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Human-interpretable image features derived from densely mapped cancer pathology slides predict diverse molecular phenotypes

Author

Listed:
  • James A. Diao

    (PathAI, Inc.
    Harvard Medical School)

  • Jason K. Wang

    (PathAI, Inc.
    Harvard Medical School)

  • Wan Fung Chui

    (PathAI, Inc.
    Harvard Medical School)

  • Victoria Mountain

    (PathAI, Inc.)

  • Sai Chowdary Gullapally

    (PathAI, Inc.)

  • Ramprakash Srinivasan

    (PathAI, Inc.)

  • Richard N. Mitchell

    (Harvard Medical School
    Harvard Medical School)

  • Benjamin Glass

    (PathAI, Inc.)

  • Sara Hoffman

    (PathAI, Inc.)

  • Sudha K. Rao

    (PathAI, Inc.)

  • Chirag Maheshwari

    (PathAI, Inc.)

  • Abhik Lahiri

    (PathAI, Inc.)

  • Aaditya Prakash

    (PathAI, Inc.)

  • Ryan McLoughlin

    (PathAI, Inc.)

  • Jennifer K. Kerner

    (PathAI, Inc.)

  • Murray B. Resnick

    (PathAI, Inc.
    Warren Alpert Medical School)

  • Michael C. Montalto

    (PathAI, Inc.)

  • Aditya Khosla

    (PathAI, Inc.)

  • Ilan N. Wapinski

    (PathAI, Inc.)

  • Andrew H. Beck

    (PathAI, Inc.)

  • Hunter L. Elliott

    (PathAI, Inc.)

  • Amaro Taylor-Weiner

    (PathAI, Inc.)

Abstract

Computational methods have made substantial progress in improving the accuracy and throughput of pathology workflows for diagnostic, prognostic, and genomic prediction. Still, lack of interpretability remains a significant barrier to clinical integration. We present an approach for predicting clinically-relevant molecular phenotypes from whole-slide histopathology images using human-interpretable image features (HIFs). Our method leverages >1.6 million annotations from board-certified pathologists across >5700 samples to train deep learning models for cell and tissue classification that can exhaustively map whole-slide images at two and four micron-resolution. Cell- and tissue-type model outputs are combined into 607 HIFs that quantify specific and biologically-relevant characteristics across five cancer types. We demonstrate that these HIFs correlate with well-known markers of the tumor microenvironment and can predict diverse molecular signatures (AUROC 0.601–0.864), including expression of four immune checkpoint proteins and homologous recombination deficiency, with performance comparable to ‘black-box’ methods. Our HIF-based approach provides a comprehensive, quantitative, and interpretable window into the composition and spatial architecture of the tumor microenvironment.

Suggested Citation

  • James A. Diao & Jason K. Wang & Wan Fung Chui & Victoria Mountain & Sai Chowdary Gullapally & Ramprakash Srinivasan & Richard N. Mitchell & Benjamin Glass & Sara Hoffman & Sudha K. Rao & Chirag Mahesh, 2021. "Human-interpretable image features derived from densely mapped cancer pathology slides predict diverse molecular phenotypes," Nature Communications, Nature, vol. 12(1), pages 1-15, December.
  • Handle: RePEc:nat:natcom:v:12:y:2021:i:1:d:10.1038_s41467-021-21896-9
    DOI: 10.1038/s41467-021-21896-9
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    Cited by:

    1. Darui Jin & Shangying Liang & Artem Shmatko & Alexander Arnold & David Horst & Thomas G. P. Grünewald & Moritz Gerstung & Xiangzhi Bai, 2024. "Teacher-student collaborated multiple instance learning for pan-cancer PDL1 expression prediction from histopathology slides," Nature Communications, Nature, vol. 15(1), pages 1-14, December.

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