Soft Biological Actuators for Meter-Scale Homeostatic Biohybrid Robots

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Abstract

Skeletal muscle’s elegant protein-based architecture powers motion throughout the animal kingdom, with its constituent actomyosin complexes driving intra- and extra-cellular motion. Classical motors and recently developed soft actuators cannot match the packing density and contractility of individual muscle fibers that scale to power the motion of ants and elephants alike. Accordingly, the interdisciplinary fields of robotics and tissue engineering have combined efforts to build living muscle actuators that can power a new class of robots to be more energy-efficient, dexterous, and safe than existing motor-powered and hydraulic paradigms. Doing so ethically and at scale─creating meter-scale tissue constructs from sustainable muscle progenitor cell lines─has inspired innovations in biomaterials and tissue culture methodology. We weave discussions of muscle cell biology, materials chemistry, tissue engineering, and biohybrid design to review the state of the art in soft actuator biofabrication. Looking forward, we outline a vision for meter-scale biohybrid robotic systems and tie discussions of recent progress to long-term research goals.

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Heisser, R. H., Bawa, M., Shah, J., Bu, A., & Raman, R. (2025, April 9). Soft Biological Actuators for Meter-Scale Homeostatic Biohybrid Robots. Chemical Reviews. American Chemical Society. https://doi.org/10.1021/acs.chemrev.4c00785

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