Data-driven Discovery of Chemotactic Migration of Bacteria Via Coordinate-invariant Machine Learning

Overview

Journal BMC Bioinformatics

Publisher Biomed Central

Specialty Biology

Date 2024 Oct 25

PMID 39448929

Authors

Yorgos M Psarellis

Seungjoon Lee

Tapomoy Bhattacharjee

Sujit S Datta

Juan M Bello-Rivas

Ioannis G Kevrekidis

Affiliations

Soon will be listed here.

Abstract

Background: E. coli chemotactic motion in the presence of a chemonutrient field can be studied using wet laboratory experiments or macroscale-level partial differential equations (PDEs) (among others). Bridging experimental measurements and chemotactic Partial Differential Equations requires knowledge of the evolution of all underlying fields, initial and boundary conditions, and often necessitates strong assumptions. In this work, we propose machine learning approaches, along with ideas from the Whitney and Takens embedding theorems, to circumvent these challenges.

Results: Machine learning approaches for identifying underlying PDEs were (a) validated through the use of simulation data from established continuum models and (b) used to infer chemotactic PDEs from experimental data. Such data-driven models were surrogates either for the entire chemotactic PDE right-hand-side (black box models), or, in a more targeted fashion, just for the chemotactic term (gray box models). Furthermore, it was demonstrated that a short history of bacterial density may compensate for the missing measurements of the field of chemonutrient concentration. In fact, given reasonable conditions, such a short history of bacterial density measurements could even be used to infer chemonutrient concentration.

Conclusion: Data-driven PDEs are an important modeling tool when studying Chemotaxis at the macroscale, as they can learn bacterial motility from various data sources, fidelities (here, computational models, experiments) or coordinate systems. The resulting data-driven PDEs can then be simulated to reproduce/predict computational or experimental bacterial density profile data independent of the coordinate system, approximate meaningful parameters or functional terms, and even possibly estimate the underlying (unmeasured) chemonutrient field evolution.

Citing Articles

From disorganized data to emergent dynamic models: Questionnaires to partial differential equations.

Sroczynski D, Kemeth F, Georgiou A, Coifman R, Kevrekidis I PNAS Nexus. 2025; 4(2):pgaf018.

PMID: 39898180 PMC: 11786195. DOI: 10.1093/pnasnexus/pgaf018.

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