Litcius/Paper detail

A cellular platform for the development of synthetic living machines

Douglas Blackiston, Emma K. Lederer, Sam Kriegman, Simon Garnier, Joshua Bongard, Michael Levin

2021Science Robotics186 citationsDOI

Abstract

) cells. These xenobots exhibit coordinated locomotion via cilia present on their surface. These cilia arise through normal tissue patterning and do not require complicated construction methods or genomic editing, making production amenable to high-throughput projects. The biological robots arise by cellular self-organization and do not require scaffolds or microprinting; the amphibian cells are highly amenable to surgical, genetic, chemical, and optical stimulation during the self-assembly process. We show that the xenobots can navigate aqueous environments in diverse ways, heal after damage, and show emergent group behaviors. We constructed a computational model to predict useful collective behaviors that can be elicited from a xenobot swarm. In addition, we provide proof of principle for a writable molecular memory using a photoconvertible protein that can record exposure to a specific wavelength of light. Together, these results introduce a platform that can be used to study many aspects of self-assembly, swarm behavior, and synthetic bioengineering, as well as provide versatile, soft-body living machines for numerous practical applications in biomedicine and the environment.

Topics & Concepts

Swarm behaviourComputer scienceProcess (computing)Living systemsCellular automatonSynthetic biologyNanotechnologyBiomimeticsArtificial intelligenceRobotHuman–computer interactionDistributed computingBiologyBioinformaticsMaterials scienceOperating systemMicro and Nano RoboticsModular Robots and Swarm IntelligenceMolecular Communication and Nanonetworks