2020
DOI: 10.1042/bst20190311
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Mathematical modelling in cell migration: tackling biochemistry in changing geometries

Abstract: Directed cell migration poses a rich set of theoretical challenges. Broadly, these are concerned with (1) how cells sense external signal gradients and adapt; (2) how actin polymerisation is localised to drive the leading cell edge and Myosin-II molecular motors retract the cell rear; and (3) how the combined action of cellular forces and cell adhesion results in cell shape changes and net migration. Reaction–diffusion models for biological pattern formation going back to Turing have long been used to explain … Show more

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Cited by 3 publications
(2 citation statements)
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“…In most studies on cell dynamics, experiments have been performed in wet labs. A few studies have presented mathematical models through applying partial differential equation to introduce cell migration, 1–3 presuppositions, and simulation methods for understanding cell dynamics; however, these studies have obtained divergent results 4–7 . Numerical studies help elucidate the fundamental mechanism of cell dynamics, which is essential for simulating cell dynamics in various conditions before wet lab testing 8,9 .…”
Section: Introductionmentioning
confidence: 99%
“…In most studies on cell dynamics, experiments have been performed in wet labs. A few studies have presented mathematical models through applying partial differential equation to introduce cell migration, 1–3 presuppositions, and simulation methods for understanding cell dynamics; however, these studies have obtained divergent results 4–7 . Numerical studies help elucidate the fundamental mechanism of cell dynamics, which is essential for simulating cell dynamics in various conditions before wet lab testing 8,9 .…”
Section: Introductionmentioning
confidence: 99%
“…Since cells often move in a spatially variable environment, the feedback from the ME can affect the mode of movement dynamically, and far more work is needed to understand how the cell-ME interaction controls the mode of movement. Significant progress has been made on simpler systems such as keratocytes moving on a flat surface [169], and recent techniques that can capture more dynamic shape changes in 3D via interface tracking shows promise [170], but much remains to be done. In the context of swimmers such as shown in Figure 3, a model in which protrusions propagate along the body length can replicate swimming speeds under various conditions [28], but how extension of protrusions is controlled by local fluid properties and other factors is not yet known.…”
mentioning
confidence: 99%