ancer diagnosis, prognosis, and therapy responsepredictions from tissue specimens highly depend on the phe-notype and topological distribution of constituting histologicalentities. Thus, adequate tissue representations for encodinghistological entities is imperative for computer aided cancerpatient care. To this end, several approaches have leveragedcell-graphs that encode cell morphology and cell organizationto denote the tissue information. These allow for utilizing graphtheory and machine learning to map tissue representationsto tissue functionality to help quantify their relationship.Though cellular information is crucial, it is incomplete aloneto comprehensively characterize complex tissue structure. Weherein treat the tissue as a hierarchical composition of multipletypes of histological entities from fine to coarse level, capturingmultivariate tissue information at multiple levels. We proposea novel multi-level hierarchical entity-graph representationof tissue specimens to model hierarchical compositions thatencode histological entities as well as their intra- and inter-entity level interactions. Subsequently, a hierarchical graphneural network is proposed to operate on the hierarchicalentity-graph representation to map the tissue structure to tissuefunctionality. Specifically, for input histology images we utilizewell-defined cells and tissue regions to build HierArchical Cell-to-Tissue (HACT) graph representations, and deviseHACT-Net, a message passing graph neural network, to classify suchHACTrepresentations. As part of this work, we introducethe BReAst Carcinoma Subtyping (BRACS) dataset, a largecohort of Haematoxylin & Eosin stained breast tumor regions-of-interest, to evaluate and benchmark our proposed method-ology against pathologists and state-of-the-art computer-aideddiagnostic approaches. Through comparative assessment andablation studies, our proposed method is demonstrated to yieldsuperior classification results compared to alternative methodsas well as individual pathologists.
Hierarchical Graph Representations in Digital Pathology
N Brancati;G De Pietro;M Frucci;
2022
Abstract
ancer diagnosis, prognosis, and therapy responsepredictions from tissue specimens highly depend on the phe-notype and topological distribution of constituting histologicalentities. Thus, adequate tissue representations for encodinghistological entities is imperative for computer aided cancerpatient care. To this end, several approaches have leveragedcell-graphs that encode cell morphology and cell organizationto denote the tissue information. These allow for utilizing graphtheory and machine learning to map tissue representationsto tissue functionality to help quantify their relationship.Though cellular information is crucial, it is incomplete aloneto comprehensively characterize complex tissue structure. Weherein treat the tissue as a hierarchical composition of multipletypes of histological entities from fine to coarse level, capturingmultivariate tissue information at multiple levels. We proposea novel multi-level hierarchical entity-graph representationof tissue specimens to model hierarchical compositions thatencode histological entities as well as their intra- and inter-entity level interactions. Subsequently, a hierarchical graphneural network is proposed to operate on the hierarchicalentity-graph representation to map the tissue structure to tissuefunctionality. Specifically, for input histology images we utilizewell-defined cells and tissue regions to build HierArchical Cell-to-Tissue (HACT) graph representations, and deviseHACT-Net, a message passing graph neural network, to classify suchHACTrepresentations. As part of this work, we introducethe BReAst Carcinoma Subtyping (BRACS) dataset, a largecohort of Haematoxylin & Eosin stained breast tumor regions-of-interest, to evaluate and benchmark our proposed method-ology against pathologists and state-of-the-art computer-aideddiagnostic approaches. Through comparative assessment andablation studies, our proposed method is demonstrated to yieldsuperior classification results compared to alternative methodsas well as individual pathologists.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
