An electrochemical protein chip was microfabricated. A thin-film three-electrode system, including an array of 36 platinum working electrodes, a set of thin-film Ag/AgCl electrodes, and platinum auxiliary electrodes, was integrated on a glass substrate. Capture antibodies were immobilized in a 4.5-nm-thick double layer of a hexamethyldisiloxane plasma-polymerized film. Because of their highly cross-linked network structure, the capture antibodies could be firmly immobilized. No nonspecific adsorption was observed during a series of procedures to detect target proteins, and electrochemical cross talk between neighboring sites was negligible. The sandwich immunoassay was conducted on a single chip using model proteins, alpha-1-fetoprotein and beta2-microglobulin. A distinct current increase following the oxidation of hydrogen peroxide produced by the enzymatic reaction of glucose oxidase was observed, which indicates that the capture proteins could actually bind the target proteins. Two kinds of protein were detected independently on multiple sites with respective capture antibodies.
We propose a simple thin-film glucose biosensor based on a plasma-polymerized film. The film is deposited directly onto the substrate under dry conditions. The resulting films are extreme thin, adhere well onto the substrate (electrode), and have a highly cross-linked network structure and functional groups, such as amino groups, which enable a large amount of enzyme to be immobilized. Since this design allows fabrication through a dry process, with the exception of the enzyme immobilization, which is the last stage of the process, the chip fabrication can be designed as a full-wafer process to achieve mass production compatibility. The resulting sensors produced using this film are more reproducible, exhibit lower noise, and reduce the effect of interference to a greater degree than sensors made using conventional immobilization methods, e.g., via 3-(aminopropyl)triethoxysilane. The obtained film is a good interfacial design between enzyme and electrode; enzyme two-dimensionally locates very close to the electrode in a manner that is quite reproducible. Therefore, a wide dynamic range (up to 60 mM) and rapid response time (11.5+/-0.8 s) were obtained. Because of its highly cross-linking network structure, the amperometric response due to interferences such as ascorbic acid and acetaminophen was reduced by size discrimination of plasma-polymerized films.
The flavoenzymes flavin adenine dinucleotidedependent glucose dehydrogenase (FAD-GDH) and oxidase (FAD-GOx) do not undergo direct electron transfer (DET) at conventional electrodes, because the flavin adenine dinucleotide (FAD) cofactor is buried deeply (∼1.4 nm) below the protein surface. We present a mediator-less DET between oxygeninsensitive FAD-GDH and single-walled carbon nanotubes (SWCNTs). A glucose-concentration-dependent current (GCDC) is observed at the electrode with the combination of glycosylated FAD-GDH and debundled SWCNTs; the GCDC, because of an increase in the polarized potential during potential sweep voltammetry, increases steeply (+0.1 V of onset, 1.2 mA cm −2 at +0.6 V 48 mM glucose) without the appearance of the FAD redox peak at −0.45 V. In the control experiment, the GCDC is not observed at the counterpart with either bundled SWCNTs or debundled multiwalled carbon nanotubes (MWCNTs). In the control experiment, the GCDC is observed at an analogous electrode based on oxygen-sensitive FAD-GOx with all CNT types (bundled SWCNTs, debundled SWCNTs, and debundled MWCNTs) in the presence of oxygen because oxygen acts as a natural and mobile mediator. Therefore, observation of the GCDC at the electrode with oxygen-insensitive FAD-GDH and debundled SWCNTs provides evidence of mediator-less DET, even though oxygen is present. Details of the DET are discussed with respect to the recently reported crystallographic model of FAD-GDH. The three-dimensional globular FAD-GDH molecule is 4.5 nm × 5.6 nm × 7.8 nm, which is larger than the 1.2 nm diameter of an individual SWCNT and smaller than the 10 nm diameter of an individual MWCNT and the 1 μm size of a SWCNT bundle. Only individual SWCNTs can be plugged into the groove of FAD-GDH, which is close to and within 1.0 nm of FAD, while maintaining their catalytic activity. Images obtained using transmission electron and atomic force microscopies support the stated configuration of FAD-GDH molecules and debundled SWCNTs. We demonstrate that DET can be explained by quantum tunneling theory. Electrochemical experiments with various FAD-GDHs suggest that (i) DET with debundling SWCNT can be applied to any type of FAD-GDH, (ii) the electrode with various types of FAD-GDH implements superior functions (compared to an analogous electrode with FAD-GOx and nicotineamide adenine dinucleotide-GDH), and (iii) glycan chains present on FAD-GDH prevent denaturation when the SWCNT is close to FAD.
The first use of plasma polymerization technique to modify the surface of a glass chip for capillary isoelectric focusing (cIEF) of different proteins is reported. The electrophoresis separation channel was machined in Tempax glass chips with length 70 mm, 300 microm width and 100 microm depth. Acetonitrile and hexamethyldisiloxane monomers were used for plasma polymerization. In each case 100 nm plasma polymer films were coated onto the chip surface to reduce protein wall adsorption and minimize the electroosmotic flow. Applied voltages of 1000 V, 2000 V and 3000 V were used to separate mixtures of cytochrome c (pI 9.6), hemoglobin (pI 7.0) and phycocyanin (pI 4.65). Reproducible isoelectric focusing of each pI marker protein was observed in different coated capillaries at increasing concentration 2.22-5 microg microL(-1). Modification of the glass capillary with hydrophobic HMDS plasma polymerized films enabled rapid cIEF within 3 min. The separation efficiency of cytochrome c and phycocyanin in both acrylamide and HMDS coated capillaries corresponded to a plate number of 19600 which compares favourably with capillary electrophoresis of neurotransmitters with amperometric detection.
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