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Main Authors: Cornejo-Olea, Gustavo, Buvinic, Lucas, Darbon, Jerome, Erban, Radek, Ravasio, Andrea, Matzavinos, Anastasios
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.18745
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author Cornejo-Olea, Gustavo
Buvinic, Lucas
Darbon, Jerome
Erban, Radek
Ravasio, Andrea
Matzavinos, Anastasios
author_facet Cornejo-Olea, Gustavo
Buvinic, Lucas
Darbon, Jerome
Erban, Radek
Ravasio, Andrea
Matzavinos, Anastasios
contents Cell migration often exhibits long-range temporal correlations and anomalous diffusion, even in the absence of external guidance cues such as chemical gradients or topographical constraints. These observations raise a fundamental question: do such correlations simply reflect internal cellular processes, or do they enhance a cell's ability to navigate complex environments? In this work, we explore how temporally correlated noise (modeled using fractional Brownian motion) influences chemotactic search dynamics. Through computational experiments, we show that superdiffusive motion, when combined with gradient-driven migration, enables robust exploration of the chemoattractant landscape. Cells reliably reach the global maximum of the concentration field, even in the presence of spatial noise, secondary cues, or irregular signal geometry. We quantify this behavior by analyzing the distribution of first hitting times under varying degrees of temporal correlation. Notably, our results are consistent across diverse conditions, including flat and curved substrates, and scenarios involving both primary and self-generated chemotactic signals. Beyond biological implications, these findings also offer insight into the design of optimization and sampling algorithms that benefit from structured stochasticity.
format Preprint
id arxiv_https___arxiv_org_abs_2511_18745
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle On the role of fractional Brownian motion in models of chemotaxis and stochastic gradient ascent
Cornejo-Olea, Gustavo
Buvinic, Lucas
Darbon, Jerome
Erban, Radek
Ravasio, Andrea
Matzavinos, Anastasios
Quantitative Methods
Computational Engineering, Finance, and Science
Applications
92C08, 92C10, 62P08
Cell migration often exhibits long-range temporal correlations and anomalous diffusion, even in the absence of external guidance cues such as chemical gradients or topographical constraints. These observations raise a fundamental question: do such correlations simply reflect internal cellular processes, or do they enhance a cell's ability to navigate complex environments? In this work, we explore how temporally correlated noise (modeled using fractional Brownian motion) influences chemotactic search dynamics. Through computational experiments, we show that superdiffusive motion, when combined with gradient-driven migration, enables robust exploration of the chemoattractant landscape. Cells reliably reach the global maximum of the concentration field, even in the presence of spatial noise, secondary cues, or irregular signal geometry. We quantify this behavior by analyzing the distribution of first hitting times under varying degrees of temporal correlation. Notably, our results are consistent across diverse conditions, including flat and curved substrates, and scenarios involving both primary and self-generated chemotactic signals. Beyond biological implications, these findings also offer insight into the design of optimization and sampling algorithms that benefit from structured stochasticity.
title On the role of fractional Brownian motion in models of chemotaxis and stochastic gradient ascent
topic Quantitative Methods
Computational Engineering, Finance, and Science
Applications
92C08, 92C10, 62P08
url https://arxiv.org/abs/2511.18745