Tiina Ylinen’s research while affiliated with Åbo Akademi University and other places

The basic principles of cathodic hot electron-induced electrochemiluminescence (HECL) and hot electron (HE) injection into aqueous electrolyte solution are shortly discussed. The applicability of miniaturized oxide-coated silicon electrodes as working electrodes in detection of electrochemiluminescent labels by HECL is studied. In addition, the fabrication processes of these tunnel oxide electrodes are described, and an immunoassay is used as an example of a real bioaffinity assay carried out using oxide-coated silicon electrodes.

Synthesis, purification and characterization of [4-ethoxycarbonyl-40-carboxy-2,20-bipyridine]bis(2,2’-bipyridine) ruthenium(II) hexafluorophosphate is described. This complex is shown to be electrochemiluminescent in aqueous solution during cathodic pulse polarization of thin insulating film-coated electrodes. Electrochemiluminescence (ECL) lifetime of the complex was observed to be ca. 40 ms at oxide-coated n-silicon electrodes; thus time-resolved detection is also possible. The ECL emission maximum of this carboxylate derivative is somewhat red-shifted when compared with an unmodified Ru(bpy)3 2+. Because the present complex can be easily covalently coupled with antibodies and oligonucleotides it is usable as an electrochemiluminescent label in various bioaffinity assays. The present chelates also produce strong chemiluminescence during dissolution of metallic magnesium in aqueous solution.

Electrochemiluminescence (ECL) of aromatic Tb(III) chelates at thin insulating film-coated electrodes provides a means for extremely sensitive detection of Tb(III) chelates and also of biologically interesting compounds if these chelates are used as labels in bioaffinity assays. The suitability of silicon electrodes coated with thermally grown silicon dioxide film as disposable working electrodes in sensitive time-resolved ECL measurements is demonstrated, and a rapid electrochemiluminoimmunoassay (ECLIA) of human C-reactive protein (hCRP) is described. Tb(III) chelate labels can be detected almost down to picomolar level, and the calibration curve of these labels covers more than 6 orders of magnitude of chelate concentration. The calibration curve of the present immunometric hCRP assay was found to be linear over a wide range, approximately 4 orders of magnitude of hCRP concentration, the detection limit of the protein being 0.3 ng mL(-1) (mean background + 2SD) on CV values of about 10-30%, depending on the immunoassay incubation time. In the ECLIA measurements, different incubation times were tested from 15 min (giving above-mentioned performance) to as short as only 2 min, which still gave successful results with approximately 20,000 times better detection limit levels than traditional commercial assay methods. During the ECLIA process, also the Si electrode surface morphology was also investigated by atomic force microscope monitoring.

Strong electrogenerated chemiluminescence (ECL) of fluorescein is generated during cathodic pulse polarization of oxide-covered aluminum electrodes and the resulting decay of emission is so sluggish that time-resolved detection of fluorescein is feasible. The present ECL in aqueous solution is based on the tunnel emission of hot electrons into the aqueous electrolyte solution, which probably results in the generation of hydrated electrons and hydroxyl radicals acting as redox mediators. The successive one-electron redox steps with the primary radicals result in fluorescein in its lowest excited singlet state. The method allows the detection of fluorescein (or its derivatives containing usable linking groups to biomolecules) over several orders of magnitude of concentration with detection limits well below nanomolar concentration level. The detection limits can still be lowered, e.g., by addition of azide or bromide ions as coreactants. The results suggest that the derivatives of fluorescein, such as fluorescein isothiocyanate (FITC), can be detected by time-resolved measurements and thus be efficiently used as electrochemiluminescent labels in bioaffinity assays.

Strong electrogenerated chemiluminescence (ECL) of fluorescein is generated in aqueous solution during cathodic pulse polarization of oxide-covered aluminum electrodes. The present method is based on the injection of hot electrons into the aqueous electrolyte solution, which probably results in the generation of hydrated electrons as reducing mediators. The successive one-electron redox reactions result in fluorescein in its lowest excited singlet state, i.e., the emission spectrum is similar to the corresponding fluorescence emission spectrum. This ECL can be enhanced by added coreactants, e.g., by peroxodisulfate, peroxodiphosphate, hydrogen peroxide and azide ions. The method can detect fluorescein over several orders of magnitude of concentration with detection limit below nanomolar concentration level in the presence of azide ions. The results suggest that the derivatives of fluorescein, such as fluorescein isothiocyanate, can be used as electrochemiluminescent labels in aqueous solution in bioaffinity assays carried out on the surface of thin aluminum oxide film-coated aluminum electrodes. This cathodic ECL is mainly based on the one-electron oxidation of fluorescein by the cathodically produced oxidizing radicals followed by reduction of the formed semioxidized fluorescein by hot or hydrated electrons back to the original oxidation state which finally emits light.