Utilizing Radiomics of Peri‐Lesional Edema in T2‐FLAIR Subtraction Digital Images to Distinguish High‐Grade Glial Tumors From Brain Metastasis

IF 3.3 2区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Journal of Magnetic Resonance Imaging Pub Date : 2024-09-10 DOI:10.1002/jmri.29572

Emin Demirel, Okan Dilek

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引用次数: 0

Abstract

BackgroundDifferentiating high‐grade glioma (HGG) and isolated brain metastasis (BM) is important for determining appropriate treatment. Radiomics, utilizing quantitative imaging features, offers the potential for improved diagnostic accuracy in this context.PurposeTo differentiate high‐grade (grade 4) glioma and BM using machine learning models from radiomics data obtained from T2‐FLAIR digital subtraction images and the peritumoral edema area.Study TypeRetrospective.PopulationThe study included 1287 patients. Of these, 602 were male and 685 were female. Of the 788 HGG patients included in the study, 702 had solitary masses. Of the 499 BM patients included in the study, 112 had solitary masses. Initially, the model was developed and tested on solitary masses. Subsequently, the model was developed and tested separately for all patients (solitary and multiple masses).Field Strength/SequenceAxial T2‐weighted fast spin‐echo sequence (T2WI) and T2‐weighted fluid‐attenuated inversion recovery sequence (T2‐FLAIR), using 1.5‐T and 3.0‐T scanners.AssessmentRadiomic features were extracted from digitally subtracted T2‐FLAIR images in the area of peritumoral edema. The maximum relevance‐minimum redundancy (mRMR) method was then used for dimensionality reduction. The naive Bayes algorithm was used in model development. The interpretability of the model was explored using SHapley Additive exPlanations (SHAP).Statistical TestsChi‐square test, one‐way analysis of variance, and Kruskal–Wallis test were performed. The P values <0.05 were considered statistically significant. The performance metrics include area under curve (AUC), sensitivity (SENS), and specificity (SPEC).ResultsThe mean age of HGG patients was 61.4 ± 13.2 years and 61.7 ± 12.2 years for BM patients. In the external validation cohort, the model achieved AUC: 0.991, SENS: 0.983, and SPEC: 0.922. The external cohort results for patients with solitary lesions were AUC: 0.987, SENS: 0.950, and SPEC: 0.922.Data ConclusionThe artificial intelligence model, developed with radiomics data from the peritumoral edema area in T2‐FLAIR digital subtraction images, might be able to differentiate isolated BM from HGG.Evidence Level3Technical EfficacyStage 2

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利用 T2-FLAIR 减影数字图像中叶周水肿的放射组学来区分高级别胶质瘤和脑转移瘤

背景区分高级别胶质瘤（HGG）和孤立的脑转移瘤（BM）对于确定适当的治疗非常重要。目的利用从 T2-FLAIR 数字减影图像和瘤周水肿区获得的放射组学数据建立机器学习模型，区分高级别（4 级）胶质瘤和脑转移瘤。其中男性 602 人，女性 685 人。在纳入研究的 788 例 HGG 患者中，702 例为单发肿块。在纳入研究的 499 名 BM 患者中，112 人有单发肿块。最初，该模型是针对单发肿块开发和测试的。场强/序列使用 1.5-T 和 3.0-T 扫描仪进行轴向 T2 加权快速自旋回波序列（T2WI）和 T2 加权液体增强反转恢复序列（T2-FLAIR）。评估从数字减影的 T2-FLAIR 图像中提取瘤周水肿区域的放射学特征。然后使用最大相关性-最小冗余（mRMR）方法进行降维。在建立模型时使用了天真贝叶斯算法。统计检验进行了秩方检验、单因素方差分析和 Kruskal-Wallis 检验。P 值为 0.05 时具有统计学意义。结果HGG患者的平均年龄为（61.4±13.2）岁，BM患者的平均年龄为（61.7±12.2）岁。在外部验证队列中，该模型的AUC为0.991，SENS为0.991，特异性为0.991：0.991，SENS：0.983，SPEC：0.922。单发病灶患者的外部队列结果为 AUC：0.987，SENS：0.983，SPEC：0.922：数据结论利用 T2-FLAIR 数字减影图像中瘤周水肿区的放射组学数据开发的人工智能模型可能能够区分孤立性 BM 和 HGG。

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来源期刊

Journal of Magnetic Resonance Imaging 医学-核医学

CiteScore

9.70

自引率

6.80%

发文量

494

审稿时长

2 months

期刊介绍： The Journal of Magnetic Resonance Imaging (JMRI) is an international journal devoted to the timely publication of basic and clinical research, educational and review articles, and other information related to the diagnostic applications of magnetic resonance.