Bioinspired materials that self-shape through programmed microstructures.

Nature displays numerous examples of materials that can autonomously change their shape in response to external stimuli. Remarkably, shape changes in biological systems can be programmed within the material's microstructure to enable self-shaping capabilities even in the absence of cellular control. Here, we revisit recent attempts to replicate in synthetic materials the shape-changing behavior of selected natural materials displaying deliberately tuned fibrous architectures. Simple processing methods like drawing, spinning or casting under magnetic fields are shown to be effective in mimicking the orientation and spatial distribution of reinforcing fibers of natural materials, thus enabling unique shape-changing features in synthetic systems. The bioinspired design and creation of self-shaping microstructures represent a new pathway to program shape changes in synthetic materials. In contrast to shape-memory polymers and metallic alloys, the self-shaping capabilities in these bioinspired materials originate at the microstructural level rather than the molecular scale. This enables the creation of programmable shape changes using building blocks that would otherwise not display the intrinsic molecular/atomic phase transitions required in conventional shape-memory materials.

[1]  S. Timoshenko,et al.  Analysis of Bi-Metal Thermostats , 1925 .

[2]  C. Tanford Macromolecules , 1994, Nature.

[3]  D. Riddle,et al.  Interacting genes in nematode dauer larva formation , 1981, Nature.

[4]  Faraday Discuss , 1985 .

[5]  D. Radford Cure Shrinkage Induced Warpage in Flat Uni-Axial Composites , 1993 .

[6]  E. Terentjev,et al.  Twisting Transition in a Capillary Filled with Chiral Smectic C Liquid Crystal , 1994 .

[7]  E. Smela,et al.  Controlled Folding of Micrometer-Size Structures , 1995, Science.

[8]  Hisaaki Tobushi,et al.  Thermomechanical properties in a thin film of shape memory polymer of polyurethane series , 1996 .

[9]  J. Trotter,et al.  Stiparin: a glycoprotein from sea cucumber dermis that aggregates collagen fibrils. , 1996, Matrix biology : journal of the International Society for Matrix Biology.

[10]  C. Dawson,et al.  How pine cones open , 1997, Nature.

[11]  C. M. Wayman,et al.  Shape-Memory Materials , 2018 .

[12]  Oddvar O. Bendiksen,et al.  Structures, Structural Dynamics and Materials Conference , 1998 .

[13]  J. Trotter,et al.  Collagen fibril aggregation-inhibitor from sea cucumber dermis. , 1999, Matrix biology : journal of the International Society for Matrix Biology.

[14]  R. Shadwick,et al.  Dynamic mechanical characterization of a mutable collagenous tissue: response of sea cucumber dermis to cell lysis and dermal extracts. , 2000, The Journal of experimental biology.

[15]  Martin M. Mikulas,et al.  Carbon Fiber Reinforced Shape Memory Polymer Composites , 2000 .

[16]  G. Whitesides,et al.  Fabrication of Micrometer‐Scale, Patterned Polyhedra by Self‐Assembly , 2002 .

[17]  R. Langer,et al.  Biodegradable, Elastic Shape-Memory Polymers for Potential Biomedical Applications , 2002, Science.

[18]  R. Foster,et al.  Plants flex their skeletons. , 2003, Trends in plant science.

[19]  T. Ikeda,et al.  Photomechanics: Directed bending of a polymer film by light , 2003, Nature.

[20]  I. Wilkie,et al.  Mutable collagenous tissue: overview and biotechnological perspective. , 2005, Progress in molecular and subcellular biology.

[21]  宁北芳,et al.  疟原虫var基因转换速率变化导致抗原变异[英]/Paul H, Robert P, Christodoulou Z, et al//Proc Natl Acad Sci U S A , 2005 .

[22]  Eugene M. Terentjev,et al.  Photomechanical actuation in polymer–nanotube composites , 2005, Nature materials.

[23]  Janet Braam,et al.  In touch: plant responses to mechanical stimuli. , 2004, The New phytologist.

