<i>Chlamydomonas</i>
            Swims with Two “Gears” in a Eukaryotic Version of Run-and-Tumble Locomotion

Polin, Marco; Tuval, Idán; Drescher, Knut; Gollub, Jerry P.; Goldstein, Raymond E.

doi:10.1126/science.1172667

Cited by 422 publications

(557 citation statements)

References 26 publications

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“…I close this section with a brief discussion of additional developments in the study of flagellar synchrony. The initial quantifications of noise in the beating of Chlamydomonas flagella Polin et al 2009) were not well resolved in time, but more recent precision studies ) have begun to reveal that there are important and largely unexplained systematics both within a beat period and on much larger time scales. For example, the noise amplitude peaks within a cycle during the transition between the power and recovery strokes.…”

Section: R E Goldsteinmentioning

confidence: 99%

“…Our initial investigations of this phenomenon Polin et al 2009) dynamics with greater spatio-temporal precision, but also to interpret the resulting time series of beating in the context of emerging models of synchrony. While it is now routine to extract detailed beating waveforms from videos of single cells, it was conceptually simpler first to implement a Poincaré section method to study…”

Section: Synchronisation Of Eukaryotic Flagellamentioning

confidence: 99%

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Batchelor Prize Lecture Fluid dynamics at the scale of the cell

Goldstein

2016

J. Fluid Mech.

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The world of cellular biology provides us with many fascinating fluid dynamical phenomena that lie at the heart of physiology, development, evolution and ecology. Advances in imaging, micromanipulation and microfluidics over the past decade have made possible high-precision measurements of such flows, providing tests of microhydrodynamic theories and revealing a wealth of new phenomena calling out for explanation. Here I summarize progress in four areas within the field of 'active matter': cytoplasmic streaming in plant cells, synchronization of eukaryotic flagella, interactions between swimming cells and surfaces and collective behaviour in suspensions of microswimmers. Throughout, I emphasize open problems in which fluid dynamical methods are key ingredients in an interdisciplinary approach to the mysteries of life.

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Section: R E Goldsteinmentioning

confidence: 99%

Section: Synchronisation Of Eukaryotic Flagellamentioning

confidence: 99%

Batchelor Prize Lecture Fluid dynamics at the scale of the cell

Goldstein

2016

J. Fluid Mech.

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“…A striking diversity in microbial single-cell behaviour has been observed [2,5,6]. Although cell-tracking provides valuable information, it is often slow and sometimes subject to biaslarge distributions of cell shapes or speeds might not be sampled properly because of faulty image recognition.…”

Section: Introductionmentioning

confidence: 99%

Fast, high-throughput measurement of collective behaviour in a bacterial population

Colin¹,

Zhang

Wilson³

2014

J. R. Soc. Interface.

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Swimming bacteria explore their environment by performing a random walk, which is biased in response to, for example, chemical stimuli, resulting in a collective drift of bacterial populations towards 'a better life'. This phenomenon, called chemotaxis, is one of the best known forms of collective behaviour in bacteria, crucial for bacterial survival and virulence. Both single-cell and macroscopic assays have investigated bacterial behaviours. However, theories that relate the two scales have previously been difficult to test directly. We present an image analysis method, inspired by light scattering, which measures the average collective motion of thousands of bacteria simultaneously. Using this method, a time-varying collective drift as small as 50 nm s 21 can be measured. The method, validated using simulations, was applied to chemotactic Escherichia coli bacteria in linear gradients of the attractant a-methylaspartate. This enabled us to test a coarse-grained minimal model of chemotaxis. Our results clearly map the onset of receptor methylation, and the transition from linear to logarithmic sensing in the bacterial response to an external chemoeffector. Our method is broadly applicable to problems involving the measurement of collective drift with high time resolution, such as cell migration and fluid flows measurements, and enables fast screening of tactic behaviours.

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“…For reasonably small values of parameters (say, ε ≃ 0.2 and δ ≃ 0.2) we have max E ∼ 0.1%, hence the efficiency of the micro-robots considered is low. In order to compare the velocities of micro-robots and micro-organisms we use the dimensional variables, in which max V * 0 ∼ ω * L * ε 2 δ; this shows that (for typical stroke frequency of self-swimming micro-organisms, which is about several Hz, see Pedley & Kessler 1987;Vladimirov et al 2004;Pedley 2009;Polin et al 2009) a micro-robot can move itself with the speed ∼10% of its own size per second. This estimation is 20-40 times lower than a similar value for natural micro-swimmers, see Vladimirov et al (2004); it again shows the low efficiency of the micro-robots considered.…”

Section: Examplesmentioning

confidence: 99%

“…The simplicity of the geometry represents the major advantage in studies of micro-robots (in contrast with the extreme complexity of self-swimming micro-organisms, e.g. Pedley & Kessler (1987), Vladimirov et al (2004), Pedley (2009) and Polin et al (2009)); it allows us to describe the motions of micro-robots in greater depth. In this paper, we generalize the theory of the three-sphere micro-robot of Najafi & Golestanian (2004) and Golestanian & Ajdari (2008) to an N-sphere micro-robot.…”

Section: Introductionmentioning

confidence: 99%

On the self-propulsion of an -sphere micro-robot

Vladimirov

2013

J. Fluid Mech.

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The aim of this paper is to describe the self-propulsion of a micro-robot (or microswimmer) consisting of N spheres moving along a fixed line. The spheres are linked to each other by arms with their lengths changing periodically. We use the asymptotic procedure containing the two-timing method and a distinguished limit. We show that self-propulsion velocity appears (in the main approximation) as a linear combination of velocities of all possible triplets of spheres. Velocities and efficiencies of three-, fourand five-sphere swimmers are calculated.

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Chlamydomonas Swims with Two “Gears” in a Eukaryotic Version of Run-and-Tumble Locomotion

Cited by 422 publications

References 26 publications

Batchelor Prize Lecture Fluid dynamics at the scale of the cell

Batchelor Prize Lecture Fluid dynamics at the scale of the cell

Fast, high-throughput measurement of collective behaviour in a bacterial population

On the self-propulsion of an -sphere micro-robot

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