Predicting Silk Fiber Mechanical Properties through Multiscale Simulation and Protein Design

Rim, Nae-Gyune; Roberts, Erin G.; Ebrahimi, Davoud; Dinjaski, Nina; Jacobsen, Matthew M.; Martín‐Moldes, Zaira; Buehler, Markus J.; Kaplan, David L.; Wong, Joyce Y.

doi:10.1021/acsbiomaterials.7b00292

Cited by 34 publications

(26 citation statements)

References 32 publications

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“…To understand how SWCNT improve the mechanical properties of S-silk at the microscopic scale, DPD simulation was performed. Here we adopted a coarse-grained description 43,44 of silk proteins and SWCNT to investigate the structural evolution of amorphous (3 1helix and β-turn) and crystalline (β-sheet nanocrystal) structures of silk in the presence of SWCNT under different strains. Every 9 water molecules are represented by one hydrophilic "w" bead, as shown in Supplementary Fig.…”

Section: Resultsmentioning

confidence: 99%

A supertough electro-tendon based on spider silk composites

et al. 2020

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Compared to transmission systems based on shafts and gears, tendon-driven systems offer a simpler and more dexterous way to transmit actuation force in robotic hands. However, current tendon fibers have low toughness and suffer from large friction, limiting the further development of tendon-driven robotic hands. Here, we report a super tough electro-tendon based on spider silk which has a toughness of 420 MJ/m 3 and conductivity of 1,077 S/cm. The electro-tendon, mechanically toughened by single-wall carbon nanotubes (SWCNTs) and electrically enhanced by PEDOT:PSS, can withstand more than 40,000 bendingstretching cycles without changes in conductivity. Because the electro-tendon can simultaneously transmit signals and force from the sensing and actuating systems, we use it to replace the single functional tendon in humanoid robotic hand to perform grasping functions without additional wiring and circuit components. This material is expected to pave the way for the development of robots and various applications in advanced manufacturing and engineering.

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Section: Resultsmentioning

confidence: 99%

A supertough electro-tendon based on spider silk composites

et al. 2020

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“…These properties are attributed to a hierarchical arrangement of ordered and disordered protein structures within a single fiber (Vollrath and Porter, 2009;Vollrath et al, 2011;Porter et al, 2013). This nanostructure has been extensively explored by bulk and space-averaging techniques such as calorimetry (Cebe et al, 2013;Vollrath et al, 2014;Holland et al, 2018a), spectroscopy (Dicko et al, 2007;Boulet-Audet et al, 2015) small angle scattering X-ray and neutron diffraction (Termonia, 1994;Riekel et al, 2000;Greving et al, 2010;Wagner et al, 2017) and solid state nuclear magnetic resonance (NMR) (Willis et al, 1972;Hijirida et al, 1996;Kümmerlen et al, 1996;Yang et al, 2000;Holland et al, 2008;McGill et al, 2018), which together have provided the fuel for a range of modeling approaches (Giesa et al, 2011;Cranford, 2013;Ebrahimi et al, 2015;Rim et al, 2017). In comparison, spatially resolved techniques are yet to be fully explored, but have already hinted at a diverse set of rich nano-and microscale features such as micelles (Lin et al, 2017;Oktaviani et al, 2018;Parent et al, 2018), nanofibrils (Wang and Schniepp, 2018), elongated cavities (Frische et al, 2002), and an overall radial variation of composition and structure (Li et al, 1994;Knight et al, 2000;Frische et al, 2002;Sponner et al, 2007;Brown et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Revealing Spider Silk's 3D Nanostructure Through Low Temperature Plasma Etching and Advanced Low-Voltage SEM

et al. 2019

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The excellent mechanical properties of spider dragline silk are closely linked to its multiscale hierarchical structuring which develops as it is spun. If this is to be understood and mimicked, multiscale models must emerge which effectively bridge the length scales. This study aims to contribute to this goal by exposing structures within Nephila dragline silk using low-temperature plasma etching and advanced Low Voltage Scanning Electron Microscopy (LV-SEM). It is shown that Secondary Electron Hyperspectral Imaging (SEHI) is sensitive to compositional differences on both the micro and nano scale. On larger scales it can distinguish the lipids outermost layer from the protein core, while at smaller scales SEHI is effective in better resolving nanostructures present in the matrix. Key results suggest that the silks spun at lower reeling speeds tend to have a greater proportion of smaller nanostructures in closer proximity to one-another in the fiber, which we associate with the fiber's higher toughness but lower stiffness. The bimodal size distribution of ordered domains, their radial distribution, nanoscale spacings, and crucially their interactions may be key in bridging the length scale gaps which remain in current spider silk structure-property models. Ultimately this will allow successful biomimetic implementation of new models.

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“…Thus, using different modeling and simulation techniques, we are able to design these materials along different length scales, from the amino acid sequence to the macroscopic structure, to predict their properties . These in silico approaches can enormously reduce the costs of experimental research . Many of these bottom‐up models for silk and silk‐based biomaterials have been extensively validated by experiments, showcasing their predictive power …”

Section: Computational Methods For Multiscale Modeling Of Silkmentioning

confidence: 99%

“…In this regard, computational modeling at different length scales provides fundamental understanding of structure–property and sequence–property relationships that can greatly accelerate the development of novel silk structures and silk‐based materials with tailored specific properties . Nevertheless, these computational models must also be validated and improved by iterating between simulations and experimental research on the synthesis and processing of silk biopolymers . The requirement of such iterative process highlights the need for interdisciplinary research consortia to accelerate the development of silk into a mainstream feedstock in the materials industry.…”

Section: Introductionmentioning

confidence: 99%

Multiscale Modeling of Silk and Silk‐Based Biomaterials—A Review

Barreiro

Yeo

Tarakanova

et al. 2018

Macromolecular Bioscience

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Silk embodies outstanding material properties and biologically relevant functions achieved through a delicate hierarchical structure. It can be used to create high‐performance, multifunctional, and biocompatible materials through mild processes and careful rational material designs. To achieve this goal, computational modeling has proven to be a powerful platform to unravel the causes of the excellent mechanical properties of silk, to predict the properties of the biomaterials derived thereof, and to assist in devising new manufacturing strategies. Fine‐scale modeling has been done mainly through all‐atom and coarse‐grained molecular dynamics simulations, which offer a bottom‐up description of silk. In this work, a selection of relevant contributions of computational modeling is reviewed to understand the properties of natural silk, and to the design of silk‐based materials, especially combined with experimental methods. Future research directions are also pointed out, including approaches such as 3D printing and machine learning, that may enable a high throughput design and manufacturing of silk‐based biomaterials.

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Predicting Silk Fiber Mechanical Properties through Multiscale Simulation and Protein Design

Cited by 34 publications

References 32 publications

A supertough electro-tendon based on spider silk composites

A supertough electro-tendon based on spider silk composites

Revealing Spider Silk's 3D Nanostructure Through Low Temperature Plasma Etching and Advanced Low-Voltage SEM

Multiscale Modeling of Silk and Silk‐Based Biomaterials—A Review

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