Jacob Knight, Paula García-Galindo, Johannes Pausch, Gunnar Pruessner
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A wide array of biological systems can navigate in shallow gradients of
chemoattractant with remarkable precision. Whilst previous approaches model
such systems using coarse-grained chemical density profiles, we construct a
dynamical model consisting of a chemotactic cell responding to discrete cue
particles. For a cell without internal memory, we derive an effective velocity
with which the cell approaches a point source of cue particles. We find that
the effective velocity becomes negative beyond some homing radius, which
represents an upper bound on the distance within which chemotaxis can be
reliably performed. This work lays the foundation for the analytical
characterisation of more detailed models of chemotaxis.
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