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Predictive modelling-based design and experiments for synthesis and spinning of bioinspired silk fibres

Author

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  • Shangchao Lin

    (Laboratory for Atomistic and Molecular Mechanics (LAMM), Massachusetts Institute of Technology
    Materials Science and Engineering Program, Florida State University)

  • Seunghwa Ryu

    (Laboratory for Atomistic and Molecular Mechanics (LAMM), Massachusetts Institute of Technology
    Korea Advanced Institute of Science and Technology (KAIST))

  • Olena Tokareva

    (Laboratory for Atomistic and Molecular Mechanics (LAMM), Massachusetts Institute of Technology
    Tufts University)

  • Greta Gronau

    (Laboratory for Atomistic and Molecular Mechanics (LAMM), Massachusetts Institute of Technology
    Institute for Particle Technology, Technische Universitat Braunschweig)

  • Matthew M. Jacobsen

    (Boston University)

  • Wenwen Huang

    (Tufts University)

  • Daniel J. Rizzo

    (Center for Nanoscopic Physics, Tufts University)

  • David Li

    (Boston University)

  • Cristian Staii

    (Center for Nanoscopic Physics, Tufts University)

  • Nicola M. Pugno

    (Laboratory of Bio-Inspired and Graphene Nanomechanics, Environmental and Mechanical Engineering, University of Trento
    Centre for Materials and Microsystems, Fondazione Bruno Kessler
    School of Engineering and Materials Science, Queen Mary University of London)

  • Joyce Y. Wong

    (Boston University)

  • David L. Kaplan

    (Tufts University)

  • Markus J. Buehler

    (Laboratory for Atomistic and Molecular Mechanics (LAMM), Massachusetts Institute of Technology)

Abstract

Scalable computational modelling tools are required to guide the rational design of complex hierarchical materials with predictable functions. Here, we utilize mesoscopic modelling, integrated with genetic block copolymer synthesis and bioinspired spinning process, to demonstrate de novo materials design that incorporates chemistry, processing and material characterization. We find that intermediate hydrophobic/hydrophilic block ratios observed in natural spider silks and longer chain lengths lead to outstanding silk fibre formation. This design by nature is based on the optimal combination of protein solubility, self-assembled aggregate size and polymer network topology. The original homogeneous network structure becomes heterogeneous after spinning, enhancing the anisotropic network connectivity along the shear flow direction. Extending beyond the classical polymer theory, with insights from the percolation network model, we illustrate the direct proportionality between network conductance and fibre Young's modulus. This integrated approach provides a general path towards de novo functional network materials with enhanced mechanical properties and beyond (optical, electrical or thermal) as we have experimentally verified.

Suggested Citation

  • Shangchao Lin & Seunghwa Ryu & Olena Tokareva & Greta Gronau & Matthew M. Jacobsen & Wenwen Huang & Daniel J. Rizzo & David Li & Cristian Staii & Nicola M. Pugno & Joyce Y. Wong & David L. Kaplan & Ma, 2015. "Predictive modelling-based design and experiments for synthesis and spinning of bioinspired silk fibres," Nature Communications, Nature, vol. 6(1), pages 1-12, November.
    • Handle: RePEc:nat:natcom:v:6:y:2015:i:1:d:10.1038_ncomms7892
    DOI: 10.1038/ncomms7892
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    Cited by:

    1. Jing Sun & Haonan He & Kelu Zhao & Wenhao Cheng & Yuanxin Li & Peng Zhang & Sikang Wan & Yawei Liu & Mengyao Wang & Ming Li & Zheng Wei & Bo Li & Yi Zhang & Cong Li & Yao Sun & Jianlei Shen & Jingjing, 2023. "Protein fibers with self-recoverable mechanical properties via dynamic imine chemistry," Nature Communications, Nature, vol. 14(1), pages 1-13, December.

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