Skin-Inspired Patterned Hydrogel with Strain-Stiffening Capability for Strain Sensors

Cui, Jianbing; Xu, Ruisheng; Dong, Weifu; Kaneko, Tatsuo; Chen, Mingqing; Shi, Dongjian

doi:10.1021/acsami.3c12127

Cited by 5 publications

(3 citation statements)

References 36 publications

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“…According to the working conditions, they can be divided into two types of application areas. The first is the field where the tactile e-skin is attached to the real human skin, − and the second is the field where the tactile e-skin is attached to the surface of bionic human skin. − In fact, the tactile e-skin used in both fields has a high demand for breathability. Currently, there are remarkable application cases of tactile e-skin attached to real skin, − which have different sensing principles, have flexible structures, and are made of functional materials.…”

Section: Introductionmentioning

confidence: 99%

Breathable and Durable Tactile e-Skin Based on S-Shaped Nanofiber Networks by Patterned Additive Manufacturing

Bu,

Song

2024

ACS Appl. Nano Mater.

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Flexible metal-based electrodes with stable resistance and low crack growth rates have important application value in the field of tactile electronic skin, but their breathable performance and durability are at a low level. S-shaped metal nanonetwork electrodes, based on S-shaped nanofiber substrates, are capable of achieving high breathability, excellent electrical properties, and stretch-resistant mechanical properties, simultaneously. Current manufacturing methods of S-shaped nanofiber substrates all suffer from various disadvantages, and they almost all use subtractive fabrications with complex processes and have environmental pollution. Here, in order to prepare durable and breathable tactile e-skin with environmentally friendly, low-cost, and efficient manufacture, a nanofiber-patterned additive manufacturing method is proposed. This additive manufacturing method is based on electrospinning to redesign the collection terminal. Through the design and dimensional optimization of the stacked electrodes, a pronounced electric field gradient forms on the upper surface of the collection terminal. This electric field gradient serves to induce the deposition of nanofibers within the targeted Sshaped pattern area. This one-step additive manufacturing method avoids complex processes, material waste, and chemical pollution, simultaneously enabling nanofibers of S-shaped substrates to have highly integrated structural characteristics. As a result, this durable tactile electronic skin, fabricated by this additive manufacturing method, can achieve sensitive tactile perception while ensuring normal evaporation of sweat on the skin surface and heat dissipation of the body.

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Section: Introductionmentioning

confidence: 99%

Breathable and Durable Tactile e-Skin Based on S-Shaped Nanofiber Networks by Patterned Additive Manufacturing

Bu,

Song

2024

ACS Appl. Nano Mater.

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“…Strain sensors have been designed using strain-stiffening poly(acrylic acid)/poly(acrylamide) hydrogels, which display a deviation from linear viscoelasticity when their stiffness increases upon the application of high strain. 24,25 Strain-stiffening oligo-(ethylene)glycol polyisocyano-peptide hydrogels have also been used as synthetic extracellular matrices; the extent of their strain-stiffening in response to deformations by encapsulated mesenchymal stem cells impacted the differ- entiation of these cells toward osteogenesis or adipogenesis. 3 Additionally, strain-stiffening hydrogels have been engineered to exhibit muscle-like fatigue resistance.…”

Section: Introductionmentioning

confidence: 99%

“…For example, hydrogels exhibiting shear-thinning and self-healing have been engineered and are widely utilized as injectable vehicles for drug delivery and 3D printing. , Shear-thinning and self-healing behaviors are typically a result of dynamic-covalent bonds or noncovalent interactions, such as hydrogen bonding, metal–ligand coordination, host–guest interactions, and hydrophobic interactions. − These relatively weak interactions are disrupted at high shear rates or high strains but reform upon cessation of the mechanical stimulus, allowing for recovery of the initial hydrogel mechanical properties. Strain sensors have been designed using strain-stiffening poly(acrylic acid)/poly(acrylamide) hydrogels, which display a deviation from linear viscoelasticity when their stiffness increases upon the application of high strain. , Strain-stiffening oligo(ethylene)glycol polyisocyano-peptide hydrogels have also been used as synthetic extracellular matrices; the extent of their strain-stiffening in response to deformations by encapsulated mesenchymal stem cells impacted the differentiation of these cells toward osteogenesis or adipogenesis . Additionally, strain-stiffening hydrogels have been engineered to exhibit muscle-like fatigue resistance. − …”

