Weakly-supervised Deep Learning Models Enable HER2-low Prediction from H &E Stained Slides

Overview

Journal Breast Cancer Res

Specialty Oncology

Date 2024 Aug 19

PMID 39160593

Authors

Renan Valieris

Luan Martins

Alexandre Defelicibus

Adriana Passos Bueno

Cynthia Aparecida Bueno de Toledo Osorio

Dirce Carraro

Emmanuel Dias-Neto

Rafael A Rosales

Jose Marcio Barros de Figueiredo

Israel Tojal Da Silva

Affiliations

Soon will be listed here.

Abstract

Background: Human epidermal growth factor receptor 2 (HER2)-low breast cancer has emerged as a new subtype of tumor, for which novel antibody-drug conjugates have shown beneficial effects. Assessment of HER2 requires several immunohistochemistry tests with an additional in situ hybridization test if a case is classified as HER2 2+. Therefore, novel cost-effective methods to speed up the HER2 assessment are highly desirable.

Methods: We used a self-supervised attention-based weakly supervised method to predict HER2-low directly from 1437 histopathological images from 1351 breast cancer patients. We built six distinct models to explore the ability of classifiers to distinguish between the HER2-negative, HER2-low, and HER2-high classes in different scenarios. The attention-based model was used to comprehend the decision-making process aimed at relevant tissue regions.

Results: Our results indicate that the effectiveness of classification models hinges on the consistency and dependability of assay-based tests for HER2, as the outcomes from these tests are utilized as the baseline truth for training our models. Through the use of explainable AI, we reveal histologic patterns associated with the HER2 subtypes.

Conclusion: Our findings offer a demonstration of how deep learning technologies can be applied to identify HER2 subgroup statuses, potentially enriching the toolkit available for clinical decision-making in oncology.

Citing Articles

Explainable AI for computational pathology identifies model limitations and tissue biomarkers.

Kaczmarzyk J, Saltz J, Koo P ArXiv. 2024; .

PMID: 39279830 PMC: 11398542.

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