(Nanowerk News) We move thanks to coordination among many skeletal muscle fibers, all twitching and pulling in sync. While some muscles align in one direction, others form intricate patterns, helping ...

It has been a long endeavor to create biohybrid robots – machines powered by lab-grown muscle as potential actuators. The flexibility of biohybrid robots could allow them to squeeze and twist through ...

Researchers have engineered a material that is as soft as skin but remarkably strong. Ulsan National Institute of Science & Technology (UNIST) team in South Korea has developed an innovative magnetic ...

Demonstrating 3 times greater actuation stroke and 2 times higher work capacity than existing photochemical actuators, the new light-responsive springs outperform mammalian muscles and enable ...

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 ...

We move thanks to coordination among many skeletal muscle fibers, all twitching and pulling in sync. While some muscles align in one direction, others form intricate patterns, helping parts of the ...

(A) A summary plot illustrating the elastic modulus range of the artificial muscle compared to representative biological tissues, highlighting the biomimetic mechanical properties of the artificial ...

Engineers at MIT have devised an ingenious new way to produce artificial muscles for soft robots that can flex in more than one direction, similar to the complex muscles in the human body. The team ...

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 study published in the journal National Science Review, scientists from Nanjing University and Nanjing Medical University successfully created an artificial muscle with mechanical ...