Spider silk as a novel high performance biomimetic muscle driven by humidity

Agnarsson, Ingi; Dhinojwala, Ali; Sahni, Vasav; Blackledge, Todd A.

doi:10.1242/jeb.028282

Cited by 136 publications

(135 citation statements)

References 29 publications

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“…3). This novel property of dragline silk can be exploited to do work and generate energy, offering potential for the development of biomimetic muscle fibers, sensors and other applications (Agnarsson et al, 2009b).…”

Section: Discussionmentioning

confidence: 99%

“…Thus, cyclic contraction can occur prior to supercontraction or after enough water has been absorbed to disrupt bonding within the glycine-rich linkers to cause supercontraction. Moreover, cyclic contraction is a phenomenon that occurs in other hydrophilic biological materials, with the magnitude of the response scaling directly with the stiffness of each material (Agnarsson et al, 2009b).…”

Section: Discussionmentioning

confidence: 99%

“…This cyclic response produces high forces that can be precisely controlled through humidity alone. Thus, spider silk emerges as an attractive model for biomimetic muscle fibers (Agnarsson et al, 2009b).…”

Section: Introductionmentioning

confidence: 99%

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How super is supercontraction? Persistent versus cyclic responses to humidity in spider dragline silk

Blackledge

Boutry

Wong

et al. 2009

Journal of Experimental Biology

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107

114

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SUMMARYSpider dragline silk has enormous potential for the development of biomimetic fibers that combine strength and elasticity in low density polymers. These applications necessitate understanding how silk reacts to different environmental conditions. For instance, spider dragline silk 'supercontracts' in high humidity. During supercontraction, unrestrained dragline silk contracts up to 50% of its original length and restrained fibers generate substantial stress. Here we characterize the response of dragline silk to changes in humidity before, during and after supercontraction. Our findings demonstrate that dragline silk exhibits two qualitatively different responses to humidity. First, silk undergoes a previously unknown cyclic relaxation-contraction response to wetting and drying. The direction and magnitude of this cyclic response is identical both before and after supercontraction. By contrast, supercontraction is a 'permanent' tensioning of restrained silk in response to high humidity. Here, water induces stress, rather than relaxation and the uptake of water molecules results in a permanent change in molecular composition of the silk, as demonstrated by thermogravimetric analysis (TGA). Even after drying, silk mass increased by ~1% after supercontraction. By contrast, the cyclic response to humidity involves a reversible uptake of water. Dried, post-supercontraction silk also differs mechanically from virgin silk. Post-supercontraction silk exhibits reduced stiffness and stress at yield, as well as changes in dynamic energy storage and dissipation. In addition to advancing understanding supercontraction, our findings open up new applications for synthetic silk analogs. For example, dragline silk emerges as a model for a biomimetic muscle, the contraction of which is precisely controlled by humidity alone.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

How super is supercontraction? Persistent versus cyclic responses to humidity in spider dragline silk

Blackledge

Boutry

Wong

et al. 2009

Journal of Experimental Biology

Self Cite

107

114

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“…Figure 4b compares the estimated energy densities and strain responses of the TNF film with typical values reported for materials frequently used or studied in the context of actuators and stimuli-responsive materials. [20][21][22][23][24] At this point, even though this TNF actuator has a much lower energy density than a shape memory alloy, it still shows a relatively high energy density compared to other actuators with sustainability and repeatability. Since this actuator uses a new hygromorphic actuating mechanism, it could be a useful actuator once the obstacles, such as response time and actuation speed, are solved.…”

Section: Resultsmentioning

confidence: 95%

“…In fact, onlỹ 15 mg of the titanium oxide nano-capillary films generated a larger force than most other actuating devices on a per mass basis. [20][21][22][23][24] Because the strain energy varies throughout a body, it is convenient to use the concept of strain energy density, which is a measure of how much energy is stored in small-volume elements throughout a material. To calculate the energy density of the free-standing TNF film, we assumed that the film is a uniform geometry in the form of an end-loaded cantilever of length L and calculated the strain energy for normal stresses acting in the elastic material upon deformation by a steadily increasing force F. The work done in extending the cantilever by a small amount, dx, is stored as elastic strain energy U, given as U = Fdx.…”

Section: Resultsmentioning

confidence: 99%

Hygromorphic actuator from a metal oxide film driven by a nano-capillary forest structure

et al. 2017

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We have developed a hygromorphic metal oxide actuator using an electrochemical method to produce a superhydrophilic freestanding nano-capillary forest of titanium oxide with a high aspect ratio (~80). This metal oxide film has an inhomogeneous initial gap at the top and bottom surfaces between the tubes due to flexure during fabrication. The actuation mechanism is as follows. First, when a drop of water is applied on the surface of a titanium oxide nano-capillary forest (TNF), the water penetrates through the film instantaneously, and the titanium oxide nano-capillaries are pulled together by interplay of the capillary force and van der Waals force. When water has fully filled in the gaps between the capillaries, the free-standing TNF film remains unbent for~2 min. Then, as the water evaporates, the film bends further in the forward direction. When the water has completely evaporated, the van der Waals force alone acts on the capillaries, and the TNF film returns to its initial state. This TNF possesses great stability and repeatability for long-term usage having a high bending energy density of~1250 kJ m -3 and unique capabilities. It may lead to novel stimuli-responsive systems, including energy collection and storage, as well as robotics applications.

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Brillouin Light Spectroscopy and Anisotropic Elasticity

Wang¹,

Fytas²

2021

Encyclopedia of Polymer Science and Technology

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Understanding the elastic properties of polymer‐based materials is essential for many applications (e.g., biofibers, coatings, interfacial fillers, organics semiconductors). Often those materials are anisotropic, posing a challenge for characterizing their direction‐dependent elasticity. As an optical technique, Brillouin light spectroscopy (BLS) allows determination of the complete elastic tensor of materials in a noncontact, nondestructive manner. The elastic properties of many polymer‐based materials have been investigated by BLS in the past five decades. In this review, we present the working principles of BLS and a few recent applications of BLS to the determination of the complete elasticity of polymer‐based, nanostructured, anisotropic materials. Considering its unique power in elasticity characterization, we expect BLS to find more applications in the future, particularly in the research fields of materials science, biomedical science, biomechanics, and nanotechnology.

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Spider silk as a novel high performance biomimetic muscle driven by humidity

Cited by 136 publications

References 29 publications

How super is supercontraction? Persistent versus cyclic responses to humidity in spider dragline silk

How super is supercontraction? Persistent versus cyclic responses to humidity in spider dragline silk

Hygromorphic actuator from a metal oxide film driven by a nano-capillary forest structure

Brillouin Light Spectroscopy and Anisotropic Elasticity

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