AI Article Synopsis
- Collective migration of eukaryotic cells is guided by chemotaxis and plays a crucial role in processes like cancer spread, wound healing, and embryonic development.
- Understanding collective chemotaxis is complex due to cells’ ability to detect tiny gradients of chemoattractants, influenced by their interactions and distribution dynamics.
- The authors introduce a new computational method called Dynamic Cluster Field modeling (DCF) that enables large-scale simulations of cell migration and chemoattractant dynamics, demonstrating its effectiveness against experimental results in various scenarios.
Article Abstract
Collective migration of eukaryotic cells is often guided by chemotaxis, and is critical in several biological processes, such as cancer metastasis, wound healing, and embryogenesis. Understanding collective chemotaxis has challenged experimental, theoretical and computational scientists because cells can sense very small chemoattractant gradients that are tightly controlled by cell-cell interactions and the regulation of the chemoattractant distribution by the cells. Computational models of collective cell migration that offer a high-fidelity resolution of the cell motion and chemoattractant dynamics in the extracellular space have been limited to a small number of cells. Here, we present Dynamic cluster field modeling (DCF), a novel computational method that enables simulations of collective chemotaxis of cellular systems with cells and high-resolution transport dynamics of the chemoattractant in the time-evolving extracellular space. We illustrate the efficiency and predictive capabilities of our approach by comparing our numerical simulations with experiments in multiple scenarios that involve chemoattractant secretion and uptake by the migrating cells, cell migration in confined spaces, regulation of the attractant distribution by cell motion, and interactions of the chemoattractant with an enzyme. The proposed algorithm opens new opportunities to address outstanding problems that involve collective cell migration in the central nervous system, immune response and cancer metastasis.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11502788 | PMC |
| http://dx.doi.org/10.1038/s41598-024-75653-1 | DOI Listing |
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