Geometrical Constraints on the Tangling of Bacterial Flagellar Filaments

Tătulea-Codrean, Maria; Lauga, Eric

doi:10.1038/s41598-020-64974-6

Cited by 6 publications

(4 citation statements)

References 46 publications

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“…To fully understand the physics behind bacterial locomotion, the phenomenon such as synchronization and tangling of the bacterial flagella are being investigated. [14][15][16] Besides its complexity in physics, the multi-flagellated mechanism is vital from both robotic and biological perspectives due to the following features: (1) directional stability, 2 (2) redundancy of actuation, 17 (3) chemical secretion using flagella, 18,19 (4) improved efficiency in the swarm and propagation. 20,21 Compared to the multi-flagellated mechanism, locomotion used by bacteria with a single flagellum lacks interaction with one or more flagella, exploiting a similar yet different mechanism.…”

Section: Introductionmentioning

confidence: 99%

Bacteria-inspired robotic propulsion from bundling of soft helical filaments at low Reynolds number

2023

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Section: Introductionmentioning

confidence: 99%

Bacteria-inspired robotic propulsion from bundling of soft helical filaments at low Reynolds number

2023

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“…Interactions of long, thin, inextensible filaments with a viscous fluid abound in biology, engineering, physics, and medicine. In biology, the swimming mechanisms of flagellated organisms have been of interest for decades, with an initial cluster of studies on how force and torque balances lead to swimming [14,9,12,42], and a more recent focus on flagellar bundling and propulsion [46,52,54]. In physics and engineering, suspensions of high-aspect-ratio fibers have been observed to display non-Newtonian, viscoelastic behavior both experimentally [10] and computationally [51,76].…”

Section: Introductionmentioning

confidence: 99%

An integral-based spectral method for inextensible slender fibers in Stokes flow

Maxian,

Mogilner,

Donev

2020

Preprint

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Every animal cell is filled with a cytoskeleton, a dynamic gel made of inextensible fibers, such as microtubules, actin fibers, and intermediate filaments, all suspended in a viscous fluid. Numerical simulation of this gel is challenging because the fiber aspect ratios can be as large as 10 4 .We describe a new method for rapidly computing the dynamics of inextensible slender filaments in periodically-sheared Stokes flow. The dynamics of the filaments are governed by a nonlocal slender body theory which we partially reformulate in terms of the Rotne-Prager-Yamakawa hydrodynamic tensor. To enforce inextensibility, we parameterize the space of inextensible fiber motions and strictly confine the dynamics to the manifold of inextensible configurations. To do this, we introduce a set of Lagrange multipliers for the tensile force densities on the filaments and impose the constraint of no virtual work in an L 2 weak sense. We augment this approach with a spectral discretization of the local and nonlocal slender body theory operators which is linear in the number of unknowns and gives improved spatial accuracy over approaches based on solving a line tension equation. For dynamics, we develop a second-order semi-implicit temporal integrator which requires at most a few evaluations of nonlocal hydrodynamics and a few block diagonal linear solves per time step. After demonstrating the improved accuracy and robustness

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“…Moreover, because the flagellar filaments and especially the hook are flexible, and the interaction between these slender elastic structures, the cell body and the fluid lead to non-linearities that are difficult to compute [27]. Despite these challenges, the dynamics of bundling and unbundling have been the subject of numerous theoretical [28][29][30][31], numerical [32][33][34][35][36][37][38][39][40][41][42][43] and experimental [6,13,16,[44][45][46][47][48][49] studies. Early studies examined the dynamics of filaments without taking into account the cell body [28, 29, 32-35, 39, 45], or ignored elastic effects [43].…”

Section: Introductionmentioning

confidence: 99%

“…With advances in computational power and the sophistication of numerical methods [50][51][52], more recent work has been able to accurately simulate the swimming dynamics of multi-flagellated motile bacteria [36,38,40]. Some studies also focus on a particular aspect of the problem, such as flagellar polymorphism [41] or the geometrical constraints of entanglement [31].…”

Section: Introductionmentioning

confidence: 99%

Direct vs indirect hydrodynamic interactions during bundle formation of bacterial flagella

Chamolly,

Lauga

2020

Preprint

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Most motile bacteria swim in viscous fluids by rotating multiple helical flagellar filaments. These semi-rigid filaments repeatedly join ('bundle') and separate ('unbundle'), resulting in a two-gait random walk-like motion of the cell. In this process, hydrodynamic interactions between the filaments are known to play an important role and can be categorised into two distinct types: direct interactions mediated through flows that are generated through the actuation of the filaments themselves, and indirect interactions mediated through the motion of the cell body (i.e. flows induced in the swimming frame that result from propulsion). To understand the relative importance of these two types of interactions, we study a minimal singularity model of flagellar bundling. Using hydrodynamic images, we solve for the flow analytically and compute both direct and indirect interactions exactly as a function of the length of the flagellar filaments and their angular separation.We show (i) that the generation of thrust by flagella alone is sufficient to drive the system towards a bundled state through both types of interaction in the entire geometric parameter range; (ii) that for both thrust-and rotation-induced flows indirect advection dominates for long filaments and at wide separation, i.e. primarily during the early stages of the bundling process; and (iii) that, in contrast, direct interactions dominate when flagellar filaments are in each other's wake, which we characterise mathematically. We further introduce a numerical elastohydrodynamic model that allows us to compute the dynamics of the helical axes of each flagellar filament while analysing direct and indirect interactions separately. With this we show (iv) that the shift in balance between direct and indirect interactions is non-monotonic during the bundling process, with a peak in direct dominance, and that different sections of the flagella are affected by these changes to different extents.

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Geometrical Constraints on the Tangling of Bacterial Flagellar Filaments

Cited by 6 publications

References 46 publications

Bacteria-inspired robotic propulsion from bundling of soft helical filaments at low Reynolds number

Bacteria-inspired robotic propulsion from bundling of soft helical filaments at low Reynolds number

An integral-based spectral method for inextensible slender fibers in Stokes flow

Direct vs indirect hydrodynamic interactions during bundle formation of bacterial flagella

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