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A forward-engineered, muscle-driven soft robotic swimmer

William Cartwright Drennan, Onur Aydin, Bashar Emon, Zhengwei Li, Md Saddam Hossain Joy, Alexandra Barishman, Yelim Kim, Margaret Wei, Dina L. Denham, Annika Carrillo, M. Taher A. Saif

2025Science Advances7 citationsDOIOpen Access PDF

Abstract

The field of biohybrid robotics focuses on using biological actuators to study the emergent properties of tissues and the locomotion of living organisms. On the basis of models of swimming at small size scales, we designed and fabricated a muscle-powered, flagellate swimmer. We investigate the design of a compliant mechanism based on nonlinear mechanics and its mechanical integration with a muscle ring and motor neurons. We find that within a range of anchor stiffnesses around 1 micronewton per micrometer, the homeostatic tension in muscle is insensitive to stiffness, offering greater design flexibility. The proximity of motor neurons results in a fourfold improvement in muscle contractility. Improved contractility and nonlinear design allow for a peak swimming speed about two orders of magnitude higher than previous biohybrid flagellate swimmers, reaching 0.58 body lengths per minute (86.8 micrometers per second), by a mechanism involving inertia that we verify through flow field imaging. This swimmer opens the door for a class of intermediate-Reynolds number swimmers.

Topics & Concepts

Reynolds numberFlexibility (engineering)StiffnessInertiaContractilityArtificial muscleSoft roboticsMechanism (biology)MechanicsActuatorComputer scienceMaterials sciencePhysicsBiologyArtificial intelligenceTurbulenceMathematicsClassical mechanicsQuantum mechanicsStatisticsEndocrinologyComposite materialMicro and Nano RoboticsCellular Mechanics and InteractionsSoft Robotics and Applications
A forward-engineered, muscle-driven soft robotic swimmer | Litcius