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5 results on '"Chen, Huajun"'

1. Printable Ultrathin Metal Oxide Semiconductor-Based Conformal Biosensors

Author

Rim, You Seung, Bae, Sang-Hoon, Chen, Huajun, Yang, Jonathan L, Kim, Jaemyung, Andrews, Anne M, Weiss, Paul S, Yang, Yang, and Tseng, Hsian-Rong

Subjects
Chemical Sciences, Engineering, Information and Computing Sciences, Data Management and Data Science, Materials Engineering, Bioengineering, Biosensing Techniques, Blood Glucose, Humans, Indium, Pliability, Semiconductors, biosensor, aqueous process, metal oxide semiconductor, conformal, flexible, field-effect transistor, Nanoscience & Nanotechnology
Abstract

Conformal bioelectronics enable wearable, noninvasive, and health-monitoring platforms. We demonstrate a simple and straightforward method for producing thin, sensitive In2O3-based conformal biosensors based on field-effect transistors using facile solution-based processing. One-step coating via aqueous In2O3 solution resulted in ultrathin (3.5 nm), high-density, uniform films over large areas. Conformal In2O3-based biosensors on ultrathin polyimide films displayed good device performance, low mechanical stress, and highly conformal contact determined using polydimethylsiloxane artificial skin having complex curvilinear surfaces or an artificial eye. Immobilized In2O3 field-effect transistors with self-assembled monolayers of NH2-terminated silanes functioned as pH sensors. Functionalization with glucose oxidase enabled d-glucose detection at physiologically relevant levels. The conformal ultrathin field-effect transistor biosensors developed here offer new opportunities for future wearable human technologies.

Published
2015

2. Fabrication of High-Performance Ultrathin In2O3 Film Field-Effect Transistors and Biosensors Using Chemical Lift-Off Lithography

Author

Kim, Jaemyung, Rim, You Seung, Chen, Huajun, Cao, Huan H, Nakatsuka, Nako, Hinton, Hannah L, Zhao, Chuanzhen, Andrews, Anne M, Yang, Yang, and Weiss, Paul S

Subjects
Engineering, Materials Engineering, Chemical Sciences, Aptamers, Nucleotide, Base Sequence, Biosensing Techniques, Dopamine, Indium, Limit of Detection, Nanotechnology, Printing, Transistors, Electronic, biosensor, field-effect transistor, chemical lift-off lithography, metal-oxide semiconductor, sol gel chemistry, aptamer, neurotransmitter, dopamine, nanotechnology, nanofabrication, sensor, sol−gel chemistry, Nanoscience & Nanotechnology
Abstract

We demonstrate straightforward fabrication of highly sensitive biosensor arrays based on field-effect transistors, using an efficient high-throughput, large-area patterning process. Chemical lift-off lithography is used to construct field-effect transistor arrays with high spatial precision suitable for the fabrication of both micrometer- and nanometer-scale devices. Sol-gel processing is used to deposit ultrathin (∼4 nm) In2O3 films as semiconducting channel layers. The aqueous sol-gel process produces uniform In2O3 coatings with thicknesses of a few nanometers over large areas through simple spin-coating, and only low-temperature thermal annealing of the coatings is required. The ultrathin In2O3 enables construction of highly sensitive and selective biosensors through immobilization of specific aptamers to the channel surface; the ability to detect subnanomolar concentrations of dopamine is demonstrated.

Published
2015

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