Department of Radiology and Research Institute of Radiology, University of Ulsan College of Medicine, Asan Medical Center, 88 Olympic-ro 43-gil, Songpa-gu, Seoul, 05505, Korea.
Biomedical Research Center, Asan Institute for Life Sciences, Asan Medical Center, 88 Olympic-ro 43-gil, Songpa-gu, Seoul, 05505, Korea.
Sci Rep. 2022 Apr 25;12(1):6735. doi: 10.1038/s41598-022-10807-7.
Although CT radiomics has shown promising results in the evaluation of vertebral fractures, the need for manual segmentation of fractured vertebrae limited the routine clinical implementation of radiomics. Therefore, automated segmentation of fractured vertebrae is needed for successful clinical use of radiomics. In this study, we aimed to develop and validate an automated algorithm for segmentation of fractured vertebral bodies on CT, and to evaluate the applicability of the algorithm in a radiomics prediction model to differentiate benign and malignant fractures. A convolutional neural network was trained to perform automated segmentation of fractured vertebral bodies using 341 vertebrae with benign or malignant fractures from 158 patients, and was validated on independent test sets (internal test, 86 vertebrae [59 patients]; external test, 102 vertebrae [59 patients]). Then, a radiomics model predicting fracture malignancy on CT was constructed, and the prediction performance was compared between automated and human expert segmentations. The algorithm achieved good agreement with human expert segmentation at testing (Dice similarity coefficient, 0.93-0.94; cross-sectional area error, 2.66-2.97%; average surface distance, 0.40-0.54 mm). The radiomics model demonstrated good performance in the training set (AUC, 0.93). In the test sets, automated and human expert segmentations showed comparable prediction performances (AUC, internal test, 0.80 vs 0.87, p = 0.044; external test, 0.83 vs 0.80, p = 0.37). In summary, we developed and validated an automated segmentation algorithm that showed comparable performance to human expert segmentation in a CT radiomics model to predict fracture malignancy, which may enable more practical clinical utilization of radiomics.
虽然 CT 放射组学在评估椎体骨折方面显示出有前景的结果,但骨折椎体的手动分割限制了放射组学的常规临床应用。因此,需要自动分割骨折椎体,以便成功地将放射组学应用于临床。在本研究中,我们旨在开发和验证一种用于 CT 上骨折椎体自动分割的算法,并评估该算法在用于区分良性和恶性骨折的放射组学预测模型中的适用性。使用来自 158 名患者的 341 个良性或恶性骨折椎体,训练卷积神经网络以执行骨折椎体的自动分割,并在独立测试集(内部测试,86 个椎体[59 名患者];外部测试,102 个椎体[59 名患者])上进行验证。然后,构建了一个用于 CT 预测骨折恶性程度的放射组学模型,并比较了自动和人工专家分割的预测性能。该算法在测试时与人工专家分割具有良好的一致性(Dice 相似系数,0.93-0.94;截面积误差,2.66-2.97%;平均表面距离,0.40-0.54mm)。该放射组学模型在训练集上表现出良好的性能(AUC,0.93)。在测试集中,自动和人工专家分割的预测性能相当(AUC,内部测试,0.80 与 0.87,p=0.044;外部测试,0.83 与 0.80,p=0.37)。总之,我们开发和验证了一种自动分割算法,该算法在 CT 放射组学模型中预测骨折恶性程度的表现与人工专家分割相当,这可能使放射组学更实际地应用于临床。
