Wearable and Implantable Soft Bioelectronics Using Two-Dimensional Materials

Choi, Changsoon; Lee, Youngsik; Cho, Kyoung Won; Koo, Ja Hoon; Doo, Gi

doi:10.1021/acs.accounts.8b00491

Cited by 168 publications

(144 citation statements)

References 47 publications

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“…Today, flexible bioelectronics are prominently found in wearable electronics with integrated biosensors embedded in a smartwatch or a smartphone . They facilitate continuous monitoring of the physiological status of individuals and provide a personalized health profile to keep track of an individual's well‐being . Over the last decade, flexible and stretchable bioelectronics have further spearheaded the research development in biological sensing platforms and point‐of‐care diagnostic devices .…”

Section: Introductionmentioning

confidence: 99%

Flexible Electrochemical Bioelectronics: The Rise of In Situ Bioanalysis

et al. 2019

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The amalgamation of flexible electronics in biological systems has shaped the way health and medicine are administered. The growing field of flexible electrochemical bioelectronics enables the in situ quantification of a variety of chemical constituents present in the human body and holds great promise for personalized health monitoring owing to its unique advantages such as inherent wearability, high sensitivity, high selectivity, and low cost. It represents a promising alternative to probe biomarkers in the human body in a simpler method compared to conventional instrumental analytical techniques. Various bioanalytical technologies are employed in flexible electrochemical bioelectronics, including ion‐selective potentiometry, enzymatic amperometry, potential sweep voltammetry, field‐effect transistors, affinity‐based biosensing, as well as biofuel cells. Recent key innovations in flexible electrochemical bioelectronics from electrochemical sensing modalities, materials, systems, fabrication, to applications are summarized and highlighted. The challenges and opportunities in this field moving forward toward future preventive and personalized medicine devices are also discussed.

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Section: Introductionmentioning

confidence: 99%

Flexible Electrochemical Bioelectronics: The Rise of In Situ Bioanalysis

et al. 2019

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“…In recent years, graphene‐based flexible sensors have attracted much attention and exhibit unprecedented performance with high sensitivity (161.6 kPa −1 within 0.56 kPa), long‐term stability (50 000 cycles), and low response time (11 ms) . Wang et al synthesized graphene woven fabrics on flexible PMDS and medical tape substrate to fabricate the graphene‐PDMS‐medical tape‐based strain sensor by piezoresistive‐type configuration.…”

Section: Flexible Mechanical Sensor Applicationmentioning

confidence: 99%

Two‐dimensional materials: From mechanical properties to flexible mechanical sensors

Jiang

Zheng

Liu

et al. 2019

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222

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Two‐dimensional (2D) materials have great potential in the fields of flexible electronics and photoelectronic devices due to their unique properties derived by special structures. The study of the mechanical properties of 2D materials plays an important role in next‐generation flexible mechanical electronic device applications. Unfortunately, traditional experiment models and measurement methods are not suitable for 2D materials due to their atomically ultrathin thickness, which limits both the theoretical research and practical value of the 2D materials. In this review, we briefly summarize the characterization of mechanical properties of 2D materials by in situ probe nanoindentation experiments, and discuss the effect of thickness, grain boundary, and interlayer interactions. We introduce the strain‐induced effect on electrical properties and optical properties of 2D materials. Then, we generalize the mechanical sensors based on various 2D materials and their future potential applications in flexible and wearable electronic devices. Finally, we discuss the state of the art for the mechanical properties of 2D materials and their opportunities and challenges in both basic research and practical applications.

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“…[95] The input signals applied in various combinations can perform Boolean logic operations [96] before they trigger ΔpH formation. The research on signal-controlled interfacial properties, including the formation of a local ΔpH, can contribute to further advances in bioelectronics, [97][98][99] resulting in novel sensingactuating bioelectronic systems for wearable [100,101] and implantable [98,102] devices with "smart" operation. Figure 20.…”

Section: Conclusion Retrospection and Perspectivesmentioning

confidence: 99%

Electrochemically Generated Interfacial pH Change: Application to Signal‐Triggered Molecule Release

2020

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Electron transfer processes during redox reactions are frequently accompanied with protonation/deprotonation processes, thus changing H+/OH− concentrations. When the redox reactions proceed at electrode surfaces, being electrochemically processed, changes in local interfacial pH are possible, particularly when the electrolyte solution is not strongly buffered. The pH gradient can be produced in the diffusion layer and its thickness depends on the rate of electrochemical process, which is measured as the current density, diffusion rates, and buffer capacity. While conventional techniques for measuring pH values are not applicable to a very thin diffusional layer, special methods have been developed for the interfacial pH measurements, including scanning electrochemical microscopy (SECM), rotating ring‐disk electrode (RRDE) measurements, various optical methods, particularly using confocal fluorescent microscopy, and others. Dramatic pH changes proceeding in a near‐electrode layer have been reported for H2O reduction/oxidation, O2 reduction, and some other electrochemical electron/proton transfer processes. These pH changes can be used to trigger some other physical processes, particularly (bio)molecule release processes from modified electrodes, which can be destabilized upon the electrochemically generated pH changes, thus releasing entrapped/loaded target molecules. This review‐type article overviews the formation and analysis of locally produced interfacial pH changes and their use for electrochemically triggered (bio)molecule release. The paper briefly reviews the research area, then concentrating on the systems designed recently by the authors.

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Wearable and Implantable Soft Bioelectronics Using Two-Dimensional Materials

Cited by 168 publications

References 47 publications

Flexible Electrochemical Bioelectronics: The Rise of In Situ Bioanalysis

Flexible Electrochemical Bioelectronics: The Rise of In Situ Bioanalysis

Two‐dimensional materials: From mechanical properties to flexible mechanical sensors

Electrochemically Generated Interfacial pH Change: Application to Signal‐Triggered Molecule Release

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