Abstract
AbstractIntratumoral heterogeneity presents a major challenge to diagnosis and treatment of glioblastoma (GBM). Such heterogeneity is further exacerbated upon the recurrence of GBM, where treatment-induced reactive changes produce additional intratumoral heterogeneity that is ambiguous to differentiate on clinical imaging. There is an urgent need to develop non-invasive approaches to map the heterogeneous landscape of histopathological alterations throughout the entire lesion for each patient. We propose to predictively fuse MRI with the underlying intratumoral heterogeneity in recurrent GBM using machine learning (ML) by leveraging unique image-localized biopsies with their associated locoregional MRI features. To this end, we develop BioNet, a biologically informed multi-task framework combining Bayesian neural networks and semi-supervised adversarial autoencoders, to predict regional distributions of three tissue-specific gene modules: proliferating tumor, reactive/inflammatory cells, and infiltrated brain tissue. BioNet provides insight into how to integrate implicit and hierarchical domain knowledge, which is difficult to incorporate into ML models through existing methods. The proposed architecture further addresses challenges in exploiting latent feature structures from limited labeled image-localized biopsy samples, which lead to improvements in prediction accuracy. BioNet performs significantly better than existing methods on cross-validation and blind test datasets, shows generalizability that surpasses other models, and is adaptable to different types of data or tasks. Prediction maps of gene modules from BioNet provide accurate predictions of intratumoral heterogeneity, which can improve surgical planning and localization of diagnostic biopsies, as well as inform neuro-oncological treatment assessment for each patient. These results also highlight the emerging role of ML in precision medicine.Significance StatementQuantitative assessments of intratumoral heterogeneity are limited by sparse biopsy sampling but is crucial for diagnosis, clinical management and treatment of (recurrent) glioblastoma. We propose leveraging a unique cohort of image-localized biopsies and their associated locoregional imaging features to develop a deep learning model, BioNet, that takes as input patient MRIs to predict output maps of the regional distributions of tissue-states. BioNet is able to (1) amplify the signal to noise ratio of the intratumoral genetic and cellular heterogeneity and (2) augment the learning capability of deep learning (DL) models through integrating implicit, hierarchical, but hard to be mathematically formulated domain knowledge. Our method performs significantly better than existing methods and is able to be adapted to related diseases.
Publisher
Cold Spring Harbor Laboratory