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Many types of bacteria swim by rotating a bundle of helical filaments also called flagella. Each filament is driven by a rotary motor and a very flexible hook transmits the motor torque to the filament. We model it by discretizing…

Biological Physics · Physics 2012-01-04 Reinhard Vogel , Holger Stark

Many bacteria are motile by means of one or more rotating rigid helical flagella, making them the only known organism to use rotation as a means of propulsion. The rotation is supplied by the bacterial flagellar motor, a particularly…

The twisting and writhing of a cell body and associated mechanical stresses is an underappreciated constraint on microbial self-propulsion. Multi-flagellated bacteria can even buckle and writhe under their own activity as they swim through…

Soft Condensed Matter · Physics 2023-09-25 Wilson Lough , Douglas B. Weibel , Saverio E. Spagnolie

Many species of bacteria swim through viscous environments by rotating multiple helical flagella. The filaments gather behind the cell body and form a close helical bundle, which propels the cell forward during a "run". The filaments inside…

Biological Physics · Physics 2020-05-22 Maria Tătulea-Codrean , Eric Lauga

We study a synthetic system of motile Escherichia coli bacteria encapsulated inside giant lipid vesicles. Forces exerted by the bacteria on the inner side of the membrane are sufficient to extrude membrane tubes filled with one or several…

Trajectories and conformations of uni- and multiflagellar bacteria are studied with a coarse-grained model of a cell comprised of elastic flagella connected to a cell body. The elasticities of both the hook protein (connecting cell body and…

Biological Physics · Physics 2018-11-07 Frank T. M. Nguyen , Michael D. Graham

Flagellar-driven locomotion plays a critical role in bacterial attachment and colonization of surfaces, contributing to the risks of contamination and infection. Tremendous attempts to uncover the underlying principles governing bacterial…

Soft Condensed Matter · Physics 2025-02-19 Xin-Xin Xu , Yangguang Tian , Yuhe Pu , Bingchen Che , Hao Luo , Yanan Liu , Yan-Jun Liu , Guangyin Jing

In this paper, we analyze the inverse dynamics and control of a bacteria-inspired uniflagellar robot in a fluid medium at low Reynolds number. Inspired by the mechanism behind the locomotion of flagellated bacteria, we consider a robot…

Robotics · Computer Science 2020-12-22 Mojtaba Forghani , Weicheng Huang , M. Khalid Jawed

Eukaryotic flagella are active structures with a complex architecture of microtubules, motor proteins and elastic links. They are capable of whiplike motions driven by motors sliding along filaments that are themselves constrained at an…

Soft Condensed Matter · Physics 2012-11-22 Raghunath Chelakkot , Arvind Gopinath , L. Mahadevan , Michael F. Hagan

Numerous studies have explored the link between bacterial swimming and the number of flagella, a distinguishing feature of motile multiflagellated bacteria. We revisit this open question using augmented slender-body theory simulations, in…

Biological Physics · Physics 2024-09-04 Maria Tătulea-Codrean , Eric Lauga

Motility is fundamental to the survival and proliferation of microorganisms. The E. coli bacterium propels itself using a bundle of rotating helical flagella. If one flagellum reverses its rotational direction, it leaves the bundle,…

Soft Condensed Matter · Physics 2025-04-30 Pierre Martin , Tapan Chandra Adhyapak , Holger Stark

Single flagellated bacteria are ubiquitous in nature. They exhibit various swimming modes using their flagella to explore complex surroundings such as soil and porous polymer networks. Some single-flagellated bacteria swim with two distinct…

Soft Condensed Matter · Physics 2024-11-20 H. Gidituri , M. Ellero , F. Balboa Usabiaga

Recent experiments proposed to use confined bacteria in order to generate flows near surfaces. We develop a mathematical and a computational model of this fluid transport using a linear superposition of fundamental flow singularities. The…

Biological Physics · Physics 2018-02-27 Justas Dauparas , Debasish Das , Eric Lauga

Peritrichous bacteria swim in viscous fluids by rotating multiple helical flagellar filaments. As the bacterium swims forward, all its flagella rotate in synchrony behind the cell in a helical bundle. When the bacterium changes its…

Fluid Dynamics · Physics 2017-11-16 Yi Man , William Page , Robert J. Poole , Eric Lauga

Peritrichously-flagellated bacteria, such as Escherichia coli, self-propel in fluids by using specialised motors to rotate multiple helical filaments. The rotation of each motor is transmitted to a short flexible segment called the hook…

Biological Physics · Physics 2018-06-07 Emily E. Riley , Debasish Das , Eric Lauga

The accumulation of swimming bacteria near surfaces may lead to biological processes such as biofilm formation and wound infection. Previous experimental observations of Vibrio alginolyticus showed an interesting correlation between the…

Biological Physics · Physics 2023-07-04 Vahid Nourian , Henry Shum

A flagellated bacterium navigates fluid environments by rotating its helical flagellar bundle. The wobbling of the bacterial body significantly influences its swimming behavior. To quantify the three underlying motions--precession,…

Soft Condensed Matter · Physics 2026-05-29 Jinglei Hu , Chen Gui , Mingxin Mao , Pu Feng , Yurui Liu , Xiangjun Gong , Gerhard Gompper

The bacterial flagellar motor is a highly efficient rotary machine used by many bacteria to propel themselves. It has recently been shown that at low speeds its rotation proceeds in steps [Sowa et al. (2005) Nature 437, 916--919]. Here we…

Biological Physics · Physics 2009-10-25 Thierry Mora , Howard Yu , Yoshiyuki Sowa , Ned S. Wingreen

The course of a peritrichous bacterium such as E. coli crucially depends on the level of synchronization and self-organization of several rotating flagella. However, the rotation of each flagellum generates counter body movements which in…

Biological Physics · Physics 2015-11-11 Tapan Chandra Adhyapak , Holger Stark

To survive in harsh conditions, motile bacteria swim in complex environment and respond to the surrounding flow. Here we develop a PDE model describing how the flagella bending affects macroscopic properties of bacterial suspensions. First,…

Analysis of PDEs · Mathematics 2016-10-11 Mykhailo Potomkin , Magali Tournus , Leonid Berlyand , Igor Aranson
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