胶质瘤
磁共振成像
医学
核医学
特征(语言学)
放射科
肿瘤分级
人工智能
模式识别(心理学)
医学影像学
数据集
集合(抽象数据类型)
谱线
放射治疗
训练集
计算机科学
Boosting(机器学习)
放射治疗计划
系综平均
切除术
文本挖掘
作者
Irvane Ngnie Kamga,Jacob Ellison,Nate Tran,Joanna J. Phillips,Annette M Molinaro,Yan Li,Tracy Luks,Anny Shai,Devika Nair,Marisa Lafontaine,Angela Jakary,Javier Villanueva-Meyer,Mitchel S. Berger,Shawn L. Hervey‐Jumper,Manish K. Aghi,Susan M. Chang,Janine Lupo
出处
期刊:Neuro-oncology
[Oxford University Press]
日期:2025-11-01
卷期号:27 (Supplement_5): v305-v306
标识
DOI:10.1093/neuonc/noaf201.1208
摘要
Abstract INTRODUCTION An ongoing challenge faced in neuro-oncology is non-invasively distinguishing treatment-induced effects (TxE) following chemotherapy and/or radiation therapy from true tumor recurrence (rTumor). Previous research has explored the utility of AI-based models for this task but has overlooked within-lesion heterogeneity and the non-enhancing, T2-lesion. We investigated the value of integrating models trained using: 1) multi-parametric MRI (mpMRI) including anatomical, diffusion-weighted, and perfusion-weighted images, and 2) individual spectra from 1cc regions surrounding the tissue-sample locations, to improve the discrimination of treatment-effect from tumor recurrence. METHODS This retrospective study included 144 high-grade glioma patients who underwent MRI scans before surgical resection for suspected recurrence. Imaging included standard anatomical, diffusion-weighted, and dynamic-susceptibility-contrast perfusion-weighted MRI, and lactate-edited ¹H-MRSI. 324 spatially-localized tissue-samples were histopathologically classified as TxE or rTumor. The mpMRI model utilized 10 mm volumetric patches of each standardized image contrast (T2-FLAIR, T1-post-contrast, peak height and %-recovery from perfusion, ADC and FA from diffusion) centered on the tissue sample coordinates and generated 20 ensemble predictions. The AI-based spectra model predicted Ki-67, cellularity, and a composite tumor aggressiveness index from the entire 1D-spectrum reconstructed at the location of the tissue-sample. These predictions were concatenated into 4 machine-learning classifiers, which were trained on the combined feature set and on individual imaging and spectral features to assess model contributions. RESULTS Balancing the dataset enhanced the performance of all models, most notably that of gradient boosting (AU-ROC: 0.655 to 0.724). The radiopathomic spectra model increased performance of the weighted ensemble by 4% to 0.73+/-0.04 AU-ROC when integrated with our previously-developed mpMRI model. Three imaging features consistently ranked among the top five predictors across classifiers. CONCLUSION Integrating radiopathomic-derived features from an AI-based model using the entire spectrum with mpMRI features preserved diagnostic performance across all models, with a maximum improvement of 5.26% in AU-ROC. Current work is evaluating different strategies for combining models for contrast-enhancing and non-enhancing samples separately.
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