Self-Assembled Porous-Reinforcement Microstructure-Based Flexible Triboelectric Patch for Remote Healthcare

Lei, Hao; Ji, Haifeng; Liu, Xiaohan; Lu, Bohan; Xie, Lin‐Jie; Lim, Eng Gee; Tu, Xin; Liu, Yina; Zhang, Peixuan; Zhao, Chun; Sun, Xuhui; Wen, Zhen

doi:10.1007/s40820-023-01081-x

Cited by 13 publications

(7 citation statements)

References 33 publications

(34 reference statements)

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“…Moreover, the sensor’s structural design is critical to improving its linearity and pressure sensing range. Previously, micropatterned , and porous − microstructures have been effectively employed to enhance the sensing performance of the tactile sensor. The interlocked structures are widely adopted in micropatterned sensors.…”

Section: Introductionmentioning

confidence: 99%

Underwater Gesture Recognition Meta-Gloves for Marine Immersive Communication

Liu,

Wang,

et al. 2024

ACS Nano

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Rapid advancements in immersive communications and artificial intelligence have created a pressing demand for high-performance tactile sensing gloves capable of delivering high sensitivity and a wide sensing range. Unfortunately, existing tactile sensing gloves fall short in terms of user comfort and are ill-suited for underwater applications. To address these limitations, we propose a flexible hand gesture recognition glove (GRG) that contains highperformance micropillar tactile sensors (MPTSs) inspired by the flexible tube foot of a starfish. The as-prepared flexible sensors offer a wide working range (5 Pa to 450 kPa), superfast response time (23 ms), reliable repeatability (∼10000 cycles), and a low limit of detection. Furthermore, these MPTSs are waterproof, which makes them well-suited for underwater applications. By integrating the high-performance MPTSs with a machine learning algorithm, the proposed GRG system achieves intelligent recognition of 16 hand gestures under water, which significantly extends real-time and effective communication capabilities for divers. The GRG system holds tremendous potential for a wide range of applications in the field of underwater communications.

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Section: Introductionmentioning

confidence: 99%

Underwater Gesture Recognition Meta-Gloves for Marine Immersive Communication

Liu,

Wang,

et al. 2024

ACS Nano

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“…The development of flexible electronics has further increased the sensitivity and sensing range of flexible sensors, which can sense external stimuli and convert external mechanical strains into visual electrical signals. − Flexible sensors are already widely used in various intelligent devices such as soft robots, electronic skins, and personalized medicine. − Materials commonly used for flexible sensors include polydimethylsiloxane, polyurethane, and hydrogels. − Compared to other materials, hydrogels have a higher water content and can mimic the stretchable, mechanical, and optical properties of natural soft tissue, making them suitable for a wider range of applications. , Therefore, it is particularly important to develop hydrogel sensors with high performance, high conductivity, and multifunctionality.…”

Section: Introductionmentioning

confidence: 99%

Multifunctional, Self-Adhesive MXene-Based Hydrogel Flexible Strain Sensors for Hand-Written Digit Recognition with Assistance of Deep Learning

Zhang,

Luan

et al. 2023

Langmuir

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The conductive hydrogel as a flexible sensor not only has certain mechanical flexibility but also can be used in the field of human health detection and human−computer interaction. Herein, by introduction of tannic acid (TA) with MXene into the polyacrylamide (PAM)/carboxymethyl chitosan (CMC) doublenetwork hydrogel, a hydrogel with high stretchability, self-adhesion, and high sensitivity was prepared. CMC and PAM form a semiinterpenetrating double-network of high toughness and durability through electrostatic interactions and multiple hydrogen bonding networks. The abundant hydrophilic functional groups on TA and MXene form multiple hydrogen bonds simultaneously with the polymer network, ensuring high stretchability and sensitivity of the hydrogel. The hydrogel can display an accurate response to a variety of stimulus signals and can monitor both human joint movements and small physiological signal changes. It can also be combined with deep learning algorithms to classify handwritten digits with an accuracy rate of 98%. This work can promote the application of hydrogel sensors with durability and high sensitivity. The combination of algorithms and flexible sensors provides important ideas for the further development of flexible devices.

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“…However, recent studies reported that the bending condition of CDBD could affect the discharge [28]. The wearable plasma source was proposed which could be used to treat the large area with irregular shapes [29][30][31]. However, the areas that do not need to be treated still should be driven by the power supply, leading to the high demand for the driven source.…”

Section: Introductionmentioning

confidence: 99%

A 3D-printed fence-surface plasma source for skin treatment and its potential for personalized medical application

Zhao,

Liu,

Liu

et al. 2023

J. Phys. D: Appl. Phys.

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A 3D-printed fence-surface electrode that has the potential for personalized medical application is fabricated in this study. The framework of the 3D-printed fence electrode could be any shape to fit the outline of the target. Here, the fence electrode with an area of 50 × 50 mm is made as an example to study the discharge characteristic and the affecting factors (number of bars and the curvature of the electrode). The results show that more bars of the fence electrode with the same area will have a larger discharge current and a more uniform glowing area, which is consistent with the numerical results. When introducing the human load, it will not affect the original discharge between the fence and the ground electrodes but will add discharging channels between the fence electrode and the human load when the load contacts the fence electrode. In the worst case, the maximum root-mean-square of the discharge current flowing through the human model is 5.9 mA, which is still lower than the safety thresholds. The highest temperature rise on the surface of the fence electrode is 35.226.55 °C at the condition of 15 bars for 7 kV, 3 min running. It needs a 60 s treatment for Escherichia coli and Staphylococcus aureus to get a sterilization rate of 99.99% while it needs about 180 s treatment for Pseudomonas aeruginosa to get the same rate. Finally, the procedure for designing a personalized fence-surface plasma source is illustrated and the electrodes used to fit the calf and heel are made. The discharge of the personalized fence-electrode is stable and could be used in personalized plasma medicine in the future.

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Self-Assembled Porous-Reinforcement Microstructure-Based Flexible Triboelectric Patch for Remote Healthcare

Cited by 13 publications

References 33 publications

Underwater Gesture Recognition Meta-Gloves for Marine Immersive Communication

Underwater Gesture Recognition Meta-Gloves for Marine Immersive Communication

Multifunctional, Self-Adhesive MXene-Based Hydrogel Flexible Strain Sensors for Hand-Written Digit Recognition with Assistance of Deep Learning

A 3D-printed fence-surface plasma source for skin treatment and its potential for personalized medical application

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