Fish muscle signals can reveal movement, sense water flow & improve robot swimming, offering a way to design smarter ...

Researchers at the Intelligent Biomimetic Design Lab at Peking University have developed a bio-signal framework showing that fish muscles do far more than generate swimming motion. In a series of ...

NUS researchers have developed a platform that lets lab-grown muscle tissues train themselves to record-breaking strength, with no external stimulation required. By mechanically coupling two muscle ...

The latest viral clip of a faceless android twitching under its own power has pushed humanoid robotics into a new, unsettling register. Instead of a metal frame in a lab, viewers are watching ...

Scientists have developed a self-training method that strengthens lab-grown muscle tissues around the clock, and used them to power a living-muscle robot that swims faster than any of its predecessors ...

Engineers have long tried to build artificial muscles that work like the ones in the human body—strong, flexible, fast, and ...

Breaking away from conventional robots that perform only predefined functions once fabricated, researchers have developed a ...

(A) A user wears the EMG-driven EVF-robot. (B) The application on a smartphone serving as a user interface. (C) The pneumatic fingers embedded in an elastic textile glove. The electro-vibro-feedback ...

A new artificial muscle can change shape, repair damage, and be reused, bringing a major shift in how robots are built and ...

Assistant Professor Tan Yu Jun (right), PhD student Mr Zhou Jinrun (left), and their team from the National University of Singapore established a simple but ingenious method that produced lab-grown ...

NUS scientists have developed a self-training method that strengthens lab-grown muscle tissues around the clock, and used them to power a living-muscle robot that swims faster than any of its ...