Barnacle Cement Proteins‐Inspired Tough Hydrogels with Robust, Long‐Lasting, and Repeatable Underwater Adhesion

Fan, Hailong; Wang, Jiahui; Gong, Jian Ping

doi:10.1002/adfm.202009334

Cited by 191 publications

(177 citation statements)

References 45 publications

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“…The monomer sequence also had a strong impact on the underwater adhesion of the hydrogels (Figure 9). The tack test shows that P(cation-adj-π) hydrogels exhibit strong adhesion to negatively charged glass in saltwater (0.7 M NaCl) because the aromatic groups can enhance the electrostatic interactions of their adjacent cationic residues with the counter surfaces in high ionic media [15,22]. In contrast, the P(cation-co-π) hydrogels, which lack adjacent cationic-aromatic sequences, exhibit weak adhesion on the glass substrate in saltwater.…”

Section: Adhesion Performance Of Hydrogels In Saltwatermentioning

confidence: 99%

Facile tuning of hydrogel properties by manipulating cationic-aromatic monomer sequences

2021

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Copolymer hydrogels formed from cationic and aromatic monomers with identical monomer compositions but different average sequences were synthesized by free-radical copolymerization in various solvents. We found that hydrogels with one-componentrich segments are mechanically stronger than those with adjacent-rich monomer sequences in water, while hydrogels with a rich cation-π adjacent sequence showed excellent mechanical strength and underwater adhesion in saltwater (0.7 M NaCl). The molecular mechanisms for these behaviors are discussed in terms of polymer structures. This work reveals the importance of monomeric sequences in determining hydrogel properties and provides a facile approach to develop hydrogels with different properties but the same monomer composition.

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Section: Adhesion Performance Of Hydrogels In Saltwatermentioning

confidence: 99%

Facile tuning of hydrogel properties by manipulating cationic-aromatic monomer sequences

2021

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“…Furthermore, in wet environment, the interfacial adhesion may be weakened by the occurrence of water at the device–skin interface, leading to potential device delamination and further inferior reliability of the acquired data. [ 13,14 ] Therefore, it is highly desirable to develop environmentally compatible hydrogel electronics owning thermal compatibility (capability at subzero and elevated temperatures) and hydration compatibility (capability at dehydrated and hydrated environments) for extended applications.…”

Section: Introductionmentioning

confidence: 99%

Environmentally Compatible Wearable Electronics Based on Ionically Conductive Organohydrogels for Health Monitoring with Thermal Compatibility, Anti‐Dehydration, and Underwater Adhesion

Niu

Liu

et al. 2021

Small

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Hydrogel‐based electronics have found widespread applications in soft sensing and health monitoring because of their remarkable biocompatibility and mechanical features similar to human skin. However, they are subjected to potential challenges like structural failure, functional degradation, and device delamination in practical applications, especially facing extreme environmental conditions (e.g., abnormal temperature and humidity). To address these, ionically conductive organohydrogel‐based soft electronics are developed, which can perform at subzero and elevated temperatures (thermal compatibility) as well as at dehydrated and hydrated environments (hydration compatibility) for extended applications. More specifically, gelatin/poly(acrylic acid–N‐hydrosuccinimide ester) (PAA–NHS ester)‐based ionic‐conductive organohydrogel is synthesized. By introducing a glycerol–water binary solvent system, the gel can maintain mechanical softness in a wide temperature range (from −80 to 60 °C). Besides, excellent conductivity is achieved under various conditions by soaking the gel into lithium chloride anhydrous (LiCl) solution. Strong adhesion with skin, even under water, can be realized by covalent bonds between NHS ester from gel and amino groups from human skin. The excellent performances of LiCl‐loaded PAA‐based organohydrogel (L‐PAA‐OH)‐based electronics are further demonstrated under freezing and high temperatures as well as underwater conditions, unveiling their promising prospects in wearable health monitoring in various conditions.

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“…The strong adhesion and super-slip surface properties of hydrogels have attracted great interest of research. According to Hailong Fan et al [14], a novel hydrogel for instant adhesion and reversibility (50 times) with strong adhesion strength (180 kPa), hydrophobic, positively charged in water is designed and synthesized by cationic and aromatic monomers, which can firmly adhere to diverse surfaces through interfacial electrostatic and hydrophobic interactions.…”

Section: Introductionmentioning

confidence: 99%

Contact Friction Regulation of the UV Laser Textured PVA Hydrogel and Titanium Alloy Interface

Zhou

Liu

Zhu

et al. 2021

Preprint

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The soft, hydrophilic and smooth surface of hydrogel displays extremely complex friction behavior. In this work, the ultraviolet laser post-processing created PVA hydrogel surface textures is found to be a one-step effective way for the contact friction regulation at the hydrogel-titanium alloy interface. Micro-grooves with various spacings and depths are fabricated by adjusting the laser scanline interval, laser energy density and the scanning times. Friction torques are measured by a strain-controlled parallel-plate rheometer to characterize frictional behaviors of micro-grooves. At the sliding velocity range of 0.085mm/s < v < 2.3mm/s, the effect of interlocking and ploughing force are the dominant origins of friction. Frictional stress increases with the decrease of the micro-groove spacing, but not with the increase of the micro-groove depth, which indicates that frictional stress doesn’t simply increase with an increase of hydrogel’s roughness. As the velocity increases from 2.3mm/s to 100mm/s, the surface wettability of textured hydrogel plays an important role in regulating friction. Both smooth hydrogel and laser textured hydrogels show stick-slip phenomenon which occurs in the same velocity range. These results take us a step closer to deriving a more effective, accurate, and dependable guideline for designing laser-textured surface grooves for sliding friction control of hydrogel applications.

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Barnacle Cement Proteins‐Inspired Tough Hydrogels with Robust, Long‐Lasting, and Repeatable Underwater Adhesion

Cited by 191 publications

References 45 publications

Facile tuning of hydrogel properties by manipulating cationic-aromatic monomer sequences

Facile tuning of hydrogel properties by manipulating cationic-aromatic monomer sequences

Environmentally Compatible Wearable Electronics Based on Ionically Conductive Organohydrogels for Health Monitoring with Thermal Compatibility, Anti‐Dehydration, and Underwater Adhesion

Contact Friction Regulation of the UV Laser Textured PVA Hydrogel and Titanium Alloy Interface

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