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- Title
High Precision, Electrochemical Detection of Reversible Binding of Recombinant Proteins on Wide Bandgap GaN Electrodes Functionalized with Biomembrane Models.
- Authors
Frenkel, Nataliya; Wallys, Jens; Lippert, Sara; Teubert, Jörg; Kaufmann, Stefan; Das, Aparna; Monroy, Eva; Eickhoff, Martin; Tanaka, Motomu
- Abstract
We report a novel hybrid charge sensor realized by the deposition of phospholipid monolayers on highly doped n-GaN electrodes. To detect the binding of recombinant proteins with histidine-tags, lipid vesicles containing chelator lipids were deposited on GaN electrodes pre-coated with octadecyltrimethoxysilane monolayers. Owing to its optical transparency, GaN allows the confirmation of the fluidity of supported membranes by fluorescence recovery after photo-bleaching (FRAP). The electrolyte-(organic) insulator-semiconductor (EIS) setup enables one to transduce variations in the surface charge density Δ Q into a change in the interface capacitance Δ Cp and, thus, the flat-band potential Δ UFB. The obtained results demonstrate that the membrane-based charge sensor can reach a high sensitivity to detect reversible changes in the surface charge density on the membranes by the formation of chelator complexes, docking of eGFP with histidine tags, and cancellation by EDTA. The achievable resolution of Δ Q ≥ 0.1 μC/cm2 is better than that obtained for membrane-functionalized p-GaAs, 0.9 μC/cm2, and for ITO coated with a polymer supported lipid monolayer, 2.2 μC/cm2. Moreover, we examined the potential application of optically active InGaN/GaN quantum dot structures, for the detection of changes in the surface potential from the photoluminescence signals measured at room temperature.
- Subjects
RECOMBINANT proteins; PROTEIN binding; ELECTROCHEMISTRY; OPTICAL properties of gallium nitride; BAND gaps
- Publication
Advanced Functional Materials, 2014, Vol 24, Issue 31, p4927
- ISSN
1616-301X
- Publication type
Article
- DOI
10.1002/adfm.201400388