Wearable Cortisol Aptasensor for Simple and Rapid Real-Time Monitoring

An, Jai Eun; Kim, Kyung Ho; Park, Seon Joo; Seo, Sung Eun; Kim, Jin-Yeong; Ha, Siyoung; Bae, Joonwon; Kwon, Oh Seok

doi:10.1021/acssensors.1c01734

Cited by 91 publications

(73 citation statements)

References 70 publications

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“…In particular, n-type transistors cannot be utilized for biosensors due to the occurrence of damage to biomolecules by radicals. [45] The transfer curves indicated the charge density and the movement of the Dirac point (Figure 4f). The OGMFET displayed a Dirac point at 0.35 V, while the Dirac point was negatively shifted to 0.15 V (ΔV g = À 0.2 V) after magainin I conjugation due to the positive charge of magainin I.…”

Section: Resultsmentioning

confidence: 99%

Open‐Bandgap Graphene‐Based Field‐Effect Transistor Using Oligo(phenylene‐ethynylene) Interfacial Chemistry

et al. 2022

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Organic interfacial compounds (OICs) are required as linkers for the highly stable and efficient immobilization of bioprobes in nanobiosensors using 2D nanomaterials such as graphene. Herein, we first demonstrated the fabrication of a field-effect transistor (FET) via a microelectromechanical system process after covalent functionalization on large-scale graphene by introducing oligo(phenylene-ethynylene)amine (OPE). OPE was compared to various OICs by density functional theory simulations and was confirmed to have a higher binding energy with graphene and a lower band gap than other OICs. OPE can improve the immobilization efficiency of a bioprobe by forming a self-assembly monolayer via anion-based reaction. Using this technology, Magainin I-conjugated OGMFET (MOGMFET) showed a high sensitivity, high selectivity, with a limit of detection of 10 0 cfu mL À 1 . These results indicate that the OPE OIC can be applied for stable and comfortable interfacing technology for biosensor fabrication.

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Section: Resultsmentioning

confidence: 99%

Open‐Bandgap Graphene‐Based Field‐Effect Transistor Using Oligo(phenylene‐ethynylene) Interfacial Chemistry

et al. 2022

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“…The liquid-ion gated FET system was suitably verified of the operation in the 𝑝-type region because electron transfer was induced by oxygen, and the biomolecules were damaged by the radicals generated in the 𝑛-type region in the liquid phase. [23]. The transfer curves showed the shifted Dirac point as a minimum gating effect depending on the surface modifications of the graphene surface, which indicated a change in the charge carrier density caused by PDA and SAb [Fig.…”

Section: Electrical Properties Of Sab-gmfetmentioning

confidence: 99%

A Portable Graphene Micropatterned Field-Effect Transistor Device for Rapid Real-Time Monitoring of Serotonin

Kim

Seo

Kwon

2022

Appl. Sci. Converg. Technol.

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Serotonin is a stress biomarker and is one of the major neurotransmitters, and its concentration in the body is related to psychological functions such as mental illness. In particular, this biomarker is used to indicate depression caused by the increased stress of modern society. Therefore, detection and monitoring technologies are important for tracing concentration changes. In this study, we developed a serotonin antibodyconjugated graphene micropatterned field-effect transistor (SAb-GMFET)-based portable device for on-site or self-diagnosis of serotonin. The SAb-GMFET consisted of a graphene micropatterned channel, SAb for selective detection, and electrodes to supply the voltage. The SAb was immobilized by forming an amide bond with a diamine linker. SAb-GFMET showed high performance of limit of detection of 10 pM within 10 s and exhibited excellent selective detection among the interfering materials. For on-site and self-diagnosis applications, a portable device was developed with a sim chip, and the SAb-GMFET was connected to a printed circuit board using wire bonding. The portable SAb-GMFET showed a similar performance to that of the SAb-GMFET. Therefore, this portable platform can be utilized for point-of-care tests.

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“…Aptamer-based sensors have presented great significance in drug screening, biomedical diagnosis, forensic analysis, and environmental monitoring . For instance, Kwon and co-workers investigated a flexible and wearable cortisol aptasensor for the real-time monitoring of cortisol in actual sweat. Undoubtedly, combined with the advantages of wearable aptasensors and electrochemical techniques, wearable electrochemical aptasensors for sweat-based analysis could provide wide application prospects for the development of new cost-effective sensing platforms for drug analysis …”

Section: Introductionmentioning

confidence: 99%

Integrated Aptasensor Array for Sweat Drug Analysis

Zhang

Tang

et al. 2022

Anal. Chem.

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Drug abuse is seriously endangering human health and jeopardizing society. There is an urgent need for rapid, sensitive, portable, and easy-to-operate methods for the daily detection of drugs in biological matrices. However, current drug detection methods based on chromatography, spectroscopy, immunosorbent assays, etc. are limited by the requirements of high logistical instruments and laboratory. Herein, we proposed a wearable electrochemical aptasensor with high sensitivity and specificity for the direct capture and rapid detection of multiple drugs in sweat. The single aptamer and dual aptamers with different base compositions were designed to compose the aptasensor array. Molecular docking simulations demonstrated different binding affinities between bioamines and aptamers. The developed aptasensor array is shown to be sufficient to generate distinct electrochemical fingerprints for different psychoactive drugs and interfering substances by extracting variable features from electrochemical signals. Sixteen analytes in the same concentration or gradient concentrations were identified with 100% accuracy. In addition, the wearable sensor platform was demonstrated to discriminate various drugs with similar chemical structures in artificial sweat and human sweat samples. The sensor array not only provided a new rapid method for the detection of drugs but also served as a reference for developing wearable sensors for onsite and daily testing of human biochemical information.

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Wearable Cortisol Aptasensor for Simple and Rapid Real-Time Monitoring

Cited by 91 publications

References 70 publications

Open‐Bandgap Graphene‐Based Field‐Effect Transistor Using Oligo(phenylene‐ethynylene) Interfacial Chemistry

Open‐Bandgap Graphene‐Based Field‐Effect Transistor Using Oligo(phenylene‐ethynylene) Interfacial Chemistry

A Portable Graphene Micropatterned Field-Effect Transistor Device for Rapid Real-Time Monitoring of Serotonin

Integrated Aptasensor Array for Sweat Drug Analysis

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