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Paper detail

A statistical-inference approach to reconstruct inter-cellular interactions in cell-migration experiments

Migration of cells can be characterized by two, prototypical types of motion: individual and collective migration. We propose a statistical-inference approach designed to detect the presence of cell-cell interactions that give rise to collective behaviors in cell-motility experiments. Such inference method has been first successfully tested on synthetic motional data, and then applied to two experiments. In the first experiment, cell migrate in a wound-healing model: when applied to this experiment, the inference method predicts the existence of cell-cell interactions, correctly mirroring the strong intercellular contacts which are present in the experiment. In the second experiment, dendritic cells migrate in a chemokine gradient. Our inference analysis does not provide evidence for interactions, indicating that cells migrate by sensing independently the chemokine source. According to this prediction, we speculate that mature dendritic cells disregard inter-cellular signals that could otherwise delay their arrival to lymph vessels.

preprint2019arXivOpen access
Elena AgliariPablo J. SáezAdriano BarraMatthieu PielPablo VargasMichele Castellana
Cell Behaviorcond-mat.stat-mechBiological Physics
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Elena AgliariPablo J. SáezAdriano BarraMatthieu PielPablo VargasMichele Castellana

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