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Learning representations for image-based profiling of perturbations

Author

Listed:
  • Nikita Moshkov

    (HUN-REN Biological Research Centre)

  • Michael Bornholdt

    (Broad Institute of MIT and Harvard)

  • Santiago Benoit

    (Broad Institute of MIT and Harvard
    Carnegie Mellon University)

  • Matthew Smith

    (Broad Institute of MIT and Harvard
    Harvard College)

  • Claire McQuin

    (Broad Institute of MIT and Harvard)

  • Allen Goodman

    (Broad Institute of MIT and Harvard)

  • Rebecca A. Senft

    (Broad Institute of MIT and Harvard)

  • Yu Han

    (Broad Institute of MIT and Harvard)

  • Mehrtash Babadi

    (Broad Institute of MIT and Harvard)

  • Peter Horvath

    (HUN-REN Biological Research Centre)

  • Beth A. Cimini

    (Broad Institute of MIT and Harvard)

  • Anne E. Carpenter

    (Broad Institute of MIT and Harvard)

  • Shantanu Singh

    (Broad Institute of MIT and Harvard)

  • Juan C. Caicedo

    (Broad Institute of MIT and Harvard
    Morgridge Institute for Research
    University of Wisconsin-Madison)

Abstract

Measuring the phenotypic effect of treatments on cells through imaging assays is an efficient and powerful way of studying cell biology, and requires computational methods for transforming images into quantitative data. Here, we present an improved strategy for learning representations of treatment effects from high-throughput imaging, following a causal interpretation. We use weakly supervised learning for modeling associations between images and treatments, and show that it encodes both confounding factors and phenotypic features in the learned representation. To facilitate their separation, we constructed a large training dataset with images from five different studies to maximize experimental diversity, following insights from our causal analysis. Training a model with this dataset successfully improves downstream performance, and produces a reusable convolutional network for image-based profiling, which we call Cell Painting CNN. We evaluated our strategy on three publicly available Cell Painting datasets, and observed that the Cell Painting CNN improves performance in downstream analysis up to 30% with respect to classical features, while also being more computationally efficient.

Suggested Citation

  • Nikita Moshkov & Michael Bornholdt & Santiago Benoit & Matthew Smith & Claire McQuin & Allen Goodman & Rebecca A. Senft & Yu Han & Mehrtash Babadi & Peter Horvath & Beth A. Cimini & Anne E. Carpenter , 2024. "Learning representations for image-based profiling of perturbations," Nature Communications, Nature, vol. 15(1), pages 1-17, December.
    • Handle: RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-024-45999-1
    DOI: 10.1038/s41467-024-45999-1
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    References listed on IDEAS

    as
    1. Agnan Kessy & Alex Lewin & Korbinian Strimmer, 2018. "Optimal Whitening and Decorrelation," The American Statistician, Taylor & Francis Journals, vol. 72(4), pages 309-314, October.
    2. Lauren Schiff & Bianca Migliori & Ye Chen & Deidre Carter & Caitlyn Bonilla & Jenna Hall & Minjie Fan & Edmund Tam & Sara Ahadi & Brodie Fischbacher & Anton Geraschenko & Christopher J. Hunter & Subha, 2022. "Integrating deep learning and unbiased automated high-content screening to identify complex disease signatures in human fibroblasts," Nature Communications, Nature, vol. 13(1), pages 1-13, December.
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