Satoshi Ihida scite author profile

This paper presents a review on state-of-the-art of thin-film transistor (TFT) technology and its wide range of applications, not only in liquid crystal displays (TFT-LCDs), but also in sensing devices. The history of the evolution of the technology is first given. Then the standard applications of TFT-LCDs, and X-ray detectors, followed by state-of-the-art applications in the field of chemical and biochemical sensing are presented. TFT technology allows the fabrication of dense arrays of independent and transparent microelectrodes on large glass substrates. The potential of these devices as electrical substrates for biological cell applications is then described. The possibility of using TFT array substrates as new tools for electrical experiments on biological cells has been investigated for the first time by our group. Dielectrophoresis experiments and impedance measurements on yeast cells are presented here. Their promising results open the door towards new applications of TFT technology.

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A MEMS Electrostatic Roll-Up Window Shade Array for House Energy Management System

Möri

Misawa

Ihida

et al. 2016

IEEE Photon. Technol. Lett.

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TFT sensor array for real-time cellular characterization, stimulation, impedance measurement and optical imaging of in-vitro neural cells

Shaik

Ihida

Ikeuchi

et al. 2020

Biosensors and Bioelectronics

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Thin-film-transistor array: an exploratory attempt for high throughput cell manipulation using electrowetting principle

Shaik

Cathcart

Ihida

et al. 2017

J. Micromech. Microeng.

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In lab-on-a-chip (LoC) devices, microfluidic displacement of liquids is a key component. electrowetting on dielectric (EWOD) is a technique to move fluids, with the advantage of not requiring channels, pumps or valves. Fluids are discretized into droplets on microelectrodes and moved by applying an electric field via the electrodes to manipulate the contact angle. Micro-objects, such as biological cells, can be transported inside of these droplets. However, the design of conventional microelectrodes, made by standard micro-fabrication techniques, fixes the path of the droplets, and limits the reconfigurability of paths and thus limits the parallel processing of droplets. In that respect, thin film transistor (TFT) technology presents a great opportunity as it allows infinitely reconfigurable paths, with high parallelizability. We propose here to investigate the possibility of using TFT array devices for high throughput cell manipulation using EWOD. A COMSOL based 2D simulation coupled with a MATLAB algorithm was used to simulate the contact angle modulation, displacement and mixing of droplets. These simulations were confirmed by experimental results. The EWOD technique was applied to a droplet of culture medium containing HepG2 carcinoma cells and demonstrated no negative effects on the viability of the cells. This confirms the possibility of applying EWOD techniques to cellular applications, such as parallel cell analysis.

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2D Dielectrophoresis using an active matrix array made by thin‐film‐transistor technology

Tixier‐Mita

Ihida

Blanchard³

et al. 2019

IEEJ Transactions Elec Engng

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New types of devices made using thin‐film‐transistor (TFT) technology were used in this article for dielectrophoresis purpose with microbeads, yeast cells, and HepG2 cells. That technology allows obtaining centimeter size transparent substrates covered with a large and dense array of 100 µm microelectrodes individually controllable. The purpose of these devices is the development of platforms for various applications on cells and cells culture, like manipulation, sensing, monitoring, or stimulation on the same device. Dielectrophoresis is one of the applications and is a key target for precise patterning and 2D displacement of cells on the device. In this article, 2D results of dielectrophoresis with microbeads and yeast cells and device programming are described. Then, application to mammal HepG2 liver cells shows the possibility of cells patterning with such devices. © 2019 Institute of Electrical Engineers of Japan. Published by John Wiley & Sons, Inc.

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Satoshi Ihida

Review on thin-film transistor technology, its applications, and possible new applications to biological cells

A MEMS Electrostatic Roll-Up Window Shade Array for House Energy Management System

TFT sensor array for real-time cellular characterization, stimulation, impedance measurement and optical imaging of in-vitro neural cells

Thin-film-transistor array: an exploratory attempt for high throughput cell manipulation using electrowetting principle

2D Dielectrophoresis using an active matrix array made by thin‐film‐transistor technology

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