Section: Introductionmentioning

confidence: 99%

Strain-Stiffening Mechanoresponse in Dynamic-Covalent Cellulose Hydrogels

Ollier,

Webber

2024

Biomacromolecules

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Mechanical stimuli such as strain, force, and pressure are pervasive within and beyond the human body. Mechanoresponsive hydrogels have been engineered to undergo changes in their physicochemical or mechanical properties in response to such stimuli. Relevant responses can include strain-stiffening, selfhealing, strain-dependent stress relaxation, and shear rate-dependent viscosity. These features are a direct result of dynamic bonds or noncovalent/physical interactions within such hydrogels. The contributions of various types of bonds and intermolecular interactions to these behaviors are important to more fully understand the resulting materials and engineer their mechanoresponsive features. Here, strain-stiffening in carboxymethylcellulose hydrogels cross-linked with pendant dynamic-covalent boronate esters using tannic acid is studied and modulated as a function of polymer concentration, temperature, and effective cross-link density. Furthermore, these materials are found to exhibit self-healing and strain-memory, as well as strain-dependent stress relaxation and shear rate-dependent changes in gel viscosity. These features are attributed to the dynamic nature of the boronate ester cross-links, interchain hydrogen bonding and bundling, or a combination of these two intermolecular interactions. This work provides insight into the interplay of such interactions in the context of mechanoresponsive behaviors, particularly informing the design of hydrogels with tunable strain-stiffening. The multiresponsive and tunable nature of this hydrogel system therefore presents a promising platform for a variety of applications.

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Structuring and Shaping of Mechanically Robust and Functional Hydrogels toward Wearable and Implantable Applications

Wang,

Xie,

Cao

et al. 2024

Advanced Materials

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Hydrogels possess unique features such as softness, wetness, responsiveness, and biocompatibility, making them highly suitable for biointegrated applications that have close interactions with living organisms. However, conventional man‐made hydrogels are usually soft and brittle, making them inferior to the mechanically robust biological hydrogels. To ensure reliable and durable operation of biointegrated wearable and implantable devices, mechanical matching and shape adaptivity of hydrogels to tissues and organs are essential. Recent advances in polymer science and processing technologies have enabled mechanical engineering and shaping of hydrogels for various biointegrated applications. In this review, we summarize polymer network structuring strategies at micro/nano scales for toughening hydrogels, and further discuss representative mechanical functionalities that exist in biological materials but are not easily achieved in synthetic hydrogels. We review three categories of processing technologies namely 3D printing, spinning, and coating for fabrication of tough hydrogel constructs with complex shapes, and the corresponding hydrogel toughening strategies are also highlighted. These developments enable adaptive fabrication of mechanically robust and functional hydrogel devices, and promote application of hydrogels in the fields of biomedical engineering, bioelectronics and soft robotics.This article is protected by copyright. All rights reserved

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Skin-Inspired Patterned Hydrogel with Strain-Stiffening Capability for Strain Sensors

Cited by 5 publications

References 36 publications

Breathable and Durable Tactile e-Skin Based on S-Shaped Nanofiber Networks by Patterned Additive Manufacturing

Breathable and Durable Tactile e-Skin Based on S-Shaped Nanofiber Networks by Patterned Additive Manufacturing

Strain-Stiffening Mechanoresponse in Dynamic-Covalent Cellulose Hydrogels

Structuring and Shaping of Mechanically Robust and Functional Hydrogels toward Wearable and Implantable Applications

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