Our muscles are amazing structures. With the trigger of a thought, muscle filaments slide past each other and bundles of contracting fibers pull on the bones moving our bodies. The triggered stretching behavior of muscle is inherently based in geometry, characterized by a decrease in length and increase in volume (or vice versa) in response to a change in the local environment, such as humidity or heat.
Variations of this dynamic geometry appear elsewhere in nature, exhibiting a variety of mechanisms and structures and inspiring development in artificial muscle technology. Spider silk, specifically Ornithoctonus Huwena spider silk, now offers the newest such inspiration thanks to research from a collaboration of scientists in China and the U.S., the results of which are published today in Applied Physics Letters, from AIP Publishing.
"Spider silk is a natural biological material with high sensitivity to water, which inspires us to study about the interaction between spider silk and water," said Hongwei Zhu, a professor in Tsinghua University's School of Material Science and Engineering in Beijing and part of the collaboration. "Ornithoctonus Huwena spider is a unique species as it can be bred artificially and it spins silk of nanoscale diameter."
Besides the shrink-stretch ability of muscles, the way in which the motion is triggered -- how the muscle is actuated -- is a key part of its functionality. These spider silk fibers, actuated by water droplets, showed impressive behavior in all the ways that matter to muscle performance (or to super heroes that may need them to swing from buildings).
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