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M. Pope, C. Swenberg (1999)
Electronic Processes in Organic Crystals and Polymers
C. Yumusak, T. Singh, N. Sariciftci, J. Grote (2009)
Bio-organic field effect transistors based on crosslinked deoxyribonucleic acid (DNA) gate dielectricApplied Physics Letters, 95
M. Ecker, A. Joshi-Imre, R. Modi, C. Frewin, Aldo Garcia-Sandoval, Jimin Maeng, G. Gutierrez-Heredia, J. Pancrazio, W. Voit (2018)
From softening polymers to multimaterial based bioelectronic devicesMultifunctional Materials, 2
(1996)
Molecular Bioelectronics, World Scientific Publishing Co., Singapore
(2019)
Wearable Bioelectronics, Elsevier, New York 2019
A. Green, Salomon Wolff (1911)
Anilinschwarz und seine ZwischenkörperEuropean Journal of Inorganic Chemistry, 44
Daniele Mantione, I. Agua, W. Schaafsma, M. Elmahmoudy, Ilke Uguz, A. Sanchez-Sanchez, H. Sardón, B. Castro, G. Malliaras, D. Mecerreyes (2017)
Low-Temperature Cross-Linking of PEDOT:PSS Films Using Divinylsulfone.ACS applied materials & interfaces, 9 21
N. Claudio (1996)
Molecular Bioelectronics
M. Panzer, C. Newman, C. Frisbie (2005)
Low-voltage operation of a pentacene field-effect transistor with a polymer electrolyte gate dielectricApplied Physics Letters, 86
H. Shirakawa, E. Louis, A. MacDiarmid, C. Chiang, A. Heeger (1977)
Synthesis of electrically conducting organic polymers: halogen derivatives of polyacetylene, (CH)x
Elisabeth Rausch, B. Balke, Torben Deschauer, S. Ouardi, C. Felser (2015)
Charge carrier concentration optimization of thermoelectric p-type half-Heusler compoundsAPL Materials, 3
L. Groenendaal, F. Jonas, D. Freitag, H. Pielartzik, J. Reynolds (2000)
Poly(3,4‐ethylenedioxythiophene) and Its Derivatives: Past, Present, and FutureAdvanced Materials, 12
Peng Lin, Feng Yan (2012)
Organic Thin‐Film Transistors for Chemical and Biological SensingAdvanced Materials, 24
J. Léger (2008)
Organic Electronics: The Ions Have ItAdvanced Materials, 20
J. Rivnay, R. Owens, G. Malliaras (2014)
The Rise of Organic BioelectronicsChemistry of Materials, 26
G. Omokhunu, C. Bach (2018)
Organic Bio-Electronics: Bridging The Gap Between Natural and Artificial Materials for Bio-Electronics ApplicationsEuropean Journal of Engineering Research and Science
Jeff Mabeck, John DeFranco, D. Bernards, G. Malliaras, S. Hocdé, C. Chase (2005)
Microfluidic gating of an organic electrochemical transistorApplied Physics Letters, 87
Erica Zeglio, M. Vagin, Chiara Musumeci, F. Ajjan, R. Gabrielsson, X. Trinh, N. Son, A. Maziz, N. Solin, O. Inganäs (2015)
Conjugated Polyelectrolyte Blends for Electrochromic and Electrochemical Transistor DevicesChemistry of Materials, 27
Hui Peng, Lijuan Zhang, C. Soeller, J. Travas-sejdic (2009)
Conducting polymers for electrochemical DNA sensing.Biomaterials, 30 11
Daniele Mantione, I. Agua, A. Sanchez-Sanchez, D. Mecerreyes (2017)
Poly(3,4-ethylenedioxythiophene) (PEDOT) Derivatives: Innovative Conductive Polymers for BioelectronicsPolymers, 9
B. Wei, Jinglin Liu, Liang Ouyang, Chin-chen Kuo, David Martin (2015)
Significant enhancement of PEDOT thin film adhesion to inorganic solid substrates with EDOT-acid.ACS applied materials & interfaces, 7 28
A. Elschner, S. Kirchmeyer, Wilfried Lövenich, U. Merker, K. Reuter (2010)
PEDOT: Principles and Applications of an Intrinsically Conductive Polymer
C. Karunakaran, K. Bhargava, R. Benjamin (2015)
Biosensors and Bioelectronics
J. Rivnay, P. Leleux, Marc Ferro, M. Sessolo, A. Williamson, D. Koutsouras, D. Khodagholy, M. Ramuz, X. Strakosas, R. Owens, C. Bénar, J. Badier, C. Bernard, G. Malliaras (2015)
High-performance transistors for bioelectronics through tuning of channel thicknessScience Advances, 1
J. Leger, M. Berggren, S. Carter (2011)
Iontronics
H. Willner, E. Katz (2005)
Bioelectronics: From Theory to Applications
H. Letheby
XXIX.—On the production of a blue substance by the electrolysis of sulphate of anilineJournal of the Chemical Society, 15
