Highly Stretchable, Adhesive, and Mechanical Zwitterionic Nanocomposite Hydrogel Biomimetic Skin

Yang, Bowen; Yuan, Weizhong

doi:10.1021/acsami.9b14040

Cited by 153 publications

(158 citation statements)

References 48 publications

(69 reference statements)

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“…Flexibility, stretchability and light‐weight of wearable electronics, as the key factors determining the comfort level of users and the portability of devices, have drawn tremendous attention across the world for developing finger/glove sensors with such characteristics 122‐125 . The common flexible strain sensors are normally based on resistive sensing 123,126‐137 or capacitive sensing, 138,139 whose output signals can dynamically respond to the variation of applied force or strain under continuous motions. A finger‐bending strain sensor is presented using stretchable gallium‐based conductors, as indicated in Figure 3C 140 .…”

Section: General Wearable Electronics and Wearable Photonicsmentioning

confidence: 99%

Progress in wearable electronics/photonics—Moving toward the era of artificial intelligence and internet of things

Shi

Dong

et al. 2020

InfoMat

412

233

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The past few years have witnessed the significant impacts of wearable electronics/photonics on various aspects of our daily life, for example, healthcare monitoring and treatment, ambient monitoring, soft robotics, prosthetics, flexible display, communication, human‐machine interactions, and so on. According to the development in recent years, the next‐generation wearable electronics and photonics are advancing rapidly toward the era of artificial intelligence (AI) and internet of things (IoT), to achieve a higher level of comfort, convenience, connection, and intelligence. Herein, this review provides an opportune overview of the recent progress in wearable electronics, photonics, and systems, in terms of emerging materials, transducing mechanisms, structural configurations, applications, and their further integration with other technologies. First, development of general wearable electronics and photonics is summarized for the applications of physical sensing, chemical sensing, human‐machine interaction, display, communication, and so on. Then self‐sustainable wearable electronics/photonics and systems are discussed based on system integration with energy harvesting and storage technologies. Next, technology fusion of wearable systems and AI is reviewed, showing the emergence and rapid development of intelligent/smart systems. In the last section of this review, perspectives about the future development trends of the next‐generation wearable electronics/photonics are provided, that is, toward multifunctional, self‐sustainable, and intelligent wearable systems in the AI/IoT era.

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Section: General Wearable Electronics and Wearable Photonicsmentioning

confidence: 99%

Progress in wearable electronics/photonics—Moving toward the era of artificial intelligence and internet of things

Shi

Dong

et al. 2020

InfoMat

412

233

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“…The functionality of a thermoplastic biodegradable polymer or natural biopolymer with versatile chemical modification has been extensively studied for theranostics and drug delivery. There have been several recent studies exploring the microscopic mechanical properties of these polymers, as well as their cellular functionality and drug delivery [8][9][10][11][12][13]. In particular, modified nanocomposite hydrogels with enhanced mechanical and functional properties have been beneficial in the fields of tissue engineering, medical devices, and depot formulation.…”

Section: Introductionmentioning

confidence: 99%

pH-dependent nanodiamonds enhance the mechanical properties of 3D-printed hyaluronic acid nanocomposite hydrogels

2020

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Nanocomposite hydrogels capable of undergoing manufacturing process have recently attracted attention in biomedical applications due to their desired mechanical properties and high functionality. 3D printing nanocomposite hydrogels of hyaluronic acid (HA)/nanodiamond (ND) revealed that the addition of ND with the low weight ratio of 0.02 wt% resulted in higher compressive force and gel breaking point, compared with HA only nanocomposites. These HA nanocomposite hydrogels loaded with surface functionalized ND allowed for the enforced compressive stress to be tuned in a pH-dependent manner. HA nanocomposite hydrogels with ND-OH at pH 8 showed an increase of 1.40-fold (0.02%: 236.18 kPa) and 1.37-fold (0.04%: 616.72 kPa) the compressive stress at the composition of 0.02 wt% and 0.04 wt, respectively, compared to those of ND-COOH (0.02%: 168.31 kPa, 0.04%: 449.59 kPa) at the same pH. Moreover, the compressive stress of HA/ND-OH (0.04 wt%) at pH 8 was mechanically enhanced 1.29-fold, compared to that of HA/ND-OH (0.04 wt%) at pH 7. These results indicate that the tunable buffering environment and interaction with the long chains of HA at the molecular level have a critical role in the dependency of the mechanical properties on pH. Due to the pH stability of the ND-OH nanophase, filament-based processing and layer-based deposition at microscale attained enforced mechanical properties of hydrogel. Fine surface tuning of the inorganic ND nanophase and controlled 3D printing leads to improved control over the pH-dependent mechanical properties of the nanocomposite hydrogels reported herein.

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“…[ 18–20 ] To address this problem, the ionic conductive hydrogels were developed and investigated recently. [ 21–25,35 ] Yang and Yuan designed a transparent ionic conductive hydrogel, which can be used as wearable skin‐like strain sensors, while it exhibited relatively low tensile stress (0.22 MPa) and compressed stress (<2.0 MPa). [ 25 ] High mechanical performance is highly essential to support tremendous mechanical loads and avoid undesired rupture when the ionic conductive hydrogel is applied in the areas of stretchable sensors and imitated soft tissue.…”

Section: Introductionmentioning

confidence: 99%

“…[ 21–25,35 ] Yang and Yuan designed a transparent ionic conductive hydrogel, which can be used as wearable skin‐like strain sensors, while it exhibited relatively low tensile stress (0.22 MPa) and compressed stress (<2.0 MPa). [ 25 ] High mechanical performance is highly essential to support tremendous mechanical loads and avoid undesired rupture when the ionic conductive hydrogel is applied in the areas of stretchable sensors and imitated soft tissue. [ 26 ] To enhance the mechanical performance, numerous double‐network hydrogels with high strength were fabricated by introducing PVA matrix.…”

Section: Introductionmentioning

confidence: 99%

Highly Strong and Transparent Ionic Conductive Hydrogel as Multifunctional Sensors

Dang

Liu

et al. 2020

Macro Materials & Eng

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Ionic conductive hydrogels as promising materials have become focus of artificial soft tissue or soft stretchable electronic devices. Especially, the next‐generation flexible electronics greatly require achieving multifunction simultaneously. Herein, a transparent hydrogel with high mechanical properties (1.73 MPa for mechanical stress, 630% for mechanical strain) and excellent ionic conductivity is fabricated based on a fully physical cross‐linked network. The stiff long polyvinyl alcohol (PVA) chains as a skeleton to form a “hard” network and the short polyacrylic acid (PAA) chains regard as the “soft” network. Moreover, the biomaterial β‐cyclodextrin (β‐CD) as physical cross‐linkers is used in the “hard–soft” hybrid networks. The construction of “soft and hard” structure is successful to integrate the good transparency, remarkable mechanical properties, and outstanding sensitivity (strain, pressure, pH, and organic solvent) together for assembling multiple sensors, which hold a promising practical development value in the domain of soft wearable electronics and sensing materials in the future.

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Highly Stretchable, Adhesive, and Mechanical Zwitterionic Nanocomposite Hydrogel Biomimetic Skin

Cited by 153 publications

References 48 publications

Progress in wearable electronics/photonics—Moving toward the era of artificial intelligence and internet of things

Progress in wearable electronics/photonics—Moving toward the era of artificial intelligence and internet of things

pH-dependent nanodiamonds enhance the mechanical properties of 3D-printed hyaluronic acid nanocomposite hydrogels

Highly Strong and Transparent Ionic Conductive Hydrogel as Multifunctional Sensors

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