Organic field-effect transistor for label-free dopamine sensing
about
Graphene Paper Decorated with a 2D Array of Dendritic Platinum Nanoparticles for Ultrasensitive Electrochemical Detection of Dopamine Secreted by Live CellsBoronic acids for sensing and other applications - a mini-review of papers published in 2013.High performing solution-coated electrolyte-gated organic field-effect transistors for aqueous media operation.Printable Bioelectronics To Investigate Functional Biological Interfaces.Self-assembled monolayers in organic electronics.Capacitance-modulated transistor detects odorant binding protein chiral interactionsOrganic ultra-thin film transistors with a liquid gate for extracellular stimulation and recording of electric activity of stem cell-derived neuronal networks.Electrical release of dopamine and levodopa mediated by amphiphilic β-cyclodextrins immobilized on polycrystalline gold.In situ probing electronic dynamics at organic bulk heterojunction/aqueous electrolyte interfaces by charge modulation spectroscopy.Selective ion-sensing with membrane-functionalized electrolyte-gated carbon nanotube field-effect transistors.Label-free C-reactive protein electronic detection with an electrolyte-gated organic field-effect transistor-based immunosensor.Electrolyte-Gated Organic Field-Effect Transistor Based on a Solution Sheared Organic Semiconductor Blend.Precursor-route ZnO films from a mixed casting solvent for high performance aqueous electrolyte-gated transistors.UV crosslinked poly(acrylic acid): a simple method to bio-functionalize electrolyte-gated OFET biosensorsHigh Performance Organic Field-Effect Transistors with Solid and Aqueous Dielectric Based on a Solution Sheared Sulfur-Bridged Annulene DerivativeWater-gated organic field effect transistors – opportunities for biochemical sensing and extracellular signal transductionFacile maskless fabrication of organic field effect transistors on biodegradable substrates
P2860
Q28821867-517241AD-51B8-4358-8BE5-B403BF12622EQ30426687-FDE36F6D-B26C-4899-84FD-322B46926527Q36231065-74EAB465-B2BC-41DA-80F1-181623D68D3AQ38595507-B02CC903-EFE7-43CD-B297-CC45BFD2F873Q38976893-2A07DCC4-24F1-4B2D-9254-7A5C995A42DAQ41972254-C6210F62-195C-4574-91C7-68F5F5854BCEQ44632253-C3FABFA2-76FE-4430-8EAB-476D072122E3Q46639796-516169B8-D38E-4A06-9897-E9D9F3052570Q47241106-452F7C8C-840B-4A53-B488-25A0D90E384EQ51065333-C606F17D-CA20-4BCE-9E7A-BF7E9F425C7BQ51404388-54ECFB15-15E6-4498-8CE1-A15F35A7A3A4Q52886552-AF300E05-76F8-41EF-8CB4-DB2726268C07Q53810138-47134045-9326-4406-A78F-532185A6ADD1Q57377082-7AF28205-3776-40E5-8835-CB22D910AFA4Q58237054-51BAC953-DCA4-4717-8508-4C9632898474Q58237065-66E4F007-F333-4D4C-8265-C863B2C74F2EQ58237188-4B7AC2DF-C1F1-43F1-BCEB-FD6F1D2A354F
P2860
Organic field-effect transistor for label-free dopamine sensing
description
article
@en
wetenschappelijk artikel
@nl
наукова стаття, опублікована в січні 2013
@uk
name
Organic field-effect transistor for label-free dopamine sensing
@en
Organic field-effect transistor for label-free dopamine sensing
@nl
type
label
Organic field-effect transistor for label-free dopamine sensing
@en
Organic field-effect transistor for label-free dopamine sensing
@nl
prefLabel
Organic field-effect transistor for label-free dopamine sensing
@en
Organic field-effect transistor for label-free dopamine sensing
@nl
P50
P921
P1433
P1476
Organic field-effect transistor for label-free dopamine sensing
@en
P2093
Tobias Cramer
P304
P356
10.1016/J.ORGEL.2012.10.027
P577
2013-01-01T00:00:00Z