# Controlling Organization and Forces in Active Matter Through   Optically-Defined Boundaries

**Authors:** Tyler D. Ross, Heun Jin Lee, Zijie Qu, Rachel A. Banks, Rob Phillips,, Matt Thomson

arXiv: 1812.09418 · 2019-08-28

## TL;DR

This paper demonstrates optical control of active biomolecular structures and fluid flows in engineered systems, enabling programmable manipulation of non-equilibrium phenomena with potential applications in studying cellular mechanics and designing active matter devices.

## Contribution

It introduces a method to optically define boundaries and control structures in active matter, allowing precise spatiotemporal manipulation of microtubule networks and flows.

## Key findings

- Microtubule structures can be created, moved, and merged using light patterns.
- Contractile microtubule networks can span hundreds of microns and move faster than individual motors.
- Generated fluid flows can be sculpted and controlled through boundary manipulation.

## Abstract

Living systems are capable of locomotion, reconfiguration, and replication. To perform these tasks, cells spatiotemporally coordinate the interactions of force-generating, "active" molecules that create and manipulate non-equilibrium structures and force fields that span up to millimeter length scales [1-3]. Experimental active matter systems of biological or synthetic molecules are capable of spontaneously organizing into structures [4,5] and generating global flows [6-9]. However, these experimental systems lack the spatiotemporal control found in cells, limiting their utility for studying non-equilibrium phenomena and bioinspired engineering. Here, we uncover non-equilibrium phenomena and principles by optically controlling structures and fluid flow in an engineered system of active biomolecules. Our engineered system consists of purified microtubules and light-activatable motor proteins that crosslink and organize microtubules into distinct structures upon illumination. We develop basic operations, defined as sets of light patterns, to create, move, and merge microtubule structures. By composing these basic operations, we are able to create microtubule networks that span several hundred microns in length and contract at speeds up to an order of magnitude faster than the speed of an individual motor. We manipulate these contractile networks to generate and sculpt persistent fluid flows. The principles of boundary-mediated control we uncover may be used to study emergent cellular structures and forces and to develop programmable active matter devices.

## Full text

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## Figures

29 figures with captions in the complete paper: https://tomesphere.com/paper/1812.09418/full.md

## References

49 references — full list in the complete paper: https://tomesphere.com/paper/1812.09418/full.md

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Source: https://tomesphere.com/paper/1812.09418