[24]  L. Mahadevan,et al.  How the Venus flytrap snaps , 2005, Nature.

[25]  A. Bausch,et al.  Cytoskeletal polymer networks: The molecular structure of cross-linkers determines macroscopic properties , 2006, Proceedings of the National Academy of Sciences.

[26]  Hongyan He,et al.  An oral delivery device based on self-folding hydrogels. , 2006, Journal of controlled release : official journal of the Controlled Release Society.

[27]  Michael R Wisnom,et al.  48th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference , 2007 .

[28]  R. Elbaum,et al.  The Role of Wheat Awns in the Seed Dispersal Unit , 2007, Science.

[29]  Pedro Brogueira,et al.  Helical Twisting of Electrospun Liquid Crystalline Cellulose Micro‐ and Nanofibers , 2008 .

[30]  Peter Fratzl,et al.  Cellulose fibrils direct plant organ movements. , 2008, Faraday discussions.

[31]  D. Tyler,et al.  Stimuli-Responsive Polymer Nanocomposites Inspired by the Sea Cucumber Dermis , 2008, Science.

[32]  D. Broer,et al.  Printed artificial cilia from liquid-crystal network actuators modularly driven by light. , 2009, Nature materials.

[33]  L. F. Pinto,et al.  How to mimic the shapes of plant tendrils on the nano and microscale: spirals and helices of electrospun liquid crystalline cellulose derivatives , 2009 .

[34]  R. Rosenfeld Nature , 2009, Otolaryngology--head and neck surgery : official journal of American Academy of Otolaryngology-Head and Neck Surgery.

[35]  F. Barth,et al.  Biomaterial systems for mechanosensing and actuation , 2009, Nature.

[36]  L. Mahadevan,et al.  Hygromorphs: from pine cones to biomimetic bilayers , 2009, Journal of The Royal Society Interface.

[37]  I. Burgert,et al.  Actuation systems in plants as prototypes for bioinspired devices , 2009, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[38]  Stuart J. Rowan,et al.  Biomimetic mechanically adaptive nanocomposites , 2010 .

[39]  H Tanaka,et al.  Programmable matter by folding , 2010, Proceedings of the National Academy of Sciences.

[40]  E. Terentjev,et al.  Self-winding of helices in plant tendrils and cellulose liquid crystal fibers , 2010 .

[41]  Thomas Speck,et al.  Ultra-fast underwater suction traps , 2011, Proceedings of the Royal Society B: Biological Sciences.

[42]  Leonid Ionov,et al.  Soft microorigami: self-folding polymer films , 2011 .

[43]  Yanju Liu,et al.  Shape-memory polymers and their composites: Stimulus methods and applications , 2011 .

[44]  R. Kupferman,et al.  Geometry and Mechanics in the Opening of Chiral Seed Pods , 2011, Science.

[45]  Peter Fratzl,et al.  Origami-like unfolding of hydro-actuated ice plant seed capsules. , 2011, Nature communications.

[46]  Stuart J. Rowan,et al.  Bioinspired Mechanically Adaptive Polymer Nanocomposites with Water-Activated Shape-Memory Effect , 2011 .

[47]  L. Mahadevan,et al.  How the Cucumber Tendril Coils and Overwinds , 2012, Science.

[48]  Thomas Speck,et al.  Catapulting Tentacles in a Sticky Carnivorous Plant , 2012, PloS one.

[49]  R. M. Erb,et al.  Non-linear alignment dynamics in suspensions of platelets under rotating magnetic fields , 2012 .

[50]  André R Studart,et al.  Composites Reinforced in Three Dimensions by Using Low Magnetic Fields , 2012, Science.

[51]  J. Greener,et al.  Three-dimensional shape transformations of hydrogel sheets induced by small-scale modulation of internal stresses , 2013, Nature Communications.

[52]  André R Studart,et al.  Self-shaping composites with programmable bioinspired microstructures , 2013, Nature Communications.

[53]  Leah Blau,et al.  Methods In Cell Biology , 2016 .