基于 PET/CT 的卵巢癌三维多类语义分割及提取的放射组学特征的稳定性。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Mohammad Hossein Sadeghi, Sedigheh Sina, Mehrosadat Alavi, Francesco Giammarile, Chai Hong Yeong
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引用次数: 0

摘要

准确分割 PET/CT 图像中的卵巢癌(OC)病灶对于有效的疾病管理至关重要,然而用于放射组学分析的人工分割既费力又费时。本研究利用先进的三维网络,介绍了三维 U-Net 深度学习模型在 PET/CT 图像中卵巢癌多类语义分割中的应用,并评估了提取的放射组学特征的稳定性。利用来自39名OC患者的3120张PET/CT图像数据集,将数据集分为训练子集(70%)、验证子集(15%)和测试子集(15%),以优化和评估模型的性能。三维 U-Net 模型,尤其是以 VGG16 为骨干的模型,取得了显著的分割准确性,Dice 得分为 0.74,精确度为 0.76,召回率为 0.78。此外,该研究还证明了放射组学特征的高度稳定性,超过 85% 的 PET 和 84% 的 CT 图像特征显示出较高的类内相关系数(ICCs > 0.8)。这些结果凸显了基于三维 U-Net 的自动分割技术在显著提高 OC 诊断和治疗计划方面的潜力。自动分割提取的放射组学特征的可靠性支持其在临床决策和个性化医疗中的应用。这项研究标志着肿瘤诊断领域的重大进展,为 PET/CT 图像中的肿瘤病灶分割提供了一种稳健高效的方法。通过应对人工分割的挑战和展示三维网络的有效性,这项研究为越来越多的证据支持人工智能在提高肿瘤学诊断准确性和患者预后方面的应用做出了贡献。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
PET/CT-based 3D multi-class semantic segmentation of ovarian cancer and the stability of the extracted radiomics features.

Accurate segmentation of ovarian cancer (OC) lesions in PET/CT images is essential for effective disease management, yet manual segmentation for radiomics analysis is labor-intensive and time-consuming. This study introduces the application of a 3D U-Net deep learning model, leveraging advanced 3D networks, for multi-class semantic segmentation of OC in PET/CT images and assesses the stability of the extracted radiomics features. Utilizing a dataset of 3120 PET/CT images from 39 OC patients, the dataset was divided into training (70%), validation (15%), and test (15%) subsets to optimize and evaluate the model's performance. The 3D U-Net model, especially with a VGG16 backbone, achieved notable segmentation accuracy with a Dice score of 0.74, Precision of 0.76, and Recall of 0.78. Additionally, the study demonstrated high stability in radiomics features, with over 85% of PET and 84% of CT image features showing high intraclass correlation coefficients (ICCs > 0.8). These results underscore the potential of automated 3D U-Net-based segmentation to significantly enhance OC diagnosis and treatment planning. The reliability of the extracted radiomics features from automated segmentation supports its application in clinical decision-making and personalized medicine. This research marks a significant advancement in oncology diagnostics, providing a robust and efficient method for segmenting OC lesions in PET/CT images. By addressing the challenges of manual segmentation and demonstrating the effectiveness of 3D networks, this study contributes to the growing body of evidence supporting the application of artificial intelligence in improving diagnostic accuracy and patient outcomes in oncology.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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