳大学总医院收集。工作流程包括图像分割、特征提取、特征选择和模型构建。

结果

预训练的Resnet-101模型表现最佳。在不同的单模态特征和融合特征模型中,列线图达到了最高水平的诊断性能(AUC:0.930,准确率:84.9%,灵敏度:93.5%,特异性:81.7%,阳性预测值:65.4%,阴性预测值:97.1%,精确率:65.4%)。列线图的诊断指标高于初级放射科医生,并且在模型的辅助下初级放射科医生的诊断指标显著提高。校准曲线显示列线图的预测与卵巢肿块的实际分类之间具有良好的一致性。决策曲线分析表明列线图在临床上是有用的。

结论

与初级放射科医生相比,该模型表现出令人满意的诊断性能。它有可能提高初级放射科医生的专业水平,并为卵巢癌筛查提供一种快速有效的方法。

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