Partial differential equation-based inference of migration and proliferation mechanisms in cancer cell populations
Targeting signaling pathways that drive cancer cell migration or proliferation is a common therapeutic approach. A popular experimental technique, the scratch assay, measures the migration and proliferation-driven cell monolayer formation. Scratch assay analyses do not differentiate between migration and proliferation effects and do not attempt to measure dynamic effects. To improve upon these methods, we combine high-throughput scratch assays, continuous video microscopy, and variational system identification (VSI) to infer partial differential equation (PDE) models of cell migration and proliferation. We capture the evolution of cell density fields over time using live cell microscopy and automated image processing. We employ VSI techniques to identify cell density dynamics modeled with first-order kinetics of advection-diffusion-reaction systems. We present a comparison of our methods to results obtained using traditional inference approaches on previously analyzed 1-dimensional scratch assay data. We demonstrate the application of this pipeline on high throughput 2-dimensional scratch assays and find that decreasing serum levels can decrease random cell migration by approximately 20%. Our integrated experimental and computational pipeline can be adapted for automatically quantifying the effect of biological perturbations on cell migration and proliferation in various cell lines.
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