手工 MRI 放射组学和机器学习：不定性实体肾上腺病变的分类。

Handcrafted MRI radiomics and machine learning: Classification of indeterminate solid adrenal lesions.

机构信息

Department of Advanced Biomedical Sciences, University of Naples "Federico II", Italy.

Department of Advanced Biomedical Sciences, University of Naples "Federico II", Italy; Augmented Reality for Health Monitoring Laboratory (ARHeMLab), Department of Electrical Engineering and Information Technology, University of Naples "Federico II", Italy.

出版信息

Magn Reson Imaging. 2021 Jun;79:52-58. doi: 10.1016/j.mri.2021.03.009. Epub 2021 Mar 13.

DOI:10.1016/j.mri.2021.03.009

PMID:33727148

Abstract

PURPOSE

To assess a radiomic machine learning (ML) model in classifying solid adrenal lesions (ALs) without fat signal drop on chemical shift (CS) as benign or malignant.

METHOD

55 indeterminate ALs (21 lipid poor adenomas, 15 benign pheocromocytomas, 1 oncocytoma, 12 metastases, 6 primary tumors) showing no fat signal drop on CS were retrospectively included. Manual 3D segmentation on T2-weighted and CS images was performed for subsequent radiomic feature extraction. After feature stability testing and an 80-20% train-test split, the train set was balanced via oversampling. Following a multi-step feature selection, an Extra Trees model was tuned with 5-fold stratified cross-validation in the train set and then tested on the hold-out test set.

RESULTS

A total of 3396 features were extracted from each AL, of which 133 resulted unstable while none had low variance (< 0.01). Highly correlated (r > 0.8) features were also excluded, leaving 440 parameters. Among these, Support Vector Machine 5-fold stratified cross-validated recursive feature elimination selected a subset of 6 features. ML obtained a cross-validation accuracy of 0.94 on the train and 0.91 on the test sets. Precision, recall and F1 score were respectively 0.92, 0.91 and 0.91.

CONCLUSIONS

Our MRI handcrafted radiomics and ML pipeline proved useful to characterize benign and malignant solid indeterminate adrenal lesions.

摘要

目的

评估一种基于放射组学机器学习（ML）的模型，用于对无化学位移（CS）脂肪信号下降的实性肾上腺病变（AL）进行良性或恶性分类。

方法

回顾性纳入 55 个不确定的 AL（21 个脂质缺乏性腺瘤、15 个良性嗜铬细胞瘤、1 个嗜酸细胞瘤、12 个转移瘤、6 个原发性肿瘤），这些病变在 CS 上均无脂肪信号下降。对 T2 加权和 CS 图像进行手动 3D 分割，以便随后进行放射组学特征提取。在进行特征稳定性测试和 80-20%的训练-测试分割后，通过过采样平衡训练集。经过多步特征选择，在训练集上使用 ExtraTrees 模型进行调优，并在保留的测试集上进行测试。

结果

从每个 AL 中提取了 3396 个特征，其中 133 个特征不稳定，而没有方差较低（<0.01）的特征。高度相关（r>0.8）的特征也被排除在外，留下 440 个参数。在这些参数中，支持向量机 5 倍分层交叉验证递归特征消除选择了一组 6 个特征。ML 在训练集上的交叉验证准确率为 0.94，在测试集上的准确率为 0.91。精度、召回率和 F1 评分分别为 0.92、0.91 和 0.91。

结论

我们的 MRI 手工放射组学和 ML 流水线证明对良性和恶性实性不确定肾上腺病变的特征描述有用。

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手工 MRI 放射组学和机器学习：不定性实体肾上腺病变的分类。

Handcrafted MRI radiomics and machine learning: Classification of indeterminate solid adrenal lesions.

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