Spider dragline silk as torsional actuator driven by humidity

Liu, Dabiao; Tarakanova, Anna; Hsu, Claire C.; Yu, Miao; Zheng, Shimin; Yu, Longteng; Liu, Jie; He, Yuming; Dunstan, D. J.; Buehler, Markus J.

doi:10.1126/sciadv.aau9183

Cited by 122 publications

(106 citation statements)

References 44 publications

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“…By increasing the RS fraction, this effect disappears and a less hydrophilic surface was obtained (Figure 3c). This shrinking effect is very similar to a well-known property of spider silk called super-contraction, in which the silk fibres can suddenly shrink in response to changes in moisture [27]. Spider silk is a protein fibre like silkworm silk.…”

Section: Morphology Structure and Mechanical Properties Of The Filmsmentioning

confidence: 60%

Plasticised Regenerated Silk/Gold Nanorods Hybrids as Sealant and Bio-Piezoelectric Materials

et al. 2020

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Manual and mechanical suturing are currently the gold standard for bowel anastomosis. If tissue approximation fails, anastomotic leaks occur. Anastomotic leaks may have catastrophic consequences. The development of a fully absorbable, biocompatible sealant material based on a bio-ink silk fibroin can reduce the chance of anastomotic leaks. We have produced a Ca-modified plasticised regenerated silk (RS) with gold nanorods sealant. This sealant was applied to anastomosed porcine intestine. Water absorption from wet tissue substrate applied compressive strains on hybrid RS films. This compression results in a sealant effect on anastomosis. The increased toughness of the hybrid plasticised RS resulted in the designing of a bio-film with superior elongation at break (i.e., ≈200%) and bursting pressure. We have also reported structure-dependent piezoelectricity of the RS film that shows a piezoelectric effect out of the plane. We hope that in the future, bowel anastomosis can be simplified by providing a multifunctional bio-film that makes feasible the mechanical tissue joint without the need for specific tools and could be used in piezoelectric sealant heads.

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Section: Morphology Structure and Mechanical Properties Of The Filmsmentioning

confidence: 60%

Plasticised Regenerated Silk/Gold Nanorods Hybrids as Sealant and Bio-Piezoelectric Materials

et al. 2020

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“…Examples include the opening of pine cones (4), the dispersion of wheat awn seeds (5), and the unfolding of ice plant seed capsules (6). At the molecular level, biological protein materials such as silk (7) and collagen (8) control their mechanical forces and motions by changing their molecular conformations in response to moisture. Inspiration drawn from such naturally occurring biological systems has led to the development of a wide range of artificial soft actuators that can reversibly alter morphological or mechanical characteristics in response to external stimuli (9)(10)(11).…”

mentioning

confidence: 99%

Actuation and locomotion driven by moisture in paper made with natural pollen

Zhao

Hwang

Yang

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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Here we describe the development of a humidity-responsive sheet of paper that is derived solely from natural pollen. Adaptive soft material components of the paper exhibit diverse and well-integrated responses to humidity that promote shape reconfiguration, actuation, and locomotion. This mechanically versatile and nonallergenic paper can generate a cyclically high contractile stress upon water absorption and desorption, and the rapid exchange of water drives locomotion due to hydrodynamic effects. Such dynamic behavior can be finely tuned by adjusting the structure and properties of the paper, including thickness, surface roughness, and processing conditions, analogous to those of classical soapmaking. We demonstrate that humidity-responsive paper-like actuators can mimic the blooming of the Michelia flower and perform self-propelled motion. Harnessing the material properties of bioinspired systems such as pollen paper opens the door to a wide range of sustainable, eco-friendly, and biocompatible material innovation platforms for applications in sensing, actuation, and locomotion.

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“…It exhibits unique humidity‐induced actuation behavior with a torsional deformation more than 300° mm −1 . This value is thousands of times higher than that of other conventional fiber microactuators, such as conducting polymer actuators (0.01° mm −1 ) and shape‐memory alloy fibers microactuators (0.15° mm −1 ) . In fact, the humidity‐induced actuation of the spider dragline silk is even higher than that of the state of the art of the carbon nanotubes (CNTs) microactuators (250° mm −1 ), which is powered by the electricity.…”

Section: Introductionmentioning

confidence: 93%

“…For example, spider dragline silk is an extraordinary fiber that surpasses the majority of conventional materials in mechanical characteristics such as the mechanical toughness. Moreover, spider dragline silk has proven to be an outstanding torsional actuator . It exhibits unique humidity‐induced actuation behavior with a torsional deformation more than 300° mm −1 .…”

Section: Introductionmentioning

confidence: 99%

Ultrastrong and Highly Sensitive Fiber Microactuators Constructed by Force‐Reeled Silks

et al. 2020

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Fiber microactuators are interesting in wide variety of emerging fields, including artificial muscles, biosensors, and wearable devices. In the present study, a robust, fast‐responsive, and humidity‐induced silk fiber microactuator is developed by integrating force‐reeling and yarn‐spinning techniques. The shape gradient, together with hierarchical rough surface, allows these silk fiber microactuators to respond rapidly to humidity. The silk fiber microactuator can reach maximum rotation speed of 6179.3° s−1 in 4.8 s. Such a response speed (1030 rotations per minute) is comparable with the most advanced microactuators. Moreover, this microactuator generates 2.1 W kg−1 of average actuation power, which is twice higher than fiber actuators constructed by cocoon silks. The actuating powers of silk fiber microactuators can be precisely programmed by controlling the number of fibers used. Lastly, theory predicts the observed performance merits of silk fiber microactuators toward inspiring the rational design of water‐induced microactuators.

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Spider dragline silk as torsional actuator driven by humidity

Cited by 122 publications

References 44 publications

Plasticised Regenerated Silk/Gold Nanorods Hybrids as Sealant and Bio-Piezoelectric Materials

Plasticised Regenerated Silk/Gold Nanorods Hybrids as Sealant and Bio-Piezoelectric Materials

Actuation and locomotion driven by moisture in paper made with natural pollen

Ultrastrong and Highly Sensitive Fiber Microactuators Constructed by Force‐Reeled Silks

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