Deep learning-based detection of primary bone tumors around the knee joint on radiographs: a multicenter study.

IF 2.9 2区 医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Quantitative Imaging in Medicine and Surgery Pub Date : 2024-08-01 Epub Date: 2024-07-12 DOI:10.21037/qims-23-1743
Danyang Xu, Bing Li, Weixiang Liu, Dan Wei, Xiaowu Long, Tanyu Huang, Hongxin Lin, Kangyang Cao, Shaonan Zhong, Jingjing Shao, Bingsheng Huang, Xian-Fen Diao, Zhenhua Gao
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引用次数: 0

Abstract

Background: Most primary bone tumors are often found in the bone around the knee joint. However, the detection of primary bone tumors on radiographs can be challenging for the inexperienced or junior radiologist. This study aimed to develop a deep learning (DL) model for the detection of primary bone tumors around the knee joint on radiographs.

Methods: From four tertiary referral centers, we recruited 687 patients diagnosed with bone tumors (including osteosarcoma, chondrosarcoma, giant cell tumor of bone, bone cyst, enchondroma, fibrous dysplasia, etc.; 417 males, 270 females; mean age 22.8±13.2 years) by postoperative pathology or clinical imaging/follow-up, and 1,988 participants with normal bone radiographs (1,152 males, 836 females; mean age 27.9±12.2 years). The dataset was split into a training set for model development, an internal independent and an external test set for model validation. The trained model located bone tumor lesions and then detected tumor patients. Receiver operating characteristic curves and Cohen's kappa coefficient were used for evaluating detection performance. We compared the model's detection performance with that of two junior radiologists in the internal test set using permutation tests.

Results: The DL model correctly localized 94.5% and 92.9% bone tumors on radiographs in the internal and external test set, respectively. An accuracy of 0.964/0.920, and an area under the receiver operating characteristic curve (AUC) of 0.981/0.990 in DL detection of bone tumor patients were for the internal and external test set, respectively. Cohen's kappa coefficient of the model in the internal test set was significantly higher than that of the two junior radiologists with 4 and 3 years of experience in musculoskeletal radiology (Model vs. Reader A, 0.927 vs. 0.777, P<0.001; Model vs. Reader B, 0.927 vs. 0.841, P=0.033).

Conclusions: The DL model achieved good performance in detecting primary bone tumors around the knee joint. This model had better performance than those of junior radiologists, indicating the potential for the detection of bone tumors on radiographs.

基于深度学习的X光片膝关节周围原发性骨肿瘤检测:一项多中心研究。
背景:大多数原发性骨肿瘤通常出现在膝关节周围的骨骼中。然而,对于缺乏经验的放射科医生或初级放射科医生来说,在X光片上检测原发性骨肿瘤是一项挑战。本研究旨在开发一种深度学习(DL)模型,用于检测X光片上膝关节周围的原发性骨肿瘤:我们从四个三级转诊中心招募了 687 名确诊为骨肿瘤(包括骨肉瘤、软骨肉瘤、骨巨细胞瘤、骨囊肿、软骨瘤、纤维发育不良等)的患者。通过术后病理或临床成像/随访,1,988 名参与者(1,152 名男性,836 名女性;平均年龄(22.8±13.2)岁)的骨X光片正常。数据集分为用于模型开发的训练集、用于模型验证的内部独立测试集和外部测试集。训练模型定位骨肿瘤病灶,然后检测肿瘤患者。接收者操作特征曲线和科恩卡帕系数用于评估检测性能。在内部测试集中,我们使用置换检验将模型的检测性能与两名初级放射科医生的检测性能进行了比较:结果:在内部和外部测试集中,DL 模型分别有 94.5% 和 92.9% 的骨肿瘤被正确定位。在内部和外部测试集中,DL检测骨肿瘤患者的准确率分别为0.964/0.920,接收者工作特征曲线下面积(AUC)分别为0.981/0.990。在内部测试集中,模型的科恩卡帕系数(Cohen's kappa coefficient)明显高于两名分别有 4 年和 3 年肌肉骨骼放射学经验的初级放射科医生(模型与读者 A 的比较为 0.927 与 0.777,与读者 B 的比较为 0.927 与 0.841,P=0.033):DL模型在检测膝关节周围原发性骨肿瘤方面表现良好。结论:DL模型在检测膝关节周围的原发性骨肿瘤方面表现良好,其表现优于初级放射科医生,这表明该模型具有在X光片上检测骨肿瘤的潜力。
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来源期刊
Quantitative Imaging in Medicine and Surgery
Quantitative Imaging in Medicine and Surgery Medicine-Radiology, Nuclear Medicine and Imaging
CiteScore
4.20
自引率
17.90%
发文量
252
期刊介绍: Information not localized
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