利用基于核磁共振成像的肿瘤位置三维概率分布,改进用于小儿低级别胶质瘤肿瘤分子亚型识别的深度学习模型。

IF 2.9 3区 医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING Canadian Association of Radiologists Journal-Journal De L Association Canadienne Des Radiologistes Pub Date : 2024-11-15 DOI:10.1177/08465371241296834
Khashayar Namdar, Matthias W Wagner, Kareem Kudus, Cynthia Hawkins, Uri Tabori, Birgit B Ertl-Wagner, Farzad Khalvati
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引用次数: 0

摘要

目的:小儿低级别胶质瘤(pLGG)是儿童中最常见的脑肿瘤,对 pLGG 的分子诊断有助于进行有针对性的治疗。我们使用基于核磁共振成像的卷积神经网络(CNNs)对 pLGG 进行分子亚型鉴定,并使用肿瘤位置概率图增强模型。材料与方法:2000年1月至2018年12月期间214例患者(110例男性,平均年龄8.54岁,143例BRAF融合和71例BRAF V600E突变pLGG肿瘤)的MRI FLAIR序列被纳入这项经REB批准的回顾性研究。肿瘤分割(感兴趣体积-VOIs)由儿科神经放射学研究员提供,并由儿科神经放射学专家验证。患者以 80/20 的比例随机分为开发组和测试组。将开发集中每个类别的三维二元 VOI 掩膜组合起来,得出肿瘤位置的概率密度函数。为 pLGG 的分子诊断开发了三种管道:基于位置的、基于 CNN 的和混合管道。实验以不同的模型初始化和数据分割重复进行了 100 次,计算了接收者操作特征曲线下面积(AUROC),并进行了学生 t 检验。结果基于位置的分类器的 AUROC 为 77.9,95% 置信区间 (CI)(76.8, 79.0)。基于 CNN 的分类器的 AUROC 为 86.1,95% 置信区间 (85.0, 87.3),而肿瘤定位引导的 CNN 则优于其他分类器,平均 AUROC 为 88.64,95% 置信区间 (87.6, 89.7),具有统计学意义(P 值 .0018)。结论将肿瘤位置概率图纳入 CNN 模型可显著改善 pLGG 的分子亚型鉴定。
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Improving Deep Learning Models for Pediatric Low-Grade Glioma Tumours Molecular Subtype Identification Using MRI-based 3D Probability Distributions of Tumour Location.

Purpose: Pediatric low-grade gliomas (pLGG) are the most common brain tumour in children, and the molecular diagnosis of pLGG enables targeted treatment. We use MRI-based Convolutional Neural Networks (CNNs) for molecular subtype identification of pLGG and augment the models using tumour location probability maps. Materials and Methods: MRI FLAIR sequences of 214 patients (110 male, mean age of 8.54 years, 143 BRAF fused and 71 BRAF V600E mutated pLGG tumours) from January 2000 to December 2018 were included in this retrospective REB-approved study. Tumour segmentations (volumes of interest-VOIs) were provided by a pediatric neuroradiology fellow and verified by a pediatric neuroradiologist. Patients were randomly split into development and test sets with an 80/20 ratio. The 3D binary VOI masks for each class in the development set were combined to derive the probability density functions of tumour location. Three pipelines for molecular diagnosis of pLGG were developed: location-based, CNN-based, and hybrid. The experiment was repeated 100 times each with different model initializations and data splits, and the Areas Under the Receiver Operating Characteristic Curve (AUROC) was calculated, and Student's t-test was conducted. Results: The location-based classifier achieved an AUROC of 77.9, 95% confidence interval (CI) (76.8, 79.0). CNN-based classifiers achieved an AUROC of 86.1, 95% CI (85.0, 87.3), while the tumour-location-guided CNNs outperformed the other classifiers with an average AUROC of 88.64, 95% CI (87.6, 89.7), which was statistically significant (P-value .0018). Conclusion: Incorporating tumour location probability maps into CNN models led to significant improvements for molecular subtype identification of pLGG.

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来源期刊
CiteScore
6.20
自引率
12.90%
发文量
98
审稿时长
6-12 weeks
期刊介绍: The Canadian Association of Radiologists Journal is a peer-reviewed, Medline-indexed publication that presents a broad scientific review of radiology in Canada. The Journal covers such topics as abdominal imaging, cardiovascular radiology, computed tomography, continuing professional development, education and training, gastrointestinal radiology, health policy and practice, magnetic resonance imaging, musculoskeletal radiology, neuroradiology, nuclear medicine, pediatric radiology, radiology history, radiology practice guidelines and advisories, thoracic and cardiac imaging, trauma and emergency room imaging, ultrasonography, and vascular and interventional radiology. Article types considered for publication include original research articles, critically appraised topics, review articles, guest editorials, pictorial essays, technical notes, and letter to the Editor.
期刊最新文献
Improving Deep Learning Models for Pediatric Low-Grade Glioma Tumours Molecular Subtype Identification Using MRI-based 3D Probability Distributions of Tumour Location. Patient Perspectives of Artificial Intelligence in Medical Imaging. Robotics in Interventional Radiology: Is the Force With Us? Planning a Successful Mid-Career Transition in Radiology: Integrating Leadership, Growth, and Personal Fulfilment. Managing Angiography Unit Failure in Interventional Radiology: Lessons in Crisis Management and Considerations in Prevention.
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