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Leveraging microtopography to pattern multi-oriented muscle actuators

Tamara Rossy, Laura Schwendeman, Sonika Kohli, Maheera Bawa, Pavankumar Umashankar, Roi Habba, Oren Tchaicheeyan, Ayelet Lesman, Ritu Raman

2025Biomaterials Science15 citationsDOIOpen Access PDF

Abstract

micro-topographical patterning), an easily accessible and cost-effective one-step method to pattern microtopography of various sizes and configurations on the surface of hydrogels using reusable 3D printed stamps. We demonstrate that STAMP enables precisely controlling the alignment of mouse and human skeletal muscle fibers without negatively impacting their maturation or function. To showcase the versatility of our technique, we designed a planar soft robot inspired by the iris, which leverages spatially segregated regions of concentric and radial muscle fibers to control pupil dilation. Optogenetic skeletal muscle fibers grown on a STAMPed iris substrates formed a multi-oriented actuator, and selective light stimulation of the radial and concentric fibers was used to control the function of the iris, including pupil constriction. Computational modeling of the biohybrid robot as an active bilayer matched experimental outcomes, showcasing the robustness of our STAMP method for designing, fabricating, and testing planar biohybrid robots capable of complex multi-DOF motion.

Topics & Concepts

ActuatorFabricationComputer scienceNanotechnologyIRIS (biosensor)Simple (philosophy)Materials scienceArtificial intelligenceBiometricsMedicinePathologyPhilosophyEpistemologyAlternative medicine3D Printing in Biomedical ResearchCellular Mechanics and InteractionsCell Image Analysis Techniques