Activity-induced interactions and cooperation of artificial microswimmers in one-dimensional environments

Regardless of whether one considers swarming insects, flocking birds, or bacterial colonies, collective motion arises from the coordination of individuals and entails the adjustment of their respective velocities. In particular, in close confinement, such as those encountered by dense cell populations during development or regeneration, collective migration can only arise coordinately. Yet, how individuals unify their velocities is often not understood. Focusing on a finite number of cells in circular confinements, we identify waves of polymerizing actin that function as a pacemaker governing the speed of individual cells. We show that the onset of collective motion coincides with the synchronization of the wave nucleation frequencies across the population. Employing a simpler and more readily accessible mechanical model system of active spheres, we identify the essential requirements to reach the corresponding collective state, i.e. the synchronization of the individuals' internal oscillators. The mechanical 'toy' experiment illustrates that the global synchronous state is achieved by nearest neighbor coupling. We suggest by analogy that local coupling and the synchronization of actin waves are essential for emergent, self-organized motion of cell collectives.

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“…2b) . 1,26 Along the resulting circular trajectory of the motorized ball the speed oscillates (Supp. Fig.…”

Section: Resultsmentioning

confidence: 99%

Synchronization in collectively moving inanimate and living active matter

Riedl

Merrin

Sixt

et al. 2022

Preprint

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“…The trapping of active particles has been studied in experiments [13][14][15][16]21] and simulations [12,54], for bacteria [16,20] and spherical [12-14, 21, 54] and rodshaped [12,13,15] artificial microswimmers. The hydrodynamic trapping as reported in these studies is manifested in the orbit of the swimmers around round obstacles and along ridges above a critical relative curvature.…”

Section: Discussionmentioning

confidence: 99%

“…For example, by using pillars of various sizes, approaching bacteria could be scattered at a particular angle [18], or for larger pillars, trapped in an orbit [16,20]. Similar trapping has been observed in artificial swimmers [13,14,21], and by using more complex geometries, more exotic behaviors, such as directional trapping can be achieved [15].…”

Section: Introductionmentioning

confidence: 93%

A simple catch: thermal fluctuations enable hydrodynamic trapping of microrollers by obstacles

Wee¹,

Blackwell²,

Usabiaga³

et al. 2022

Preprint

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In order to leverage colloidal swimmers in microfluidic and drug-delivery applications, it is crucial to understand their interaction with obstacles. Previous studies have shown that this interaction can result in the hydrodynamic trapping in orbits around cylindrical obstacles, where the trapping strength heavily depends on the obstacle geometry and the flow field of the swimmer, and that Brownian motion is needed to escape the trap. Here, we use both experiments and simulations to investigate the interaction of driven microrollers with cylindrical obstacles. Microrollers have a unique flow field and a prescribed propulsion direction; the flow field that drives their motion is quite different than previously-studied swimmers. We observe curvature-dependent hydrodynamic trapping of these microrollers in the wake of an obstacle, and show explicitly the mechanism for this trapping. More interestingly, we find that these rollers need Brownian motion to both leave and enter the trap. By tuning both the obstacle curvature and the Debye length of the roller suspension, the trapping strength can be tuned over three orders of magnitude. Our findings suggest that the trapping of fluid-pumping swimmers is generic and encourages the study of swimmers with other flow fields and their interaction with obstacles.

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“…5b inset). Secondly, it is known that hydrodynamic interactions can increase the particle mobility even at low Reynolds numbers, as soon as two or APs are close by [39][40][41][42] . A further observation is the appearance of convection-like eddies in the bottleneck in the experiment (Fig.…”

Section: Simulationsmentioning

confidence: 99%

Role of cohesion in the flow of active particles through bottlenecks

Knippenberg

Lüders

Lozano

et al. 2022

Sci Rep

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We experimentally and numerically study the flow of programmable active particles (APs) with tunable cohesion strength through geometric constrictions. Similar to purely repulsive granular systems, we observe an exponential distribution of burst sizes and power-law-distributed clogging durations. Upon increasing cohesion between APs, we find a rather abrupt transition from an arch-dominated clogging regime to a cohesion-dominated regime where droplets form at the aperture of the bottleneck. In the arch-dominated regime the flow-rate only weakly depends on the cohesion strength. This suggests that cohesion must not necessarily decrease the group’s efficiency passing through geometric constrictions or pores. Such behavior is explained by “slippery” particle bonds which avoids the formation of a rigid particle network and thus prevents clogging. Overall, our results confirm the general applicability of the statistical framework of intermittent flow through bottlenecks developed for granular materials also in case of active microswimmers whose behavior is more complex than that of Brownian particles but which mimic the behavior of living systems.

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Activity-induced interactions and cooperation of artificial microswimmers in one-dimensional environments

Cited by 17 publications

References 60 publications

Synchronization in collectively moving inanimate and living active matter

Synchronization in collectively moving inanimate and living active matter

A simple catch: thermal fluctuations enable hydrodynamic trapping of microrollers by obstacles

Role of cohesion in the flow of active particles through bottlenecks

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