K. Pal, H.‐B. Kraatz, A. Khasnobish, S. Bag, I. Banerjee, U. Kuruganti (2019)
Bioelectronics and Medical Devices
D. Khodagholy, J. Rivnay, M. Sessolo, M. Gurfinkel, P. Leleux, L. Jimison, E. Stavrinidou, T. Hervé, S. Sanaur, R. Owens, G. Malliaras (2013)
High transconductance organic electrochemical transistorsNature Communications, 4
C. Nielsen, A. Giovannitti, Dan-Tiberiu Sbircea, E. Bandiello, M. Niazi, David Hanifi, M. Sessolo, A. Amassian, G. Malliaras, J. Rivnay, I. McCulloch (2016)
Molecular Design of Semiconducting Polymers for High-Performance Organic Electrochemical TransistorsJournal of the American Chemical Society, 138
M. Irimia‐Vladu, E. D. Glowacki, N. S. Sariciftci, S. Bauer (2018)
Green Materials for Electronics
D. A. Bernards, R. M. Owens, G. G. Malliaras (2010)
Organic Semiconductors in Sensor Applications
D. Simon, S. Kurup, K. Larsson, Ryusuke Hori, K. Tybrandt, M. Goiny, E. Jager, M. Berggren, B. Canlon, A. Richter‐Dahlfors (2009)
Organic electronics for precise delivery of neurotransmitters to modulate mammalian sensory function.Nature materials, 8 9
J. Liao, Hewei Si, Xidong Zhang, Shiwei Lin (2019)
Functional Sensing Interfaces of PEDOT:PSS Organic Electrochemical Transistors for Chemical and Biological Sensors: A Mini ReviewSensors (Basel, Switzerland), 19
Rongjun He, Meng Zhang, Fei Tan, P. Leung, Xingzhong Zhao, H. Chan, Mo Yang, Feng Yan (2012)
Detection of bacteria with organic electrochemical transistorsJournal of Materials Chemistry, 22
Yogesh Ner, Michael Invernale, J. Grote, J. Stuart, G. Sotzing (2010)
Facile chemical synthesis of DNA-doped PEDOTSynthetic Metals, 160
J. Thackeray, H. White, M. Wrighton (1985)
Poly(3-methylthiophene)-coated electrodes: optical and electrical properties as a function of redox potential and amplification of electrical and chemical signals using poly(3-methylthiophene)-based microelectrochemical transistorsThe Journal of Physical Chemistry, 89
X. Strakosas, B. Wei, David Martin, R. Owens (2016)
Biofunctionalization of polydioxythiophene derivatives for biomedical applications.Journal of materials chemistry. B, 4 29
(2015)
Biosensors and Bioelec tronics, Elsevier, USA
Birendra Singh, N. Sariciftci, J. Grote, F. Hopkins (2006)
Bio-organic-semiconductor-field-effect-transistor based on deoxyribonucleic acid gate dielectricJournal of Applied Physics, 100
V. Rani, K. Santhanam (1998)
Polycarbazole-based electrochemical transistorJournal of Solid State Electrochemistry, 2
Erica Zeglio, O. Inganäs (2018)
Active Materials for Organic Electrochemical TransistorsAdvanced Materials, 30
P. Stadler, Kerstin Oppelt, T. Singh, J. Grote, R. Schwödiauer, S. Bauer, Heidi Piglmayer-Brezina, D. Bäuerle, N. Sariciftci (2007)
Organic field-effect transistors and memory elements using deoxyribonucleic acid (DNA) gate dielectricOrganic Electronics, 8
C. Boehler, Z. Aqrawe, M. Asplund (2019)
Applications of PEDOT in bioelectronic medicineBioelectronics in Medicine
A. Giovannitti, I. Maria, David Hanifi, M. Donahue, Daniel Bryant, Katrina Barth, Beatrice Makdah, A. Savva, Davide Moia, Matyáš Zetek, Piers Barnes, O. Reid, S. Inal, G. Rumbles, G. Malliaras, J. Nelson, J. Rivnay, I. McCulloch (2018)
The Role of the Side Chain on the Performance of N-type Conjugated Polymers in Aqueous ElectrolytesChemistry of Materials, 30
Yangping Wen, Jingkun Xu (2017)
Scientific Importance of Water‐Processable PEDOT–PSS and Preparation, Challenge and New Application in Sensors of Its Film Electrode: A ReviewJournal of Polymer Science Part A, 55
H. White, G. Kittlesen, M. Wrighton (1984)
Chemical derivatization of an array of three gold microelectrodes with polypyrrole: Fabrication of a molecule-based transistorJournal of the American Chemical Society, 106
L. Kergoat, B. Piro, D. Simon, M. Pham, V. Noël, M. Berggren (2014)
