Cameron A Rivera, Shovan Bhatia, Alexis A Morell, Lekhaj C Daggubati, Martin A Merenzon, Sulaiman A Sheriff, Evan Luther, Jay Chandar, Adam S Levy, Ashley R Metzler, Chandler N Berke, Mohammed Goryawala, Eric A Mellon, Rita G Bhatia, Natalya Nagornaya, Gaurav Saigal, Macarena I de la Fuente, Ricardo J Komotar, Michael E Ivan, Ashish H Shah
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引用次数: 0
Abstract
Purpose: Recurrence for high-grade gliomas is inevitable despite maximal safe resection and adjuvant chemoradiation, and current imaging techniques fall short in predicting future progression. However, we introduce a novel whole-brain magnetic resonance spectroscopy (WB-MRS) protocol that delves into the intricacies of tumor microenvironments, offering a comprehensive understanding of glioma progression to inform expectant surgical and adjuvant intervention.
Methods: We investigated five locoregional tumor metabolites in a post-treatment population and applied machine learning (ML) techniques to analyze key relationships within seven regions of interest: contralateral normal-appearing white matter (NAWM), fluid-attenuated inversion recovery (FLAIR), contrast-enhancing tumor at time of WB-MRS (Tumor), areas of future recurrence (AFR), whole-brain healthy (WBH), non-progressive FLAIR (NPF), and progressive FLAIR (PF). Five supervised ML classification models and a neural network were developed, optimized, trained, tested, and validated. Lastly, a web application was developed to host our novel calculator, the Miami Glioma Prediction Map (MGPM), for open-source interaction.
Results: Sixteen patients with histopathological confirmation of high-grade glioma prior to WB-MRS were included in this study, totaling 118,922 whole-brain voxels. ML models successfully differentiated normal-appearing white matter from tumor and future progression. Notably, the highest performing ML model predicted glioma progression within fluid-attenuated inversion recovery (FLAIR) signal in the post-treatment setting (mean AUC = 0.86), with Cho/Cr as the most important feature.
Conclusions: This study marks a significant milestone as the first of its kind to unveil radiographic occult glioma progression in post-treatment gliomas within 8 months of discovery. These findings underscore the utility of ML-based WB-MRS growth predictions, presenting a promising avenue for the guidance of early treatment decision-making. This research represents a crucial advancement in predicting the timing and location of glioblastoma recurrence, which can inform treatment decisions to improve patient outcomes.
目的:尽管进行了最大限度的安全切除和辅助化疗,高级别胶质瘤的复发仍不可避免,而目前的成像技术在预测未来进展方面存在不足。然而,我们引入了一种新型全脑磁共振波谱(WB-MRS)方案,该方案可深入研究错综复杂的肿瘤微环境,从而全面了解胶质瘤的进展情况,为预期的手术和辅助干预提供依据:我们研究了治疗后人群中五个局部区域的肿瘤代谢物,并应用机器学习(ML)技术分析了七个感兴趣区域内的关键关系:对侧正常显示白质(NAWM)、流体增强反转恢复(FLAIR)、WB-MRS(肿瘤)时对比度增强的肿瘤、未来复发区域(AFR)、全脑健康区域(WBH)、非进展性FLAIR(NPF)和进展性FLAIR(PF)。开发、优化、训练、测试和验证了五个有监督的 ML 分类模型和一个神经网络。最后,还开发了一个网络应用程序,用于托管我们的新型计算器--迈阿密胶质瘤预测图(MGPM),以便进行开源互动:本研究共纳入了16名在WB-MRS检查前经组织病理学证实为高级别胶质瘤的患者,共计118,922个全脑体素。ML 模型成功地将正常外观的白质与肿瘤和未来的进展区分开来。值得注意的是,性能最高的 ML 模型可预测治疗后流体增强反转恢复(FLAIR)信号中的胶质瘤进展(平均 AUC = 0.86),Cho/Cr 是最重要的特征:这项研究是一个重要的里程碑,它首次揭示了治疗后胶质瘤在发现后8个月内的放射学隐匿性胶质瘤进展。这些发现强调了基于 ML 的 WB-MRS 生长预测的实用性,为指导早期治疗决策提供了一个前景广阔的途径。这项研究在预测胶质母细胞瘤复发的时间和位置方面取得了重要进展,可为改善患者预后的治疗决策提供依据。
期刊介绍:
The Journal of Neuro-Oncology is a multi-disciplinary journal encompassing basic, applied, and clinical investigations in all research areas as they relate to cancer and the central nervous system. It provides a single forum for communication among neurologists, neurosurgeons, radiotherapists, medical oncologists, neuropathologists, neurodiagnosticians, and laboratory-based oncologists conducting relevant research. The Journal of Neuro-Oncology does not seek to isolate the field, but rather to focus the efforts of many disciplines in one publication through a format which pulls together these diverse interests. More than any other field of oncology, cancer of the central nervous system requires multi-disciplinary approaches. To alleviate having to scan dozens of journals of cell biology, pathology, laboratory and clinical endeavours, JNO is a periodical in which current, high-quality, relevant research in all aspects of neuro-oncology may be found.
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