In-drop capillary spooling of spider capture thread inspires highly extensible fibres

TL;DR

This study reveals how glue droplets in spider capture threads induce buckling and coiling of the silk core, inspiring the design of highly extensible synthetic fibers through capillarity and elasticity interplay.

Contribution

The paper demonstrates that glue droplets actively spool the silk core via capillarity, providing a new understanding of spider silk mechanics and inspiring bioinspired synthetic fibers.

Findings

Glue droplets induce buckling and coiling of silk filaments.

Fibre spooling results from elasticity-capillarity interplay.

Synthetic fibers mimic natural spooling mechanism.

Abstract

Spiders' webs and gossamer threads are often paraded as paradigms for lightweight structures and outstanding polymers. Probably the most intriguing of all spider silks is the araneid capture thread, covered with tiny glycoprotein glue droplets. Even if compressed, this thread remains surprisingly taut, a property shared with pure liquid films, allowing both thread and web to be in a constant state of tension. Vollrath and Edmonds proposed that the glue droplets would act as small windlasses and be responsible for the tension, but other explanations have also been suggested, involving for example the macromolecular properties of the flagelliform silk core filaments. Here we show that the nanolitre glue droplets of the capture thread indeed induce buckling and coiling of the core filaments: microscopic in-vivo observations reveal that the slack fibre is spooled into and within the droplets. We model windlass activation as a structural phase transition, and show that fibre spooling essentially results from the interplay between elasticity and capillarity. This is demonstrated by reproducing artificially the mechanism on a synthetic polyurethane thread/silicone oil droplet system. Fibre size is the key in natural and artificial setups which both require micrometer-sized fibres to function. The spools and coils inside the drops are further shown to directly affect the mechanical response of the thread, evidencing the central role played by geometry in spider silk mechanics. Beside shedding light on araneid capture thread functionality, we argue that the properties of this biological system provide novel insights for bioinspired synthetic actuators.