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Bioelectronics

Electroanalysis, 2005
Preface.List of Contributors.1 Bioelectronics - An Introduction (Itamar Willner and Eugenii Katz).2 Electron Transfer Through Proteins (Jay R. Winkler, HarryB.Gray, TatianaR. Prytkova, Igor V. Kurnikov, and David N. Beratan).2.1 Electronic Energy Landscapes.2.2 Theory of Electron Tunneling.2.3 Tunneling Pathways.2.4 Coupling-limited ET Rates and Tests ...
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Protein-Based Bioelectronics

ACS Biomaterials Science & Engineering, 2016
The desire for flexible electronics is booming, and development of bioelectronics for health monitoring, internal body procedures, and other biomedical applications is heavily responsible for the growing market. Most current fabrication techniques for flexible bioelectronics, however, do not use materials that optimize both biocompatibility and ...
Maria, Torculas   +3 more
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The rise of plastic bioelectronics

Nature, 2016
Plastic bioelectronics is a research field that takes advantage of the inherent properties of polymers and soft organic electronics for applications at the interface of biology and electronics. The resulting electronic materials and devices are soft, stretchable and mechanically conformable, which are important qualities for interacting with biological
Takao, Someya   +2 more
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Bioelectronics for sustainable healthcare

2012 IEEE International Solid-State Circuits Conference, 2012
The aim of this forum is to translate the challenge of sustainable healthcare into a set of application challenges, from which design, circuit and technology needs can be derived. By means of examples, the role of advanced circuit design in solving the application challenges will be clarified. Enabling circuit paradigms will be presented and discussed.
Chris Van Hoof   +5 more
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Sixty seconds on . . . bioelectronics

BMJ, 2017
Well, it’s new and exciting, but it’s not a major blockbuster movie. It’s actually a new scientific field developing miniaturised, implantable devices that could replace pills or injections in the future. The vision is that the devices will be smaller than a grain of sand. No. But bigger implantable devices are already in use.
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Freestanding, soft bioelectronics

2015 7th International IEEE/EMBS Conference on Neural Engineering (NER), 2015
Soft, flexible electrode arrays are proposed to address the limitations of metallic tracks and electrodes in stimulating neuroprosthetics. The aim of these studies was to explore spatially selective polymerization of conductive polymer (CP) within a hydrogel as a proof of concept for freestanding conductive hydrogel electrode arrays, which are not ...
Alessandro D. Amella   +5 more
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Bioelectronic Nose and Bioelectronic Tongue in vitro and in vivo

2022 IEEE International Symposium on Olfaction and Electronic Nose (ISOEN), 2022
Ping Wang   +5 more
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Organic bioelectronics in nanomedicine

Biochimica et Biophysica Acta (BBA) - General Subjects, 2011
Nanomedicine is a research area with potential to shape, direct, and change future medical treatments in a revolutionary manner over the next decades. While the common goal with other fields of biomedicine is to solve medical problems, this area embraces an increasing number of technology platforms as they become miniaturized.
Karl, Svennersten   +3 more
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Bioelectronics: Biosensors

2011 IEEE Industry Applications Society Annual Meeting, 2011
D. P. Addy, T. D. Gehman, M. H. Rashid
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