Highly Stretchable Starch Hydrogel Wearable Patch for Electrooculographic Signal Detection and Human–Machine Interaction

Wan, Shu; Wu, N. J.; Ye, Yizhou; Li, Shunbo; Huang, Haizhou; Chen, Li; Bi, Hengchang; Sun, Litao

doi:10.1002/sstr.202100105

Cited by 21 publications

(24 citation statements)

References 65 publications

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“…The biodegradability of a polymer is primarily due to the principle of releasing polymer-binding chains through various microorganisms, water, and biofluids. In addition, naturally extractable guar gum [ 18 ], gelatin [ 118 ], starch [ 119 ], and fabric [ 120 , 121 ] have been adopted for achieving green electrophysiological devices, by fabricating biodegradable polymers. Furthermore, research is underway to improve parameters such as the conductivity, biocompatibility, and stability of biodegradable polymers.…”

Section: Electrophysiological Signal Sensingmentioning

confidence: 99%

“…The biodegradability of a polymer is primarily due to the principle of releasing polymer-binding chains through various microorganisms, water, and biofluids. In addition, naturally extractable guar gum [18], gelatin [118], starch [119], and fabric [120,121] have been adopted for achieving green (d) EEG waveform of alpha and beta waves (adapted from [115] with permission from John Wiley and Sons); (e) swelling rate and degradation rate of conduct polymer coatings (adapted from [116] with permission from the Elsevier B.V.).…”

Section: Biodegradability Evaluation Of Polymersmentioning

confidence: 99%

Section: Biodegradability Evaluation Of Polymersmentioning

confidence: 99%

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Biodegradable Polymer Composites for Electrophysiological Signal Sensing

2022

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Electrophysiological signals are collected to characterize human health and applied in various fields, such as medicine, engineering, and pharmaceuticals. Studies of electrophysiological signals have focused on accurate signal acquisition, real-time monitoring, and signal interpretation. Furthermore, the development of electronic devices consisting of biodegradable and biocompatible materials has been attracting attention over the last decade. In this regard, this review presents a timely overview of electrophysiological signals collected with biodegradable polymer electrodes. Candidate polymers that can constitute biodegradable polymer electrodes are systemically classified by their essential properties for collecting electrophysiological signals. Moreover, electrophysiological signals, such as electrocardiograms, electromyograms, and electroencephalograms subdivided with human organs, are discussed. In addition, the evaluation of the biodegradability of various electrodes with an electrophysiology signal collection purpose is comprehensively revisited.

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Section: Electrophysiological Signal Sensingmentioning

confidence: 99%

“…The biodegradability of a polymer is primarily due to the principle of releasing polymer-binding chains through various microorganisms, water, and biofluids. In addition, naturally extractable guar gum [18], gelatin [118], starch [119], and fabric [120,121] have been adopted for achieving green (d) EEG waveform of alpha and beta waves (adapted from [115] with permission from John Wiley and Sons); (e) swelling rate and degradation rate of conduct polymer coatings (adapted from [116] with permission from the Elsevier B.V.).…”

Section: Biodegradability Evaluation Of Polymersmentioning

confidence: 99%

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Biodegradable Polymer Composites for Electrophysiological Signal Sensing

2022

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“…Due to the development of these technologies and 3D printing, designing wearable platforms has become possible, such as eyeglass types [ 5 , 31 , 32 , 33 , 34 , 35 , 36 , 37 , 38 , 39 ], face mask types [ 7 , 40 , 41 , 42 ], ear plug types [ 43 , 44 , 45 , 46 , 47 ], and headband types [ 48 , 49 , 50 , 51 , 52 , 53 , 54 , 55 , 56 , 57 , 58 ] for various applications. Previously, various controllers for an HMI such as wheelchairs [ 1 , 4 , 51 , 52 ], drones [ 11 , 59 ], game interfaces [ 5 , 36 , 47 , 60 , 61 ], and virtual keyboards [ 34 , 38 , 51 , 62 ] were created by using only an EOG signal. Recently, various healthcare monitoring systems [ 7 , 40 , 41 ,…”

Section: Introductionmentioning

confidence: 99%

Advances in Materials, Sensors, and Integrated Systems for Monitoring Eye Movements

et al. 2022

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Eye movements show primary responses that reflect humans' voluntary intention and conscious selection. Because visual perception is one of the fundamental sensory interactions in the brain, eye movements contain critical information regarding physical/psychological health, perception, intention, and preference. With the advancement of wearable device technologies, the performance of monitoring eye tracking has been significantly improved. It also has led to myriad applications for assisting and augmenting human activities. Among them, electrooculograms, measured by skin-mounted electrodes, have been widely used to track eye motions accurately. In addition, eye trackers that detect reflected optical signals offer alternative ways without using wearable sensors. This paper outlines a systematic summary of the latest research on various materials, sensors, and integrated systems for monitoring eye movements and enabling human-machine interfaces. Specifically, we summarize recent developments in soft materials, biocompatible materials, manufacturing methods, sensor functions, systems' performances, and their applications in eye tracking. Finally, we discuss the remaining challenges and suggest research directions for future studies.

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Up to now, tactile sensors have made significant breakthroughs with novel features such as stretchable, [5][6][7] self-healing, [8,9] self-powered, [10,11] and multi-functional properties. [12][13][14] Most of these tactile sensors must require battery storage to provide energy if they continuously collect information.

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mentioning

confidence: 99%

Fully Fibrous Large‐Area Tailorable Triboelectric Nanogenerator Based on Solution Blow Spinning Technology for Energy Harvesting and Self‐Powered Sensing

Tao

Liu

et al. 2022

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An all‐fibrous large‐area (20 × 50 cm2) tailorable triboelectric nanogenerator (LT‐TENG) is prepared using a one‐step solution blow spinning technology, which has the advantages of easy operation, scale‐up in the area, and high production efficiency. The prepared LT‐TENG is composed of polyvinylidene fluoride (PVDF)/MXene (Ti3C2Tx) nanofibers (NFs) and conductive textile. Benefiting from the fibrous materials and large‐area properties, the LT‐TENG possesses the merits of good tailorability, breathability, hydrophobicity, and washability. When optimized by mixing the MXene into PVDF NFs, the LT‐TENG has a preferable output and sensing property, with a detection range over 16 kPa and a relatively high sensitivity of 12.33 V KPa−1. At maximum applied pressure, the voltage, current, and charge are 108 V, 38 µA, and 35 nC, respectively. This LT‐TENG can serve as a biomechanical energy harvester when used as wearable devices with an output power density of 12.6 mW m−2 at an external load resistance of 500 MΩ, and it also has the ability of self‐powered tactile sensing for pressure mapping and slide sensing. Thus, this LT‐TENG exhibits great potential prospects in wearable devices, intelligent robots, and human–machine interaction.

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Highly Stretchable Starch Hydrogel Wearable Patch for Electrooculographic Signal Detection and Human–Machine Interaction

Cited by 21 publications

References 65 publications

Biodegradable Polymer Composites for Electrophysiological Signal Sensing

Biodegradable Polymer Composites for Electrophysiological Signal Sensing

Advances in Materials, Sensors, and Integrated Systems for Monitoring Eye Movements

Fully Fibrous Large‐Area Tailorable Triboelectric Nanogenerator Based on Solution Blow Spinning Technology for Energy Harvesting and Self‐Powered Sensing

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