PATH-08. Establishing the utility of deep-learning for H&E-based meningioma molecular classification and outcome prediction

Abstract

Abstract The introduction of genomic profiling as a tool for molecular classification and outcome prediction has revolutionized the care of patients with brain tumors. Artificial intelligence (AI) provides advanced avenues to convert complex genomic information into routinely available patient-level information. In this study, we leverage deep learning to demonstrate that H&E can robustly characterize the molecular subtypes of the most common brain tumor, meningioma. To do this, we created a cohort of 605 meningiomas with paired DNA methylation and matched digitized H&E images. We trained and validated dedicated deep learning models to predict molecular groups, relevant chromosomal arm aneuploidies (1p loss, 1q gain, 22q loss), and clinical outcomes using the H&E alone. AUROCs and balanced accuracy were used to assess classifier performance and risk-group-specific outcomes were compared using the log-rank test. Our deep learning classifier achieved a balanced accuracy of 87-97% for predicting molecular groups of meningiomas. Similar performance was achieved in the prediction of chromosomal aneuploidies. Our dedicated outcome prediction model was remarkably prognostic even when adjusting for WHO grade, extent of resection, and age (HR 3.49, 95% CI 1.54-7.91, p = 0.003), demonstrating the clear and immediate translational value of deep learning in this context. Beyond this direct translational utility, the generated AI models also provide novel insights into group-specific molecular heterogeneity which have not been detected using bulk genomic approaches to date. This work is the first to demonstrate the ability to apply deep learning models that can, beyond diagnosis, determine molecular subtypes and predict outcomes in a single brain tumour entity using H&E alone, which to date is only possible using resource-intensive genomic profiling. It further demonstrates the broad clinical utility of applying AI modelling to readily available H&E to democratize access to genomic information globally.

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