A Stretchable Strain-Insensitive Temperature Sensor Based on Free-Standing Elastomeric Composite Fibers for On-Body Monitoring of Skin Temperature

Trung, Tran Quang; Dang, Thi My Linh; Ramasundaram, Subramaniyan; Toi, Phan Tan; Park, Soo‐Jin; Lee, Nae‐Eung

doi:10.1021/acsami.8b19425

Cited by 157 publications

(117 citation statements)

References 46 publications

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“…The sensor was reproducible with the cycling temperature changes, indicating reliable and stable performances in repeated measurements. The response and recovery time of the sensor were about 4.5 and 12.5 s, respectively, calculated with an exponential fitting model (Figure f) . To test the long‐term stability, the UCNPs‐SPOFs sensor was kept at a constant temperature of 30 °C and the emission spectra were recorded for 4 days ( Figure a).…”

Section: Resultsmentioning

confidence: 99%

“…To meet the requirements of these applications, wearable sensors are required to be flexible, stretchable, and biocompatible so that they can stretch, bend, and twist like skin in long‐term wearing. As such, there has been considerable effort in developing various stretchable materials and structures to achieve a range of wearable devices for monitoring temperature, strain, pressure, and so on.…”

Section: Introductionmentioning

confidence: 99%

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Stretchable and Temperature‐Sensitive Polymer Optical Fibers for Wearable Health Monitoring

Guo

Zhou

Yang

et al. 2019

Adv Funct Materials

167

157

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Stretchable physical sensors that can detect and quantify human physiological signals such as temperature, are essential to the realization of healthcare devices for biomedical monitoring and human-machine interfaces. Despite recent achievements in stretchable electronic sensors using various conductive materials and structures, the design of stretchable sensors in optics remains a considerable challenge. Here, an optical strategy for the design of stretchable temperature sensors, which can maintain stable performance even under a strain deformation up to 80%, is reported. The optical temperature sensor is fabricated by the incorporation of thermal-sensitive upconversion nanoparticles (UCNPs) in stretchable polymer-based optical fibers (SPOFs). The SPOFs are made from stretchable elastomers and constructed in a step-index core/cladding structure for effective light confinements. The UCNPs, incorporated in the SPOFs, provide thermal-sensitive upconversion emissions at dual wavelengths for ratiometric temperature sensing by near-infrared excitation, while the SPOFs endow the sensor with skin-like mechanical compliance and excellent light-guiding characteristics for laser delivery and emission collection. The broad applications of the proposed sensor in real-time monitoring of the temperature and thermal activities of the human body, providing optical alternatives for wearable health monitoring, are demonstrated.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Stretchable and Temperature‐Sensitive Polymer Optical Fibers for Wearable Health Monitoring

Guo

Zhou

Yang

et al. 2019

Adv Funct Materials

167

157

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“…The resistance of the PTL/rGO hybrid coatings shows a negative temperature coefficient behavior (Figure S9, Supporting Information), which indicated that conductivity modulation of the rGO nanosheets with temperature changes is a dominant mechanism rather than conductivity modulation induced by the thermal expansion of the protein matrix. [ 49 ] The high‐conductivity rGO nanosheets enclosed by the hygroscopic protein aggregation network provide a sensitive platform to sense a series of stimuli, typically including moisture and related human breathing monitoring (Figures S10 and S11, Supporting Information), and strain/pressure and related Morse code information transmission (Figure S12, Supporting Information). Unlike pristine rGO, generally having poor biocompatibility, [ 50 ] the protein component endowed the PTL/rGO hybrid coating with good biocompatibility, so that the adhesion and proliferation of HMEC‐1 endothelial cells, a commonly used cell line, on the hybrid coating were much better than those on the pristine rGO film (Figure 3e).…”

Section: Resultsmentioning

confidence: 99%

Controlling Long‐Distance Photoactuation with Protein Additives

Zhao

Miao

et al. 2020

Small

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Long-distance wireless actuation indicates precise remote control over materials, sensors, and devices that are widely utilized in biomedical, defence, disaster relief, deep ocean, and outer space applications to replace human work. Unlike radio frequency (RF) control, which has low tolerance toward electromagnetic interference (EMI), light control represents a promising method to overcome EMI. Nonetheless, long-distance lightcontrolled wireless actuation able to compete with RF control has not been achieved until now due to the lack of highly light-sensitive actuator designs. Here, it is demonstrate that amyloid-like protein aggregates can organize photomodule single-layer reduced graphene oxide (rGO) into a well-defined multilayer stack to display long-distance photoactuation. The amyloid-like proteinaceous component docks the rGO layers together to form a hybrid film, which can reliably adhere onto various material surfaces with robust interfacial adhesion. The sensitive photothermal effect and a fast bending in 1 s to switch a circuit are achieved after forming the film on a plastic substrate and irradiating the bilayer film with a blue laser from 100 m away. A photoactuation distance of 50 km can be further extrapolated based on a commercial high-power laser. This study reveals the great potential of amyloid-like aggregates in remote light control of robots and devices.

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“…They can be sewn into regular fabrics to measure the temperature in different parts of the body or attached to a bandage (Figure h). Through geometric engineering, it is possible to minimize the interference of strain on the temperature response …”

Section: Applicationsmentioning

confidence: 99%

“…Flexible sensors are especially suited for novel applications in healthcare, which are represented by noninvasive, measurement and real‐time monitoring of biophysical and biochemical signals from the human body, such as wrist pulse monitoring, strain measurement, humidity measurement, vibration detection, touch and pressure measurement, electrochemical detection, body temperature measurement, and many others. Table shows the flexible sensors, materials used, their performance, and applications.…”

Section: Introductionmentioning

confidence: 99%

Fabrication and Patterning Methods of Flexible Sensors Using Carbon Nanomaterials on Polymers

Costa

Choi

2020

Advanced Intelligent Systems

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Flexible sensors composed of carbon nanostructures and elastic materials have been developed for healthcare monitoring, environmental monitoring, disposable biochemical or electrochemical sensors, and many other applications. Fabrication approaches for such sensors and their advantages and current issues related to patterning high-performance flexible sensors are reviewed. A focus is placed on patterning techniques for carbon-based flexible sensors including carbon nanotubes, graphene, and other carbon nanostructures. First, novel patterning techniques for nanomaterials are described, along with their current challenges. Next, emerging flexible sensors including humidity, temperature, strain, and pressure sensors are discussed. Finally, the challenges and perspectives for flexible sensors are addressed. REVIEW www.advintellsyst.com

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A Stretchable Strain-Insensitive Temperature Sensor Based on Free-Standing Elastomeric Composite Fibers for On-Body Monitoring of Skin Temperature

Cited by 157 publications

References 46 publications

Stretchable and Temperature‐Sensitive Polymer Optical Fibers for Wearable Health Monitoring

Stretchable and Temperature‐Sensitive Polymer Optical Fibers for Wearable Health Monitoring

Controlling Long‐Distance Photoactuation with Protein Additives

Fabrication and Patterning Methods of Flexible Sensors Using Carbon Nanomaterials on Polymers

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