Epidermal Patch with Glucose Biosensor: pH and Temperature Correction toward More Accurate Sweat Analysis during Sport Practice

Wiorek, Alexander; Parrilla, Marc; Cuartero, María; Crespo, Gastón A.

doi:10.1021/acs.analchem.0c02211

Cited by 145 publications

(136 citation statements)

References 35 publications

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“…The enzymatic activity of both HRP and GOX can be affected by the pH of sweat, which has been reported to change between 4.5 and 7. 26 To study this, we prepared 3 calibration curves with different glucose dilutions in an artificial sweat matrix adjusted to pH 5, 6 and 7 (Fig. 4C).…”

Section: Analysis Of Potential Interferencesmentioning

confidence: 99%

Detection of low glucose levels in sweat with colorimetric wearable biosensors

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Rica

2021

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Section: Analysis Of Potential Interferencesmentioning

confidence: 99%

Detection of low glucose levels in sweat with colorimetric wearable biosensors

Vaquer

Barón

Rica

2021

Analyst

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“…DOI: 10.1002/adma.202004178 detection mechanisms including optical, capacitive, resistive, geomagnetic, chemical, and thermosensitive, [9][10][11][12][13][14] which possess advantages of high sensitivity and functional diversification. However, a common drawback of them is that external power supply is generally required for their operation.…”

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confidence: 99%

The Triboelectric Nanogenerator as an Innovative Technology toward Intelligent Sports

2021

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In the new era of the Internet‐of‐Things, athletic big data collection and analysis based on widely distributed sensing networks are particularly important in the development of intelligent sports. Conventional sensors usually require an external power supply, with limitations such as limited lifetime and high maintenance cost. As a newly developed mechanical energy harvesting and self‐powered sensing technology, the triboelectric nanogenerator (TENG) shows great potential to overcome these limitations. Most importantly, TENGs can be fabricated using wood, paper, fibers, and polymers, which are the most frequently used materials for sports. Recent progress on the development of TENGs for the field of intelligent sports is summarized. First, the working mechanism of TENG and its association with athletic big data are introduced. Subsequently, the development of TENG‐based sports sensing systems, including smart sports facilities and wearable equipment is highlighted. At last, the remaining challenges and open opportunities are also discussed.

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“…A growing area in medicine, and one of the most promising ones, is bioelectronics electronics. Such medical devices can measure vital parameters of a patient noninvasively, such as heart rate (Asada et al, 2003;Schwartz et al, 2013;Jiang et al, 2019;Coffen et al, 2020), blood pressure (Pang et al, 2015;Wang et al, 2017;Chung, 2019a, 2019b), body temperature (Seungyong Goeckenjan et al, 2020), brain activity (Borisova et al, 2018;Ganesana et al, 2019) and specific biomarkers (pH, glucose, lactate) (Murat et al, 2020;Wiorek et al, 2020), to name a few. These measurements take place in real time, so they can alert individuals and physicians of the situation in order to minimize the decision-making time of a possible or necessary intervention.…”

Section: Bioelectronicsmentioning

confidence: 99%

Flexible Electronics: Status, Challenges and Opportunities

2020

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The concept of flexible electronics has been around for several decades. In principle, anything thin or very long can become flexible. While cables and wiring are the prime example for flexibility, it was not until the space race that silicon wafers used for solar cells in satellites were thinned to increase their power per weight ratio, thus allowing a certain degree of warping. This concept permitted the first flexible solar cells in the 1960s (Crabb and Treble, 1967). The development of conductive polymers (Shirakawa et al., 1977), organic semiconductors, and amorphous silicon (Chittick et al., 1969; Okaniwa et al., 1983) in the following decades meant huge strides toward flexibility and processability, and thus these materials became the base for electronic devices in applications that require bending, rolling, folding, and stretching, among other properties that cannot be fulfilled by conventional electronics (Cheng and Wagner, 2009) (Figure 1). Presently there is great interest in new materials and fabrication techniques which allow for highperformance scalable electronic devices to be manufactured directly onto flexible substrates. This interest has also extended to not only flexibility but also properties like stretchability and healability which can be achieved by utilizing elastomeric substrates with strong molecular interactions (Oh et al., 2016; Kang et al., 2018). Likewise, biocompatibility and biodegradability has been achieved through polymers that do not cause adverse effect to the body and can be broken down into smaller constituent pieces after utilization (Bettinger and Bao, 2010; Irimia-Vladu et al., 2010; Liu H. et al., 2019). This new progress is now enabling devices which can conform to complex and dynamic surfaces, such as those found in biological systems and bioinspired soft robotics. These next-generation flexible electronics open up a wide range of exciting new applications such as flexible lighting and display technologies for consumer electronics, architecture, and textiles, wearables with sensors that help monitor our health and habits, implantable electronics for improved medical imaging and diagnostics, as well as extending the functionality of robots and unmanned aircraft through lightweight and conformable energy harvesting devices and sensors. While conventional electronics are very capable of these functions, flexible electronics are intended to expand the mechanical features to adhere to novel form factors through hybrid strategies, or as standalone solutions where the application does not require high computation power, intended to be highly robust to deformation, low cost, thin, or disposable. The definition of flexibility differs from application to application. From bending and rolling for easier handling of large area photovoltaics, to conforming onto irregular shapes, folding, twisting, stretching, and deforming required for devices in electronic skin, all while maintaining device performance and reliability. While early progress and many important innovations have alre...

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Epidermal Patch with Glucose Biosensor: pH and Temperature Correction toward More Accurate Sweat Analysis during Sport Practice

Cited by 145 publications

References 35 publications

Detection of low glucose levels in sweat with colorimetric wearable biosensors

Detection of low glucose levels in sweat with colorimetric wearable biosensors

The Triboelectric Nanogenerator as an Innovative Technology toward Intelligent Sports

Flexible Electronics: Status, Challenges and Opportunities

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