English

DynaCLR: Contrastive Learning of Cellular Dynamics with Temporal Regularization

Computer Vision and Pattern Recognition 2025-07-02 v2 Quantitative Methods

Abstract

We report DynaCLR, a self-supervised method for embedding cell and organelle Dynamics via Contrastive Learning of Representations of time-lapse images. DynaCLR integrates single-cell tracking and time-aware contrastive sampling to learn robust, temporally regularized representations of cell dynamics. DynaCLR embeddings generalize effectively to in-distribution and out-of-distribution datasets, and can be used for several downstream tasks with sparse human annotations. We demonstrate efficient annotations of cell states with a human-in-the-loop using fluorescence and label-free imaging channels. DynaCLR method enables diverse downstream biological analyses: classification of cell division and infection, clustering heterogeneous cell migration patterns, cross-modal distillation of cell states from fluorescence to label-free channel, alignment of asynchronous cellular responses and broken cell tracks, and discovering organelle response due to infection. DynaCLR is a flexible method for comparative analyses of dynamic cellular responses to pharmacological, microbial, and genetic perturbations. We provide PyTorch-based implementations of the model training and inference pipeline (https://github.com/mehta-lab/viscy) and a GUI (https://github.com/czbiohub-sf/napari-iohub) for the visualization and annotation of trajectories of cells in the real space and the embedding space.

Keywords

Cite

@article{arxiv.2410.11281,
  title  = {DynaCLR: Contrastive Learning of Cellular Dynamics with Temporal Regularization},
  author = {Eduardo Hirata-Miyasaki and Soorya Pradeep and Ziwen Liu and Alishba Imran and Taylla Milena Theodoro and Ivan E. Ivanov and Sudip Khadka and See-Chi Lee and Michelle Grunberg and Hunter Woosley and Madhura Bhave and Carolina Arias and Shalin B. Mehta},
  journal= {arXiv preprint arXiv:2410.11281},
  year   = {2025}
}

Comments

30 pages, 6 figures, 13 appendix figures, 5 videos (ancillary files)

R2 v1 2026-06-28T19:22:03.886Z