Dual-gradient enabled ultrafast biomimetic snapping of hydrogel materials

Fan, Wenxin; Shan, Caiyun; Guo, Hongyu; Sang, Jianwei; Wang, Rui; Zheng, Ranran; Sui, Kunyan; Nie, Zhihong

doi:10.1126/sciadv.aav7174

Cited by 195 publications

(185 citation statements)

References 36 publications

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“…Fan et al suggested the preparation of dual-gradient hydrogel materials, i.e., hydrogels with chain and cross-linking density gradients [13]. The dual-gradient should mimic fast actuation phenomena in nature such as the snapping leaves of a flytrap.…”

Section: Controlled Gelationmentioning

confidence: 99%

Gradient Hydrogels—The State of the Art in Preparation Methods

2020

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Gradient hydrogels refer to hydrogel materials with a gradual or abrupt change in one or some of their properties. They represent examples of more sophisticated gel materials in comparison to simple, native gel networks. Here, we review techniques used to prepare gradient hydrogels which have been reported in literature over the last few years. A variety of simple preparation methods are available, most of which can be relatively easily utilized in standard laboratories

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Section: Controlled Gelationmentioning

confidence: 99%

Gradient Hydrogels—The State of the Art in Preparation Methods

2020

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“…Hydrogels with good flexibility and water‐storage performance belong to the class of highly promising functional materials. Their high hydrophilicity, water retention, and good biocompatibility endows them with extensive application prospects in biological tissue scaffold, controlled release of drug, adsorption and separation of pollutants, sensors, intelligent soft robots, petroleum engineering, mining engineering, and other fields. However, the traditional hydrogels are brittle.…”

Section: Introductionmentioning

confidence: 99%

Poly(acrylic acid)‐chitosan @ tannic acid double‐network self‐healing hydrogel based on ionic coordination

Zhang

et al. 2020

Polymers for Advanced Techs

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In this work, poly(acrylic) acid-chitosan @ tannic acid-aluminum ion (PAA-CS@TA-Al 3+ ) double-network hydrogel was prepared via prefabrication, blending method, and Al 3+ immersion method. The interaction between chitosan and tannic acid (CS@TA) was analyzed using Fourier transfer infrared spectra and UV-Vis spectra. The UV-Vis spectrum was also used to confirm the formation of ionic coordination in the gel. Then, the possible coordination modes were studied and analyzed. The microscopic pore structure and macroscopic strain behavior of the gel were analyzed using SEM and tensile testing, respectively, which verified that the tensile strength (≈32 KPa) and elongation at break (≈1700%) of the gel primarily resulted from its crosslinking structure. In addition, the gel also demonstrated a good self-healing performance with recovery ≈92.2% at 60 minutes.Hence, the proposed novel self-healing gel can provide inspiration for the preparation of future self-healing gels. K E Y W O R D Schitosan, double-network hydrogel, ionic coordination, self-healing, tannic acid

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“…To address the working environment limitation, the poly(acrylic acid‐ co ‐acrylamide) P(AAm‐ co ‐AAc) hydrogel was introduced on account of its opposite thermos‐responsiveness. Previous researches have reported some bilayer hydrogels which were composed of intelligent hydrogels with opposite responsiveness . As the temperature increases above the upper critical solution temperature of the P(AAm‐ co ‐AAc) hydrogel, the hydrogen bonds between PAAm and PAAc segments break and they form new hydrogen bonds with water molecules, respectively.…”

Section: Resultsmentioning

confidence: 99%

Bioinspired Bilayer Structural Color Hydrogel Actuator with Multienvironment Responsiveness and Survivability

et al. 2019

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Inspired by the actuator mechanism of Venus flytrap leaves, presented is a bilayer structural color hydrogel actuator by employing a hybrid inverse opal scaffold to join the poly(acrylic acid‐co‐acrylamide) layer and the poly(N‐isopropylacrylamide) layer together. The nanostructure of the inverse opal scaffold imparts the bilayer hydrogel with brilliant structural color, which can show a reversible coloration switch during the structural change. An internal water distribution occurs in the composite bilayer hydrogel during the heating or cooling process because of the opposite thermo‐responsiveness of the two hydrogels. Thus, this intelligent soft material can work in various environments and break the limitation of aqueous media of most structural color hydrogels. In addition, the water transference of the bilayer hydrogel enables the material with bending/unbending deformations and hence a series of complex motions like screwing, catching, and releasing can be achieved. Attractively, with the integrating of graphene oxide, the hydrogel systems can even be imparted with near‐infrared remote responsiveness to both of their color change and 3D deformation. These features of the bioinspired bilayer structural color hydrogel indicate its potential values in a variety of intelligent soft material applications.

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Dual-gradient enabled ultrafast biomimetic snapping of hydrogel materials

Cited by 195 publications

References 36 publications

Gradient Hydrogels—The State of the Art in Preparation Methods

Gradient Hydrogels—The State of the Art in Preparation Methods

Poly(acrylic acid)‐chitosan @ tannic acid double‐network self‐healing hydrogel based on ionic coordination

Bioinspired Bilayer Structural Color Hydrogel Actuator with Multienvironment Responsiveness and Survivability

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