The stiffened artificial muscle can support up to 5 kilograms (11 pounds) — roughly “4,000 times its own weight.” The muscle ...

A research team affiliated with UNIST has unveiled a new type of artificial muscle that can seamlessly transition from soft ...

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 ...

The human body moves through a coordinated effort of skeletal muscles, working in concert to generate force. While some ...

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 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 ...

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 ...

(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 ...

The study, led by Dr. Cheng-Hui Li from the School of Chemistry and Chemical Engineering, Nanjing University, and Dr. Pengfei Zheng from the Children's Hospital of Nanjing Medical University, ...

According to its developers, this transition — much like rubber transforming into steel — occurs when the artificial muscle ...

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 ...