Machine learning traction force maps for contractile cell monolayers

Machine learning offers immense potential as a transformative tool capable of reshaping optical microscopy and quantitative modeling in cell biology. Here we exemplify this potential through the development of a generative adversarial network (GAN) designed to comprehend and predict cell traction force maps. Empowered by a hybrid dataset from traction force microscopy (TFM) and phase-field modeling (PFM), the GAN learns the intricacies of the traction force maps of contractile cells in complex chemomechanical environments, with the sole input being the phase-contrast images of the cells. The trained GAN accurately predicts collective durotaxis by leveraging the learned asymmetric traction force maps, while also unveiling the concealed correlation between substrate stiffness and cell contractility arising from mechanotransduction. Remarkably, despite its foundation in epithelial cell data, our image-learning algorithm can be extended to other contractile cell types by adjusting a single scaling factor. Our approach underscores the potential of synergizing force microscopies and biophysical models with image-based learning, thus catalyzing data-driven scientific revelations in cell mechanobiology.

© This manuscript version is made available under the CC-BY-NC-ND 4.0 license https://creativecommons.org/licenses/by-nc-nd/4.0/

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Work Title Machine learning traction force maps for contractile cell monolayers
Access
Open Access
Creators
  1. Changhao Li
  2. Luyi Feng
  3. Yang Jeong Park
  4. Jian Yang
  5. Ju Li
  6. Sulin Zhang
Keyword
  1. Scientific machine learning
  2. Traction force microscopy
  3. Generative adversarial networks
  4. Phase-field simulations
  5. Cellular mechanics
License CC BY-NC-ND 4.0 (Attribution-NonCommercial-NoDerivatives)
Work Type Article
Publisher
  1. Extreme Mechanics Letters
Publication Date March 30, 2024
Publisher Identifier (DOI)
  1. https://doi.org/10.1016/j.eml.2024.102150
Deposited February 20, 2025

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  • Created

    February 20, 2025 15:22 by Researcher Metadata Database

  • Added main_text_EML_f-1.docx

    February 20, 2025 15:22 by Researcher Metadata Database

  • Added Creator Changhao Li

    February 20, 2025 15:22 by Researcher Metadata Database

  • Added Creator Luyi Feng

    February 20, 2025 15:22 by Researcher Metadata Database

  • Added Creator Yang Jeong Park

    February 20, 2025 15:22 by Researcher Metadata Database

  • Added Creator Jian Yang

    February 20, 2025 15:22 by Researcher Metadata Database

  • Added Creator Ju Li

    February 20, 2025 15:22 by Researcher Metadata Database

  • Added Creator Sulin Zhang

    February 20, 2025 15:22 by Researcher Metadata Database

  • Published

    February 20, 2025 15:22 by Researcher Metadata Database

  • Updated

    February 20, 2025 21:05 by [unknown user]

  • Updated Keyword, Publication Date Show Changes

    February 21, 2025 08:57 by avs5190

    Keyword
    • Scientific machine learning, Traction force microscopy, Generative adversarial networks, Phase-field simulations, Cellular mechanics
    Publication Date
    • 2024-03-21
    • 2024-03-30