NUS researchers have developed a platform that lets lab-grown muscle tissues train themselves to record-breaking strength, ...

Researchers at the National University of Singapore have developed a new way to make lab-grown muscles stronger by letting them train themselves, removing a major limitation in biohybrid robotics. The ...

As one reader points out on the comments board of a related Design News article, combining living tissue with mechanical components sounds like Mary Shelley's Frankenstein story written almost 200 ...

Skeletal muscle mechanics and force generation are governed by complex interactions between contractile proteins and passive structural elements. At the cellular level, the sarcomere – the fundamental ...

Scientists have developed a specially formulated bioink, which contains microparticles engineered for sustained delivery of insulin-like growth factor-1 (IGF-1). This delivery enhances the formation ...

A research team from Xi'an Jiaotong University has developed a new method for bioprinting skeletal muscle tissue.

A research team led by Prof. Chen Yan and Prof. Yang Lifeng from the Shanghai Institute of Nutrition and Health of the Chinese Academy of Sciences revealed a physiological function of monocarboxylate ...

Scientists from Tokyo Metropolitan University have discovered that a protein called platelet-derived growth factor subunit B (PDGF-B) is continuously secreted from skeletal muscle cells and helps to ...

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 c ...