Stretchable, Skin‐Mountable, and Wearable Strain Sensors and Their Potential Applications: A Review

Amjadi, Morteza; Kyung, Ki-Uk; Park, Inkyu; Sitti, Metin

doi:10.1002/adfm.201504755

Cited by 2,395 publications

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“…[5][6][7][8] Although many stretchable conductors exist, including liquid metals, [9,10] nanowires, [11,12] nanoribbons [13] , pre-stretched elastomer fibers with conductive coatings, [14] and micro-cracked metals, [15,16] these materials have generally been unable to achieve high levels of optical transparency while maintaining high conductivities and stretchability; a feature that would enable their use in optogenetics [17] or allow optical imaging of the underlying substrate. Conventional strategies of incorporating metallic components with elastomers to attain stretchability also yield non-trivial failure modes such as liquid metal leakage [8] and hard-soft material interfacial failure [18] .…”

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confidence: 99%

“…If the field is to progress, advanced manufacturing techniques that integrate dielectric elastomers and hydrogels need to be developed. [7] Fabrication techniques specific to hydrogels have already been developed, including extrusion three-dimensional (3D) printing, [24,[32][33][34][35] digital projection based techniques, [36] and screen printing [37,38] . Extrusion printing techniques in particular are most easily capable of multi-material printing at high resolution and low costs.…”

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3D Printing of Transparent and Conductive Heterogeneous Hydrogel–Elastomer Systems

et al. 2017

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A hydrogel–dielectric‐elastomer system, polyacrylamide and poly(dimethylsiloxane) (PDMS), is adapted for extrusion printing for integrated device fabrication. A lithium‐chloride‐containing hydrogel printing ink is developed and printed onto treated PDMS with no visible signs of delamination and geometrically scaling resistance under moderate uniaxial tension and fatigue. A variety of designs are demonstrated, including a resistive strain gauge and an ionic cable.

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3D Printing of Transparent and Conductive Heterogeneous Hydrogel–Elastomer Systems

et al. 2017

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“…[41] Capacitive strain sensors possess good linearity with low hysteresis, fast response, and are less susceptible to overshoot and creep. [107] While capacitive strain sensors exhibit smaller GFs than the resistive strain sensors, they are ideal for applications where the strain is relatively large. In addition, the GFs of capacitive strain sensors remain constant in the entire strain range.…”

Section: Capacitive Strain Sensorsmentioning

confidence: 99%

“…While most resistive strain sensors exhibit large stretchability and high sensitivity, many suffer from nonlinear response, large hysteresis, and irreversibility. [107] When the applied strain is released, it is difficult for the nanomaterials to slide back to the initial position or for the cracks to be completely closed. Due to the viscoelasticity of polymers and the friction between the nanomaterials and the polymer matrix during loading and unloading, rearrangement of nanomaterials Polyaniline doped AuNW/Latex rubber [68] Resistive 2-12 for 0-100% 149.6% -Human finger-controlled robotic arm system AuNW/Latex rubber [44] Resistive 9.9 (0-5%), 6.9 (5-50%) 300% 0.01% Data glove, monitoring of forearm muscle movement, cheek movement, phonation, and wrist pulse AgNW/Ecoflex/AgNW [41] Capacitive 0.7 50% -Monitoring of finger bending and knee motion CNT/Ecoflex/CNT [25] Capacitive 0.4 50% --CNT/silicone/CNT [127] Capacitive 0.99 100% -Robotic linkage CNT/Dragon Skin/CNT [129] Capacitive 1 300% -Date glove, monitoring of balloon inflation and chest movement PVDF-TrFE with graphene FET [134] Piezoelectric 389 ≈0.3% 0.008% Monitoring of hand movement ZnO NW array [132] Piezoelectric 1813 0.8% --Carbon fiber-ZnO NW [217] Piezoelectric 60-80 1.2% 0.2% -www.advancedsciencenews.com www.advhealthmat.…”

Section: Resistive Strain Sensorsmentioning

confidence: 99%

“…For strain sensors based on nanomaterial composites, the resistance change originates from four mechanisms: (1) the change in the geometry of the nanomaterials themselves and the composites; (2) change in resistivity of nanomaterial fillers due to the intrinsic piezoresistive effect (second term in Equation (1)); (3) strain induced separation of neighboring nanomaterials and the resulting modified tunneling resistance for nanomaterials not electrically conducting with each other; [105,106] (4) decreased number of percolation pathways between nanomaterials, mainly due to disconnection (or sliding) between nanomaterials or propagation of microcracks under strain, which leads to increased contact resistance. [107] Separation and/or sliding of nanomaterials under strain (especially large strain) results in small strain experienced by the nanomaterials themselves. In this case the resistance change due to the first two mechanisms is relatively small, while that due to the last two mechanisms becomes dominant.…”

