Bioinspired living structural color hydrogels

Fu, Fanfan; Shang, Luoran; Chen, Zhuoyue; Yu, Yunru; Zhao, Yuanjin

doi:10.1126/scirobotics.aar8580

Cited by 458 publications

(383 citation statements)

References 48 publications

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“…[111] As these stimuli greatly overlap with the ones for actuating soft materials,one promising path in research is to combine the photonic materials with soft actuators for adaptive,d ynamic displays in future biohybrid robots (Figure 2c). [112] Directly embedding artificial "chromatophores" into the elastomeric substrates is more widely adopted in conventional soft robotic systems.T hese chromatophores are based upon materials and structures that are capable of emitting light. Examples include the patterning of microfluidic networks filled with pigmented or fluorescent liquids and overlaying highly stretchable electroluminescent polymer composites ( Figure 2d).…”

Section: Soft Display and Camouflage Materialsmentioning

confidence: 99%

Bio‐inspired Design and Additive Manufacturing of Soft Materials, Machines, Robots, and Haptic Interfaces

et al. 2019

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Soft materials possess several distinctive characteristics, such as controllable deformation, infinite degrees of freedom, and self‐assembly, which make them promising candidates for building soft machines, robots, and haptic interfaces. In this Review, we give an overview of recent advances in these areas, with an emphasis on two specific topics: bio‐inspired design and additive manufacturing. Biology is an abundant source of inspiration for functional materials and systems that mimic the function or mechanism of biological tissues, agents, and behaviors. Additive manufacturing has enabled the fabrication of materials and structures prevalent in biology, thereby leading to more‐capable soft robots and machines. We believe that bio‐inspired design and additive manufacturing have been, and will continue to be, important tools for the design of soft robots.

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Section: Soft Display and Camouflage Materialsmentioning

confidence: 99%

Bio‐inspired Design and Additive Manufacturing of Soft Materials, Machines, Robots, and Haptic Interfaces

et al. 2019

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“…[1][2][3][4][5][6] For instance, cephalopods (squid, cuttlefish, www.advmatinterfaces.de strain sensors, such as incapability of information delivery, [35] humidity dependence, [19,22,25] and lack of scalability [15,23] and has various potential applications including stress, strain and bending sensors, data encryption and security labels. [1][2][3][4][5][6] For instance, cephalopods (squid, cuttlefish, www.advmatinterfaces.de strain sensors, such as incapability of information delivery, [35] humidity dependence, [19,22,25] and lack of scalability [15,23] and has various potential applications including stress, strain and bending sensors, data encryption and security labels.…”

Section: Introductionmentioning

confidence: 99%

A Patterned Mechanochromic Photonic Polymer for Reversible Image Reveal

Zhang

Shi

Schenning

et al. 2019

Adv Materials Inter

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octopus, and so on) are able to produce a wide range of structural colors and photonic patterns to signal and communicate with their own species and others. [4,7] Inspired by nature, scientific efforts have been devoted to develop smart photonic materials which inform the user by changing their structural color. [8][9][10] Mechanochromic photonic materials, which change structural color in response to mechanical stimuli, are attractive for a wide range of applications such as strain mapping, [11,12] stress sensing, [13][14][15][16] anti-counterfeiting, [17][18][19] tunable optical devices, [20,21] and so on. Different materials, such as inorganic, polymeric, and hybrid components have been used to fabricate these mechanochromic photonic devices. [11][12][13][14][15][16][17][18][19][20][21][22][23][24][25] Among these smart materials, cholesteric liquid crystals (CLCs) have garnered significant attention in the

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“…Along with the culture time, the aligned cells increased from 39 ± 5% after 8 h of seeding to 57 ± 3% after 72 h, and then decreased after 192 h as a result of the formation of confluence. In another study, Fu et al fabricated 20, 40, and 60 µm wide parallel grooves on gelMA hydrogel films by replicating the patterns on silicon wafers . It was found that 55% of CMs aligned within 30° from the direction of 60 µm grooves, while this proportion increased when the width decreased (80% for 20 µm).…”

Section: Nano‐ and Microfabrication For Cell Alignmentmentioning

confidence: 99%

Nano‐ and Microfabrication for Engineering Native‐Like Muscle Tissues

et al. 2020

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Muscle tissues are characterized by highly organized 3D structures consisting of aligned myocytes and nonmyocytes. Several nano‐ and microfabrication technologies are used to engineer native‐like muscle tissues for muscle regeneration, the treatment of cardiovascular diseases, and in vitro disease modeling. In this paper, traditional tissue engineering methods and novel nano‐/microfabrication technologies for constructing muscle tissues are reviewed. Focus is given on the effects of nano‐/microfabricated architectures on the alignment of cells. In addition, issues of vascularization and cell–cell interaction in fabricating muscle tissues are discussed. Finally, common challenges of fabricating three types of muscle tissues and specific requirements for each type are reviewed, and perspectives are given for future studies.

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Bioinspired living structural color hydrogels

Cited by 458 publications

References 48 publications

Bio‐inspired Design and Additive Manufacturing of Soft Materials, Machines, Robots, and Haptic Interfaces

Bio‐inspired Design and Additive Manufacturing of Soft Materials, Machines, Robots, and Haptic Interfaces

A Patterned Mechanochromic Photonic Polymer for Reversible Image Reveal

Nano‐ and Microfabrication for Engineering Native‐Like Muscle Tissues

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