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Hauptverfasser: Bai, Yang, He, Caiyun, Liu, Weirong, Cheng, Songtao, Chu, Pan, Luo, Liang, Liu, Chenli, Fu, Xiongfei
Format: Preprint
Veröffentlicht: 2025
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2510.12106
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author Bai, Yang
He, Caiyun
Liu, Weirong
Cheng, Songtao
Chu, Pan
Luo, Liang
Liu, Chenli
Fu, Xiongfei
author_facet Bai, Yang
He, Caiyun
Liu, Weirong
Cheng, Songtao
Chu, Pan
Luo, Liang
Liu, Chenli
Fu, Xiongfei
contents Active navigation in disordered media depends on a biased random walk interacting with environmental constraints. Using E. coli chemotactic navigation in agar gels as a model system, we reveal a fundamental trade-off between diffusive exploration and chemotactic directional bias that dictates the optimal strategy for population range expansion. Counter-intuitively, evolution selects for shorter mean run times (τ_f) to achieve faster chemotactic migration in denser environments. Controlled experiments reveal a non-monotonic relationship between chemotactic navigation speed and τ_f, with the optimum shifting according to the density of physical traps in the gel. Single-cell analysis demonstrates that escape from these traps occurs independently of the tumbling mechanism, challenging the classical view that reorientation is essential for navigation in obstructed spaces. Based on these insights, we develop a minimal theoretical model showing that the optimal τ_f emerges from an antagonistic scaling: while the diffusion coefficient increases with τ_f, the chemotactic bias coefficient decreases with it. This work establishes a general principle for optimizing active transport through complex, disordered environments.
format Preprint
id arxiv_https___arxiv_org_abs_2510_12106
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Optimal chemotactic navigation in disordered landscapes
Bai, Yang
He, Caiyun
Liu, Weirong
Cheng, Songtao
Chu, Pan
Luo, Liang
Liu, Chenli
Fu, Xiongfei
Soft Condensed Matter
Active navigation in disordered media depends on a biased random walk interacting with environmental constraints. Using E. coli chemotactic navigation in agar gels as a model system, we reveal a fundamental trade-off between diffusive exploration and chemotactic directional bias that dictates the optimal strategy for population range expansion. Counter-intuitively, evolution selects for shorter mean run times (τ_f) to achieve faster chemotactic migration in denser environments. Controlled experiments reveal a non-monotonic relationship between chemotactic navigation speed and τ_f, with the optimum shifting according to the density of physical traps in the gel. Single-cell analysis demonstrates that escape from these traps occurs independently of the tumbling mechanism, challenging the classical view that reorientation is essential for navigation in obstructed spaces. Based on these insights, we develop a minimal theoretical model showing that the optimal τ_f emerges from an antagonistic scaling: while the diffusion coefficient increases with τ_f, the chemotactic bias coefficient decreases with it. This work establishes a general principle for optimizing active transport through complex, disordered environments.
title Optimal chemotactic navigation in disordered landscapes
topic Soft Condensed Matter
url https://arxiv.org/abs/2510.12106