Protein Assays on Organic Electronics: Rational Device and Material Designs for Organic Transistor‐Based Sensors

Protein Assays on Organic Electronics: Rational Device and Material Designs for Organic Transistor‐Based Sensors

Abstract Artificial receptor‐based protein assays have various attractive features such as a long‐term stability, a low‐cost production process, and the ease of tuning the target specificity. However, such protein sensors are still immature compared with conventional immunoassays. To enhance the app...

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Main Authors: Dr. Tsukuru Minamiki, Dr. Riku Kubota, Yui Sasaki, Koichiro Asano, Prof. Tsuyoshi Minami
Format: Article
Language:English
Published: Wiley-VCH 2020-05-01
Series:ChemistryOpen
Subjects:
organic transistors
protein assays
self-assembled monolayers
artificial receptors
host-guest chemistry
Online Access:https://doi.org/10.1002/open.202000025
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spelling doaj-b050773847904a609cff59fc999e5cf12021-04-02T13:17:02ZengWiley-VCHChemistryOpen2191-13632020-05-019557358110.1002/open.202000025Protein Assays on Organic Electronics: Rational Device and Material Designs for Organic Transistor‐Based SensorsDr. Tsukuru Minamiki0Dr. Riku Kubota1Yui Sasaki2Koichiro Asano3Prof. Tsuyoshi Minami4Institute of Industrial Science The University of Tokyo 4-6-1 Komaba, Meguro-ku Tokyo 153-8505 JapanInstitute of Industrial Science The University of Tokyo 4-6-1 Komaba, Meguro-ku Tokyo 153-8505 JapanInstitute of Industrial Science The University of Tokyo 4-6-1 Komaba, Meguro-ku Tokyo 153-8505 JapanInstitute of Industrial Science The University of Tokyo 4-6-1 Komaba, Meguro-ku Tokyo 153-8505 JapanInstitute of Industrial Science The University of Tokyo 4-6-1 Komaba, Meguro-ku Tokyo 153-8505 JapanAbstract Artificial receptor‐based protein assays have various attractive features such as a long‐term stability, a low‐cost production process, and the ease of tuning the target specificity. However, such protein sensors are still immature compared with conventional immunoassays. To enhance the application potential of synthetic sensing materials, organic field‐effect transistors (OFETs) are some of the suitable platforms for protein assays because of their solution processability, durability, and compact integration. Importantly, OFETs enable the electrical readout of the protein recognition phenomena of artificial receptors on sensing electrodes. Thus, we believe that OFETs functionalized with artificial protein receptors will be a powerful tool for the on‐site analyses of target proteins. In this Minireview, we summarize the recent progress of the OFET‐based protein assays including the rational design strategies for devices and sensing materials.https://doi.org/10.1002/open.202000025organic transistorsprotein assaysself-assembled monolayersartificial receptorshost-guest chemistry
collection DOAJ
language English
format Article
sources DOAJ
author Dr. Tsukuru Minamiki
Dr. Riku Kubota
Yui Sasaki
Koichiro Asano
Prof. Tsuyoshi Minami
spellingShingle Dr. Tsukuru Minamiki
Dr. Riku Kubota
Yui Sasaki
Koichiro Asano
Prof. Tsuyoshi Minami
Protein Assays on Organic Electronics: Rational Device and Material Designs for Organic Transistor‐Based Sensors
ChemistryOpen
organic transistors
protein assays
self-assembled monolayers
artificial receptors
host-guest chemistry
author_facet Dr. Tsukuru Minamiki
Dr. Riku Kubota
Yui Sasaki
Koichiro Asano
Prof. Tsuyoshi Minami
author_sort Dr. Tsukuru Minamiki
title Protein Assays on Organic Electronics: Rational Device and Material Designs for Organic Transistor‐Based Sensors
title_short Protein Assays on Organic Electronics: Rational Device and Material Designs for Organic Transistor‐Based Sensors
title_full Protein Assays on Organic Electronics: Rational Device and Material Designs for Organic Transistor‐Based Sensors
title_fullStr Protein Assays on Organic Electronics: Rational Device and Material Designs for Organic Transistor‐Based Sensors
title_full_unstemmed Protein Assays on Organic Electronics: Rational Device and Material Designs for Organic Transistor‐Based Sensors
title_sort protein assays on organic electronics: rational device and material designs for organic transistor‐based sensors
publisher Wiley-VCH
series ChemistryOpen
issn 2191-1363
publishDate 2020-05-01
description Abstract Artificial receptor‐based protein assays have various attractive features such as a long‐term stability, a low‐cost production process, and the ease of tuning the target specificity. However, such protein sensors are still immature compared with conventional immunoassays. To enhance the application potential of synthetic sensing materials, organic field‐effect transistors (OFETs) are some of the suitable platforms for protein assays because of their solution processability, durability, and compact integration. Importantly, OFETs enable the electrical readout of the protein recognition phenomena of artificial receptors on sensing electrodes. Thus, we believe that OFETs functionalized with artificial protein receptors will be a powerful tool for the on‐site analyses of target proteins. In this Minireview, we summarize the recent progress of the OFET‐based protein assays including the rational design strategies for devices and sensing materials.
topic organic transistors
protein assays
self-assembled monolayers
artificial receptors
host-guest chemistry
url https://doi.org/10.1002/open.202000025
work_keys_str_mv AT drtsukuruminamiki proteinassaysonorganicelectronicsrationaldeviceandmaterialdesignsfororganictransistorbasedsensors
AT drrikukubota proteinassaysonorganicelectronicsrationaldeviceandmaterialdesignsfororganictransistorbasedsensors
AT yuisasaki proteinassaysonorganicelectronicsrationaldeviceandmaterialdesignsfororganictransistorbasedsensors
AT koichiroasano proteinassaysonorganicelectronicsrationaldeviceandmaterialdesignsfororganictransistorbasedsensors
AT proftsuyoshiminami proteinassaysonorganicelectronicsrationaldeviceandmaterialdesignsfororganictransistorbasedsensors
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