Detection of Glutamate and Acetylcholine with Organic Electrochemical Transistors Based on Conducting Polymer/Platinum Nanoparticle CompositesAdvanced Materials, 26
S. Carrara, K. Iniewski (2015)
Handbook of bioelectronics : directly interfacing electronics and biological systems
A. Offenhäusser, R. Rinaldi (2009)
Nanobioelectronics : for electronics, biology, and medicine
M. Asplund, E. Thaning, J. Lundberg, A. Sandberg-Nordqvist, B. Kostyszyn, O. Inganäs, H. Holst, H. Holst (2009)
Toxicity evaluation of PEDOT/biomolecular composites intended for neural communication electrodesBiomedical Materials, 4
E. Stavrinidou, P. Leleux, Harizo Rajaona, D. Khodagholy, J. Rivnay, M. Lindau, S. Sanaur, G. Malliaras (2013)
Direct Measurement of Ion Mobility in a Conducting PolymerAdvanced Materials, 25
A. Steckl, H. Spaeth, H. You, Eliot Gomez, J. Grote (2011)
DNA as an Optical MaterialOptics & Photonics News, 22
Li-li Wang, Jonichi Yoshida, N. Ogata, S. Sasaki, T. Kajiyama (2001)
Self-assembled supramolecular films derived from marine deoxyribonucleic acid (DNA)-cationic surfactant complexes : Large-scale preparation and optical and thermal propertiesChemistry of Materials, 13
J. Isaksson, Peter Kjäll, D. Nilsson, N. Robinson, M. Berggren, A. Richter‐Dahlfors (2007)
Electronic control of Ca2+ signalling in neuronal cells using an organic electronic ion pump.Nature materials, 6 9
Lisa Savagian, Anna Österholm, James Ponder, Katrina Barth, J. Rivnay, J. Reynolds (2018)
Balancing Charge Storage and Mobility in an Oligo(Ether) Functionalized Dioxythiophene Copolymer for Organic‐ and Aqueous‐ Based Electrochemical Devices and TransistorsAdvanced Materials, 30
B. Zhang, A. Zavabeti, A. Chrimes, F. Haque, L. O’Dell, H. Khan, Nitu Syed, R. Datta, Yichao Wang, A. Chesman, T. Daeneke, K. Kalantar-zadeh, J. Ou (2018)
Degenerately Hydrogen Doped Molybdenum Oxide Nanodisks for Ultrasensitive Plasmonic BiosensingAdvanced Functional Materials, 28
G. Tarabella, F. Mohammadi, N. Coppedé, Francesco Barbero, S. Iannotta, C. Santato, F. Cicoira (2013)
New opportunities for organic electronics and bioelectronics: ions in actionChemical Science, 4
R. Pethig, Stewart Smith (2012)
Introductory Bioelectronics: For Engineers and Physical Scientists
Elizabeth Paul, A. Ricco, M. Wrighton (1985)
Resistance of polyaniline films as a function of electrochemical potential and the fabrication of polyaniline-based microelectronic devicesThe Journal of Physical Chemistry, 89
S. Inal, J. Rivnay, P. Leleux, Marc Ferro, M. Ramuz, Johannes Brendel, Martina Schmidt, M. Thelakkat, G. Malliaras (2014)
A High Transconductance Accumulation Mode Electrochemical TransistorAdvanced Materials, 26
A. Green, A. Woodhead
CCXLIII.—Aniline-black and allied compounds. Part IJournal of The Chemical Society, Transactions, 97
D. Nilsson, N. Robinson, M. Berggren, R. Forchheimer (2005)
Electrochemical Logic CircuitsAdvanced Materials, 17
O. Parlak, A. Salleo, A. Turner (2019)
Wearable Bioelectronics
D. Nilsson, Miaoxiang Chen, T. Kugler, T. Remonen, M. Armgarth, M. Berggren (2002)
Bi-stable and dynamic current modulation in electrochemical organic transistorsAdvanced Materials, 14
G. Hadziioannou, P. Hutten (2005)
Semiconducting polymers: chemistry, physics and engineering
N. Claudio (2016)
Molecular Bioelectronics: The 19 Years of Progress
R. Gupta, Anuj Kumar (2022)
Bioelectronics
A. Håkansson, Shaobo Han, Suhao Wang, Jun Lu, S. Braun, M. Fahlman, M. Berggren, X. Crispin, S. Fabiano (2017)
Effect of (3-glycidyloxypropyl)trimethoxysilane (GOPS) on the electrical properties of PEDOT:PSS filmsJournal of Polymer Science Part B, 55
Scientific and Industrial History of Aniline Black
Per-Olof Svensson, D. Nilsson, R. Forchheimer, M. Berggren (2008)
A sensor circuit using reference-based conductance switching in organic electrochemical transistorsApplied Physics Letters, 93
Advanced Materials Technologies – Wiley
Published: Mar 1, 2020
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