Flexible bioelectronics for physiological signals sensing and disease treatment

Yao, Guang; Yin, Chenhui; Wang, Qian; Wang, Ziyang; Chen, Sihong; Lu, Chang; Zhao, Kangning; Xu, Weina; Pan, Taisong; Gao, Min; Lin, Yuan

doi:10.1016/j.jmat.2019.12.005

Cited by 40 publications

(27 citation statements)

References 127 publications

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“…X. Anitha Mary et al (2020) say that measurement in the physiological and environment with regard to the human body is as follows: physiology or biosensors i.e., body temperature, pressure and blood flow, heart rate, breathing, hydrogen, glucose, movement angle, accelerometers, physical activity; and environment i.e., temperature environment (Mary et al, 2020). Yaoet et al (2020) say that measurement in the physiological and environment with regard to the human body is as follows: physiology or biosensors i.e., body temperature, pressure of blood, heart rate, heartbeat, breathing, glucose, gas, weight, movement angle, skin conductance, accelerometers, physical activity, brain activity, bone mass; and environment i.e., air density, lighting, humidity (Yao et al, 2020). 5.1.1., 5.1.2, 5.1.3 and 5.1.4 as Shown in Table 1 Table 1…”

Section: The Results Of the Synthesis Of Physiological And Environmental Measurements With Regard To The Human Bodymentioning

confidence: 99%

Sensorization of Things Intelligent Technology for Sport Science to Develop an Athlete’s Physical Potential

Sattaburuth¹,

Wannapiroon²

2021

HES

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Sports can build both strength and be fun at the same time. When it comes to a professional athlete's victory, the winner will enhance his reputation and can earn a great deal of money. The problem that athletes frequently encounter is traumas, which can happen in games or during training. Today, the technology is very advanced and modernized. Innovations and perceptual devices can be created to monitor, measure, analyze and evaluate data from the information received from the introduction of an intelligent system of evaluation and prediction in terms of safety and risk prevention with regard to athletes, by collecting heart rate data, blood oxygen measurement, air density around the athletes’ body, body temperature and a temperature in the sports training room. This is the point of view and vision of a sports industry leaders, who perceive the opportunity and advantage associated with the competition and training of both amateur and professional athletes, to develop the athlete’s physical potential to achieve international excellence. The study of intelligent sensor technology that is used to support devices that work on the guidelines of Internet of Things (IoT) leading to the development of real time data collecting applications. These are used to process or interpret physiological knowledge for an analysis of results and for the prediction of incoming results. It was found that using intelligent sensing technology which are two main groups of detection and measurement: First, human body function sensing and second, measurement to environment around the body or object, and explained to detail in this article.

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Section: The Results Of the Synthesis Of Physiological And Environmental Measurements With Regard To The Human Bodymentioning

confidence: 99%

Sensorization of Things Intelligent Technology for Sport Science to Develop an Athlete’s Physical Potential

Sattaburuth¹,

Wannapiroon²

2021

HES

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“…Furthermore, due to the ability of electric current to induce polarity within cells and tissues, they hold significant promise in actuating the movement of cells and modulation of the cell cycle, which could revolutionize the wound healing, tissue regeneration processes and cancer therapeutics (Chang & Minc, 2014). The current state‐of‐the‐art bioelectronics for actuation of cell behavior include wearable and implantable electronics (Koo et al, 2018; Topfer & Farrah, 2018; Yao et al, 2020). Others include microfluidic “lab‐on‐a‐chip” devices that maintain the concentration and distribution of biological signaling molecules such as growth factors and cytokines (Paguirigan & Beebe, 2008; Whitesides, 2006).…”

Section: Wireless Nanobioelectronic Toolsmentioning

confidence: 99%

Toward nanobioelectronic medicine: Unlocking new applications using nanotechnology

Gibney

Hicks

Robinson

et al. 2021

WIREs Nanomed Nanobiotechnol

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Bioelectronic medicine aims to interface electronic technology with biological components and design more effective therapeutic and diagnostic tools. Advances in nanotechnology have moved the field forward improving the seamless interaction between biological and electronic components. In the lab many of these nanobioelectronic devices have the potential to improve current treatment approaches, including those for cancer, cardiovascular disorders, and disease underpinned by malfunctions in neuronal electrical communication. While promising, many of these devices and technologies require further development before they can be successfully applied in a clinical setting. Here, we highlight recent work which is close to achieving this goal, including discussion of nanoparticles, carbon nanotubes, and nanowires for medical applications. We also look forward toward the next decade to determine how current developments in nanotechnology could shape the growing field of bioelectronic medicine. This article is categorized under: Therapeutic Approaches and Drug Discovery > Emerging Technologies Nanotechnology Approaches to Biology > Nanoscale Systems in Biology Diagnostic Tools > Biosensing

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“…In an effort to interface electronics with human tissues, many developments are focused on elastomeric, stretchable materials incorporating flexible electronic devices. [1][2][3] This serves to advance bioelectronics for long-term physiological monitoring parameters, [4][5][6] regulate or restore organ functions, [7][8][9] ondemand drug-delivery, [10][11] small molecule biosensing, [12][13][14] and tissue repair. [15] Despite the impressive miniaturization and multifunctional attributes, their implementation in patients still faces several challenges.…”

Section: Introductionmentioning

confidence: 99%

Precise Control of Diazirine Reduction to Tune the Mechanical Properties of Electrocuring Adhesives

et al. 2021

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There is a growing interest in developing innovative adhesive materials that offer stimuli-responsive mechanical properties. Electrocuring adhesives exploit electric-field stimuli towards initiating and propagating polymerization reactions with projected benefits of on-demand adhesion and microelectronic control. Voltaglue is a recently developed biocompatible, waterbased bioadhesive that combines a biomacromolecule (polyamidoamine, PAMAM) with a grafted electrochemical crosslinker (diazirine) where the former mediates viscoelastic properties and the latter voltage-based activation. Through this relatively simple design, a range of viscoelastic and adhesive properties are possible by controlling the intensity (voltage) and duration (coulombs) of the electric field. For the first time, bioadhesive properties are correlated to the moles of diazirine reduced during electrocuring via chronoamperograms. The method is based on the precise measurement of the charge exchanged during the reductive reaction which ultimately results in a series of voltage/time combinations that can be used to drive diazirine activation and charge quantitation. A strong correlation is finally observed between diazirine electrolysis and specific mechanical properties of the cured adhesive. This ultimately enables fine-tune control over the adhesive properties with benefits in a wide variety of applications ranging from electromagnetic biomaterials to additive manufacturing.

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Flexible bioelectronics for physiological signals sensing and disease treatment

Cited by 40 publications

References 127 publications

Sensorization of Things Intelligent Technology for Sport Science to Develop an Athlete’s Physical Potential

Sensorization of Things Intelligent Technology for Sport Science to Develop an Athlete’s Physical Potential

Toward nanobioelectronic medicine: Unlocking new applications using nanotechnology

Precise Control of Diazirine Reduction to Tune the Mechanical Properties of Electrocuring Adhesives

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