Metabolic Signatures Derived from Whole-brain MR-spectroscopy Identify Early Tumor Progression in High-grade Gliomas Using Machine Learning

Overview

Journal J Neurooncol

Publisher Springer

Date 2024 Aug 24

PMID 39180640

Authors

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

Affiliations

Soon will be listed here.

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.

Citing Articles

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