Fully integrated wearable sensor arrays for multiplexed in situ perspiration analysis
Wei Gao,Wei Gao,Sam Emaminejad,Sam Emaminejad,Sam Emaminejad,Hnin Yin Yin Nyein,Hnin Yin Yin Nyein,Samyuktha Challa,Kevin Chen,Kevin Chen,Austin J Peck,Hossain M. Fahad,Hossain M. Fahad,Hiroki Ota,Hiroki Ota,Hiroshi Shiraki,Hiroshi Shiraki,Daisuke Kiriya,Daisuke Kiriya,Der Hsien Lien,George A. Brooks,Ronald W. Davis,Ali Javey,Ali Javey +23 more
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TLDR
This work bridges the technological gap between signal transduction, conditioning, processing and wireless transmission in wearable biosensors by merging plastic-based sensors that interface with the skin with silicon integrated circuits consolidated on a flexible circuit board for complex signal processing.Abstract:
Wearable sensor technologies are essential to the realization of personalized medicine through continuously monitoring an individual's state of health. Sampling human sweat, which is rich in physiological information, could enable non-invasive monitoring. Previously reported sweat-based and other non-invasive biosensors either can only monitor a single analyte at a time or lack on-site signal processing circuitry and sensor calibration mechanisms for accurate analysis of the physiological state. Given the complexity of sweat secretion, simultaneous and multiplexed screening of target biomarkers is critical and requires full system integration to ensure the accuracy of measurements. Here we present a mechanically flexible and fully integrated (that is, no external analysis is needed) sensor array for multiplexed in situ perspiration analysis, which simultaneously and selectively measures sweat metabolites (such as glucose and lactate) and electrolytes (such as sodium and potassium ions), as well as the skin temperature (to calibrate the response of the sensors). Our work bridges the technological gap between signal transduction, conditioning (amplification and filtering), processing and wireless transmission in wearable biosensors by merging plastic-based sensors that interface with the skin with silicon integrated circuits consolidated on a flexible circuit board for complex signal processing. This application could not have been realized using either of these technologies alone owing to their respective inherent limitations. The wearable system is used to measure the detailed sweat profile of human subjects engaged in prolonged indoor and outdoor physical activities, and to make a real-time assessment of the physiological state of the subjects. This platform enables a wide range of personalized diagnostic and physiological monitoring applications.read more
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An IoT-Based Computational Framework for Healthcare Monitoring in Mobile Environments
TL;DR: A distributed framework based on the internet of things paradigm is proposed for monitoring human biomedical signals in activities involving physical exertion, with main advantages and novelties the flexibility in computing the health application by using resources from available devices inside the body area network of the user.
Journal ArticleDOI
Recent Developments in Graphene-Based Tactile Sensors and E-Skins
Abstract: DOI: 10.1002/admt.201700248 intelligence, healthcare monitoring, artificial prosthesis, and human–machine interaction electronics.[1–4] Human skin, served as the largest sensory organ in human body, can help us communicate with surroundings such as the contacted pressures, changed temperatures, shapes, and textures of touched objects, via the specialized sense receptors.[5,6] For an intact haptic system, the collected information will be sent to the central nervous systems for comprehending and processing the meaning of the received information, and then our body will be guided to respond to the physical contact successfully. To imitate the sophisticated perception of human skin, various kinds of functional electronic devices which can sense and distinguish external physical, chemical, and biological signals simultaneously are integrated in a flexible or elastic system likes human skin. The functional electronic devices including pressure sensor, temperature sensor, and humidity sensor[7–9] have the ability to transfer the generated information from physical signals into electrical signals that electronic devices can recognize.[10–12] However, there remains enormous challenges to construct E-skins with multimodal detection, fleet response, high sensitivity and resolution, even though much research has been reported on the imitation of human skin behaviors recently. The rise of E-skins in early years may be resulted from the inspiration of science fiction and movies, which builds a bridge between virtual imagination and scientific reality. Since a prosthetic hand with tactile feedback was demonstrated by Clippinger et al. in 1974,[13] several studies have been followed to explore the potential application of tactile bionics.[14–16] Especially, flexible electronics achieved significant progress which served as a foundation to construct E-skins, due to the particular importance of mechanical compliance and highly sensitive characteristics in mimicking human skin.[17–21] For examples, Rogers and co-workers developed flexible electronics technologies to transfer traditional Si electronic devices onto 100 nm ultrathin films connected by stretchable interconnects.[22,23] Someya and co-workers integrated a large-scale organic fieldeffect transistors (FETs) based on flexible pentacene which showed excellent pressure sensitivity.[24] Bao and coworkers developed novel self-healing and mechanical force sensing E-skins with microstructured elastomeric dielectrics.[25–27] In addition, piezoresistive, capacitive, and piezoelectric sensors are deemed as three major transduction mechanisms for the Human skin, the largest organ of human body, can perceive tactile sensations, temperature, humidity, and other complex environmental stimulations. To mimic the capabilities of human skin, graphene provides great potential in building wearable electronic skins (E-skins), which hold broad applications in advanced robotics, healthcare monitoring, artificial intelligence, human– machine interfaces, etc. Herein, the recent progress in flexible tactile sensors and E-skins based on graphene material is presented. A brief introduction of the main approaches to prepare graphene nanosheets is provided. The main developments on the functions and mechanisms of bionic functional devices in E-skins including tactile sensors, temperature sensors, and humidity sensors are then highlighted. The current and future applications for graphenebased E-skins, such as multifunctional biomimetic E-skins, healthcare monitoring, and interactive human–machine interface, are also described. Finally, the existing challenges and future development trends for graphenebased E-skins are discussed.
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Inorganic semiconducting materials for flexible and stretchable electronics
TL;DR: In this article, a review summarizes some recent progress in flexible electronics based on inorganic semiconductor nanomaterials, the key associated design strategies and examples of device components and modules with utility in biomedicine.
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Printable Fabrication of a Fully Integrated and Self-Powered Sensor System on Plastic Substrates
Yuanjing Lin,Jiaqi Chen,Mohammad Mahdi Tavakoli,Yuan Gao,Yudong Zhu,Yudong Zhu,Daquan Zhang,Matthew Kam,Zhubing He,Zhiyong Fan +9 more
TL;DR: A monolithically integrated self-powered smart sensor system with printed interconnects, printed gas sensor for ethanol and acetone detection, and printable supercapacitors and embedded solar cells as energy sources is successfully demonstrated in a wearable wristband fashion by utilizing inkjet printing as a proof of concept.
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Emerging Telemedicine Tools for Remote COVID-19 Diagnosis, Monitoring, and Management.
TL;DR: Current implementations of mHealth sensors for COVID-19 are summarized, recent technological advances are highlighted, and an overview on how these tools may be utilized to better control the CO VID-19 pandemic is provided.
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