nnU-Net-based Segmentation of Tumor Subcompartments in Pediatric Medulloblastoma Using Multiparametric MRI: A Multi-institutional Study.

IF 8.1 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Radiology-Artificial Intelligence Pub Date : 2024-09-01 DOI:10.1148/ryai.230115

Rohan Bareja, Marwa Ismail, Douglas Martin, Ameya Nayate, Ipsa Yadav, Murad Labbad, Prateek Dullur, Sanya Garg, Benita Tamrazi, Ralph Salloum, Ashley Margol, Alexander Judkins, Sukanya Iyer, Peter de Blank, Pallavi Tiwari

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Abstract

Purpose To evaluate nnU-Net-based segmentation models for automated delineation of medulloblastoma tumors on multi-institutional MRI scans. Materials and Methods This retrospective study included 78 pediatric patients (52 male, 26 female), with ages ranging from 2 to 18 years, with medulloblastomas, from three different sites (28 from hospital A, 18 from hospital B, and 32 from hospital C), who had data available from three clinical MRI protocols (gadolinium-enhanced T1-weighted, T2-weighted, and fluid-attenuated inversion recovery). The scans were retrospectively collected from the year 2000 until May 2019. Reference standard annotations of the tumor habitat, including enhancing tumor, edema, and cystic core plus nonenhancing tumor subcompartments, were performed by two experienced neuroradiologists. Preprocessing included registration to age-appropriate atlases, skull stripping, bias correction, and intensity matching. The two models were trained as follows: (a) the transfer learning nnU-Net model was pretrained on an adult glioma cohort (n = 484) and fine-tuned on medulloblastoma studies using Models Genesis and (b) the direct deep learning nnU-Net model was trained directly on the medulloblastoma datasets, across fivefold cross-validation. Model robustness was evaluated on the three datasets when using different combinations of training and test sets, with data from two sites at a time used for training and data from the third site used for testing. Results Analysis on the three test sites yielded Dice scores of 0.81, 0.86, and 0.86 and 0.80, 0.86, and 0.85 for tumor habitat; 0.68, 0.84, and 0.77 and 0.67, 0.83, and 0.76 for enhancing tumor; 0.56, 0.71, and 0.69 and 0.56, 0.71, and 0.70 for edema; and 0.32, 0.48, and 0.43 and 0.29, 0.44, and 0.41 for cystic core plus nonenhancing tumor for the transfer learning and direct nnU-Net models, respectively. The models were largely robust to site-specific variations. Conclusion nnU-Net segmentation models hold promise for accurate, robust automated delineation of medulloblastoma tumor subcompartments, potentially leading to more effective radiation therapy planning in pediatric medulloblastoma. Keywords: Pediatrics, MR Imaging, Segmentation, Transfer Learning, Medulloblastoma, nnU-Net, MRI Supplemental material is available for this article. © RSNA, 2024 See also the commentary by Rudie and Correia de Verdier in this issue.

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基于 Nn-Unet 的多参数磁共振成像对小儿髓母细胞瘤肿瘤亚区的分割：一项多机构研究

"刚刚接受 "的论文经过同行评审，已被接受在《放射学》上发表：人工智能》上发表。这篇文章在以最终版本发表之前，还将经过校对、排版和校对审核。请注意，在制作最终校对稿的过程中，可能会发现影响内容的错误。目的评估基于 nn-Unet 的分割模型在多机构 MRI 扫描中自动划分髓母细胞瘤（MB）肿瘤的情况。材料与方法这项回顾性研究纳入了 78 名儿科患者（52 名男性，26 名女性），他们的年龄在 2-18 岁之间，患有来自三个不同部位的 MB 肿瘤（28 名来自 A 医院，18 名来自 B 医院，32 名来自 C 医院），他们拥有三种临床 MRI 方案（钆增强 T1 加权、T2 加权、FLAIR）的数据。这些扫描数据是回顾性收集的，时间从 2000 年至 2019 年 5 月。肿瘤生境的参考标准注释，包括增强肿瘤、水肿、囊性核心+非增强肿瘤亚分区，由两位经验丰富的神经放射科医生完成。预处理包括与年龄相适应的图谱配准、头骨剥离、偏差校正和强度匹配。两个模型的训练方法如下：(1) 转移学习 nn-Unet 模型在成人胶质瘤队列（n = 484）上进行预训练，并使用 Models Genesis 在 MB 研究上进行微调；(2) 直接深度学习 nn-Unet 模型直接在 MB 数据集上进行训练，并进行五倍交叉验证。使用不同的训练集和测试集组合在三个数据集上评估了模型的鲁棒性，每次使用两个站点的数据进行训练，使用第三个站点的数据进行测试。结果对 3 个测试点进行分析后发现，肿瘤生境的 Dice 分数分别为 0.81、0.86、0.86 和 0.80、0.86、0.85；肿瘤增强的 Dice 分数分别为 0.68、0.84、0.77 和 0.67、0.83、0.76；肿瘤生长的 Dice 分数分别为 0.56、0.对于转移学习模型和直接 nn-Unet 模型，水肿分别为 0.56、0.71、0.69 和 0.56、0.71、0.70；囊核 + 非增强肿瘤分别为 0.32、0.48、0.43 和 0.29、0.44、0.41。这些模型对特定部位的变化基本没有影响。结论 nn-Unet 分割模型有望准确、稳健地自动划分 MB 肿瘤亚分区，从而更有效地制定小儿 MB 放疗计划。©RSNA，2024。

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来源期刊

Radiology-Artificial Intelligence

CiteScore

16.20

自引率

1.00%

发文量

期刊介绍： Radiology: Artificial Intelligence is a bi-monthly publication that focuses on the emerging applications of machine learning and artificial intelligence in the field of imaging across various disciplines. This journal is available online and accepts multiple manuscript types, including Original Research, Technical Developments, Data Resources, Review articles, Editorials, Letters to the Editor and Replies, Special Reports, and AI in Brief.