Biological muscles act as flexible actuators, generating force naturally and with an impressive range of motion. Unsurprisingly, scientists and engineers have been striving to build artificial muscles ...

Researchers created tough hydrogel artificial tendons, attached them to lab-grown muscle to form a muscle-tendon unit, then linked the tendons to a robotic gripper's fingers. (Nanowerk News) Our ...

MIT engineers grew an artificial, muscle-powered structure that pulls both concentrically and radially, much like how the iris in the human eye acts to dilate and constrict the pupil. We move thanks ...

Researchers have made groundbreaking advancements in bionics with the development of a new electric variable-stiffness artificial muscle. This innovative technology possesses self-sensing capabilities ...

(Nanowerk Spotlight) Artificial muscles hold the promise of revolutionizing fields ranging from robotics and prosthetics to biomedical devices. These lightweight, flexible materials can mimic the ...

Most robots rely on rigid, bulky parts that limit their adaptability, strength, and safety in real-world environments. Researchers developed soft, battery-powered artificial muscles inspired by human ...

In a recent article published in Gels, researchers from China developed multilayer porous plasticized polyvinyl chloride (PVC) gel artificial muscles using carbon nanotube-doped 3D-printed silicone ...

That’s not a vanity statement for those who want to look good or a performance issue for those who want to be better, stronger, and faster. It’s a medical issue and has been for a long time. And if ...

Our muscles are nature’s actuators. The sinewy tissue is what generates the forces that make our bodies move. In recent years, engineers have used real muscle tissue to actuate “biohybrid robots” made ...