Section: Resistive Strain Sensorsmentioning

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Nanomaterial‐Enabled Wearable Sensors for Healthcare

Yao

Swetha

Zhu

2017

Adv Healthcare Materials

429

273

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humidity level, and concentration of harmful gases, and airborne particulates can provide valuable information for the prediction, management, and treatment of chronic diseases. [4,5] In addition to the applications in wearable health monitoring, continuous tracking of daily and sports activities can offer an efficient way to assess the well-being and athletic performances. [6] In order to ensure a robust and conformal contact with the curvilinear, coarse, and dynamic surface of skin without impeding daily activities, the wearable sensor should have low modulus and high stretchability. The epidermis has a modulus of 140-600 kPa while the dermis has an even lower modulus of 2-80 kPa. [7] Skin itself can be stretched elastically up to 15% and with the help of wrinkles and creases, the overall stretchability can reach as high as 100% during daily motions. [8] In addition to good wearability, wearable sensors should be highly sensitive, lightweight, low-cost, and with low power consumption. To achieve these features, nanomaterials that are compliant, possessing larger surface area and exceptional material properties, and compatible with low-cost fabrication processes are widely employed as building blocks for developing wearable sensors.In this review, we start from a brief overview of nanomaterials, their related structural designs and fabrication processes (Section 2). Following that, recent advances of nanomaterialenabled wearable sensors including temperature, electrophysiological, strain, tactile, electrochemical, and other sensors will be summarized (Section 3). A survey on the integration of multiple sensors and other components into wearable systems will be given in Section 4. The application of nanomaterialenabled wearable sensors for healthcare including health monitoring, activity tracking, and electronic skin will be presented in Section 5. The challenges and opportunities will be discussed at the end. Nanomaterials, Structural Designs, and Fabrication ProcessesNanomaterials can be classified into two categories-top-down fabricated ones and bottom-up synthesized ones. [9] The focus of this review is on the wearable sensors based on bottom-up synthesized nanomaterials. Nanomaterials can be synthesized into various dimensions, from 0D such as metallic nanoparticles (NPs), to 1D such as carbon nanotubes (CNTs), and metallic nanowires (NWs), to 2D such as graphene and transition metal Highly sensitive wearable sensors that can be conformably attached to human skin or integrated with textiles to monitor the physiological parameters of human body or the surrounding environment have garnered tremendous interest. Owing to the large surface area and outstanding material properties, nanomaterials are promising building blocks for wearable sensors. Recent advances in the nanomaterial-enabled wearable sensors including temperature, electrophysiological, strain, tactile, electrochemical, and environmental sensors are presented in this review. Integration of multiple sensors for multimodal sensing and integration with...

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Appendix A Antennas and Sensors for Medical Applications: A Representative Literature Review

Song¹,

Rahmat‐Samii²

2021

Antenna and Sensor Technologies in Modern Medical Applications

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Advanced wireless diagnosis and treatment technologies have recently and rapidly moved from largely a vision of science fiction to widely spreading consumer and clinical products. Large numbers of research and literature are published in different journals and conferences each year on the development of antennas and sensors of various health-care applications. This chapter presents a representative literature review on the recently developed antenna and sensor technologies for advanced medical applications. A block diagram summarizing the subtopics included in this review chapter is shown in Figure A.1. The antenna-related topics are broken into three subsections according to their operating mechanisms: medical imaging antennas and coils, wireless telemetry antennas for implantable and ingestible devices, and microwave ablation antennas for localized tumor treatments. The discussion on sensor technologies consists of mechanical, electrical, optical, and chemical sensing devices. For each of the subtopics, we present the basic system-level physics, followed by the state of the art with representative literature, general outlooks for current challenges, and potential solutions in each field. This review not only serves as an introductory platform for new researchers to the fields but also benefits experienced researchers by broadening their views among various related topics. Various chapters of this book provide in-depth discussions with additional references, detailing the topics briefly covered in this appendix.

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Stretchable, Skin‐Mountable, and Wearable Strain Sensors and Their Potential Applications: A Review

Cited by 2,395 publications

References 148 publications

3D Printing of Transparent and Conductive Heterogeneous Hydrogel–Elastomer Systems

3D Printing of Transparent and Conductive Heterogeneous Hydrogel–Elastomer Systems

Nanomaterial‐Enabled Wearable Sensors for Healthcare

Appendix A Antennas and Sensors for Medical Applications: A Representative Literature Review

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