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Hauptverfasser: Gao, David, Wang, Zeyuan, Jain, Mihika, Mathijssen, Arnold J T M, Tao, Ran
Format: Artículo científico
Sprache:en
Veröffentlicht: Integrative and comparative biology 2026
Schlagworte:
Online-Zugang:https://pubmed.ncbi.nlm.nih.gov/41955438/
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author Gao, David
Wang, Zeyuan
Jain, Mihika
Mathijssen, Arnold J T M
Tao, Ran
author_facet Gao, David
Wang, Zeyuan
Jain, Mihika
Mathijssen, Arnold J T M
Tao, Ran
Gao, David
Wang, Zeyuan
Jain, Mihika
Mathijssen, Arnold J T M
Tao, Ran
collection PubMed - marine biology
contents Selective Trapping of Bacteria in Porous Media by Cell Length. Gao, David Wang, Zeyuan Jain, Mihika Mathijssen, Arnold J T M Tao, Ran Escherichia coli Porosity Bacteria commonly inhabit porous environments such as host tissues, soil, and marine sediments, where complex geometries constrain and redirect their motion. Although bacterial motility has been studied in porous media, the roles of cell length and pore shape in navigating these environments remain poorly understood. Here, we investigate how cell morphology and pore architecture jointly determine bacterial spreading behavior. Using genetically engineered Escherichia coli with tunable cell length, we performed single-cell tracking in microfluidic devices that mimic ordered and disordered porous structures. We find that elongated bacteria traverse ordered pore networks more effectively than short cells, exhibiting straighter paths, greater directional persistence, and enhanced exploration efficiency. In contrast, in disordered porous media, elongated bacteria become trapped in dead-end regions for extended periods, resulting in markedly reduced navigational efficiency. Together, these results reveal how cell shape and environmental geometry interact to govern bacterial transport. Moreover, we suggest a new mechanism for separating antimicrobial-resistant bacteria from elongated susceptible cells in designer porous media.
format Artículo científico
id pubmed_41955438
institution PubMed
language en
publishDate 2026
publisher Integrative and comparative biology
record_format pubmed
spellingShingle Selective Trapping of Bacteria in Porous Media by Cell Length.
Gao, David
Wang, Zeyuan
Jain, Mihika
Mathijssen, Arnold J T M
Tao, Ran
Escherichia coli
Porosity
Selective Trapping of Bacteria in Porous Media by Cell Length. Gao, David Wang, Zeyuan Jain, Mihika Mathijssen, Arnold J T M Tao, Ran Escherichia coli Porosity Bacteria commonly inhabit porous environments such as host tissues, soil, and marine sediments, where complex geometries constrain and redirect their motion. Although bacterial motility has been studied in porous media, the roles of cell length and pore shape in navigating these environments remain poorly understood. Here, we investigate how cell morphology and pore architecture jointly determine bacterial spreading behavior. Using genetically engineered Escherichia coli with tunable cell length, we performed single-cell tracking in microfluidic devices that mimic ordered and disordered porous structures. We find that elongated bacteria traverse ordered pore networks more effectively than short cells, exhibiting straighter paths, greater directional persistence, and enhanced exploration efficiency. In contrast, in disordered porous media, elongated bacteria become trapped in dead-end regions for extended periods, resulting in markedly reduced navigational efficiency. Together, these results reveal how cell shape and environmental geometry interact to govern bacterial transport. Moreover, we suggest a new mechanism for separating antimicrobial-resistant bacteria from elongated susceptible cells in designer porous media.
title Selective Trapping of Bacteria in Porous Media by Cell Length.
topic Escherichia coli
Porosity
url https://pubmed.ncbi.nlm.nih.gov/41955438/