Fengyun Guo scite author profile

Wearable and stretchable electronics including various conductors and sensors are featured with their lightweight, high flexibility, and easy integration into functional devices or textiles. However, most flexible electronic materials are still unsatisfactory due to their poor recoverability under large strain. Herein, we fabricated a carbon nanotubes (CNTs) and polyurethane (PU) nanofibers composite helical yarn with electrical conductivity, ultrastretchability, and high stretch sensitivity. The synergy of elastic PU molecules and springlike microgeometry enable the helical yarn excellent stretchability, while CNTs are stably winding-locked into the yarn through a simple twisting strategy, making good conductivity. By virtue of the interlaced conductive network of CNTs in microlevel and the helical structure in macrolevel, the CNTs/PU helical yarn achieves good recoverability within 900% and maximum tensile elongation up to 1700%. With these features, it can be used as a superelastic and highly stable conductive wire. Moreover, it also can monitor the human motion as a rapid-response strain sensor by adjusting the content of the CNTs simply. This general and low-cost strategy is of great promise for ultrastretchable wearable electronics and multifunctional devices.

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Bioinspired graphene membrane with temperature tunable channels for water gating and molecular separation

Liu

et al. 2017

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Smart regulation of substance permeability through porous membranes is highly desirable for membrane applications. Inspired by the stomatal closure feature of plant leaves at relatively high temperature, here we report a nano-gating membrane with a negative temperature-response coefficient that is capable of tunable water gating and precise small molecule separation. The membrane is composed of poly(N-isopropylacrylamide) covalently bound to graphene oxide via free-radical polymerization. By virtue of the temperature tunable lamellar spaces of the graphene oxide nanosheets, the water permeance of the membrane could be reversibly regulated with a high gating ratio. Moreover, the space tunability endows the membrane with the capability of gradually separating multiple molecules of different sizes. This nano-gating membrane expands the scope of temperature-responsive membranes and has great potential applications in smart gating systems and molecular separation.

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A Robust Cu(OH)₂ Nanoneedles Mesh with Tunable Wettability for Nonaqueous Multiphase Liquid Separation

Liu

Wang

et al. 2016

Small

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Opposite and complementary: a superhydrophobic–superhydrophilic integrated system for high-flux, high-efficiency and continuous oil/water separation

et al. 2016

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A bio-inspired high strength three-layer nanofiber vascular graft with structure guided cell growth

Wang

et al. 2017

J. Mater. Chem. B

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A Co₃O₄ nano-needle mesh for highly efficient, high-flux emulsion separation

et al. 2016

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Helical nanofiber yarn enabling highly stretchable engineered microtissue

Guo

Hao

et al. 2019

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

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Development of microtissues that possess mechanical properties mimicking those of native stretchable tissues, such as muscle and tendon, is in high demand for tissue engineering and regenerative medicine. However, regardless of the significant advances in synthetic biomaterials, it remains challenging to fabricate living microtissue with high stretchability because application of large strains to microtissues can damage the cells by rupturing their structures. Inspired by the hierarchical helical structure of native fibrous tissues and its behavior of nonaffine deformation, we develop a highly stretchable and tough microtissue fiber made up of a hierarchical helix yarn scaffold, scaling from nanometers to millimeters, that can overcome this limitation. This microtissue can be stretched up to 15 times its initial length and has a toughness of 57 GJ m−3. More importantly, cells grown on this scaffold maintain high viability, even under severe cyclic strains (up to 600%) that can be attributed to the nonaffine deformation under large strains, mimicking native biopolymer scaffolds. Furthermore, as proof of principle, we demonstrate that the nanotopography of the helical nanofiber yarn is able to induce cytoskeletal alignment and nuclear elongation, which promote myogenic differentiation of mesenchymal stem cells by triggering nuclear translocation of transcriptional coactivator with PDZ-binding motif (TAZ). The highly stretchable microtissues we develop here will facilitate a variety of tissue engineering applications and the development of engineered living systems.

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Trap Effect of Three‐Dimensional Fibers Network for High Efficient Cancer‐Cell Capture

Gao

Wang

et al. 2015

Adv Healthcare Materials

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Fengyun Guo

Winding-Locked Carbon Nanotubes/Polymer Nanofibers Helical Yarn for Ultrastretchable Conductor and Strain Sensor

Bioinspired graphene membrane with temperature tunable channels for water gating and molecular separation

A Robust Cu(OH)₂ Nanoneedles Mesh with Tunable Wettability for Nonaqueous Multiphase Liquid Separation

Opposite and complementary: a superhydrophobic–superhydrophilic integrated system for high-flux, high-efficiency and continuous oil/water separation

A bio-inspired high strength three-layer nanofiber vascular graft with structure guided cell growth

A Co₃O₄ nano-needle mesh for highly efficient, high-flux emulsion separation

Helical nanofiber yarn enabling highly stretchable engineered microtissue

Trap Effect of Three‐Dimensional Fibers Network for High Efficient Cancer‐Cell Capture

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Fengyun Guo

Winding-Locked Carbon Nanotubes/Polymer Nanofibers Helical Yarn for Ultrastretchable Conductor and Strain Sensor

Bioinspired graphene membrane with temperature tunable channels for water gating and molecular separation

A Robust Cu(OH)2 Nanoneedles Mesh with Tunable Wettability for Nonaqueous Multiphase Liquid Separation

Opposite and complementary: a superhydrophobic–superhydrophilic integrated system for high-flux, high-efficiency and continuous oil/water separation

A bio-inspired high strength three-layer nanofiber vascular graft with structure guided cell growth

A Co3O4 nano-needle mesh for highly efficient, high-flux emulsion separation

Helical nanofiber yarn enabling highly stretchable engineered microtissue

Trap Effect of Three‐Dimensional Fibers Network for High Efficient Cancer‐Cell Capture

Contact Info

Product

Resources

About

A Robust Cu(OH)₂ Nanoneedles Mesh with Tunable Wettability for Nonaqueous Multiphase Liquid Separation

A Co₃O₄ nano-needle mesh for highly efficient, high-flux emulsion separation