Immunoassay labelling reactions

Chemiluminescent labels may be employed in sandwich or competitive antigen assays. In sandwich assays, a solid support holds a primary antibody, and incubation with ligand yields a species that is detectable following a second incubation step with a labeled second antibody. Luminol has been tested as an immunoassay label it may be coupled to proteins through its primary amino group. Luminol reacts with hydrogen peroxide and hydroxide in a microperoxidase-catalyzed reaction, which yields light at 430 nm (Eq. 6.8) ... 

Our hollow cylindrical waveguide structure has also been coated with a human h-IgG antibody enzyme and used to detect a fluorescent labeled antigen Ag /OyB in a immunoassay-type reaction. 

Numerous applications involve coupling liquid-phase chemiluminescence detection to physical or chemical separation processes. Conversely, adequate selectivity can also be achieved for particular analytes in a range of sample matrices through a judicious selection of reagent and reaction conditions. Successful detection strategies have been employed for HPLC, flow analysis, electrophoresis, immunoassay labels, DNA probes, and enzyme reactions. 

In fact, most RIAs and many nonisotopic immunoassays use a competitive binding format (see Fig. 2). In this approach, the analyte in the sample to be measured competes with a known amount of added analyte that has been labeled with an indicator that binds to the immobilized antibody. After reaction, the free analyte—analyte-indicator solution is washed away from the soHd phase. The analyte-indicator on the soHd phase or remaining in the wash solution is then used to quantify the amount of analyte present in the sample as measured against a control assay using only an analyte-indicator. This is done by quantifying the analyte-indicator using the method appropriate for the assay, for example, enzyme activity, fluorescence, radioactivity, etc. 

In the most common method for chemiluminescent immunoassay (GLIA), after the immunological reaction and any necessary separation steps, the labeled compounds or complexes react with an oxidizer, eg, hydrogen peroxide, and an enzyme, eg, peroxidase, or a chelating agent such as hemin or metal... 

ImmunO lSS iy. Chemiluminescence compounds (eg, acridinium esters and sulfonamides, isoluminol), luciferases (eg, firefly, marine bacterial, Benilla and Varela luciferase), photoproteins (eg, aequorin, Benilld), and components of bioluminescence reactions have been tested as replacements for radioactive labels in both competitive and sandwich-type immunoassays. Acridinium ester labels are used extensively in routine clinical immunoassay analysis designed to detect a wide range of hormones, cancer markers, specific antibodies, specific proteins, and therapeutic dmgs. An acridinium ester label produces a flash of light when it reacts with an alkaline solution of hydrogen peroxide. The detection limit for the label is 0.5 amol. 

Enzyme Immunosensors. Enzyme immunosensors are enzyme immunoassays coupled with electrochemical sensors. These sensors (qv) require multiple steps for analyte determination, and either sandwich assays or competitive binding assays maybe used. Both of these assays use antibodies for the analyte of interest attached to a membrane on the surface of an electrochemical sensor. In the sandwich assay type, the membrane-bound antibody binds the sample antigen, which in turn binds another antibody that is enzyme-labeled. This immunosensor is then placed in a solution containing the substrate for the labeling enzyme and the rate of product formation is measured electrochemically. The rate of the reaction is proportional to the amount of bound enzyme and thus to the amount of the analyte antigen. The sandwich assay can be used only with antigens capable of binding two different antibodies simultaneously (53). 

Instead of immobilizing the antibody onto the transducer, it is possible to use a bare (amperometric or potentiometric) electrode for probing enzyme immunoassay reactions (42). In this case, the content of the immunoassay reaction vessel is injected to an appropriate flow system containing an electrochemical detector, or the electrode can be inserted into the reaction vessel. Remarkably low (femtomolar) detection limits have been reported in connection with the use of the alkaline phosphatase label (43,44). This enzyme catalyzes the hydrolysis of phosphate esters to liberate easily oxidizable phenolic products. 

Chemiluminescence reactions are currently exploited mainly either for analyte concentration measurements or for immunoanalysis and nucleic acid detection. In the latter case, a compound involved in the light emitting reaction is used as a label for immunoassays or for nucleic acid probes. In the former case, the analyte of interest directly participates in a chemiluminescence reaction or undergoes a chemical or an enzymatic transformation in such a way that one of the reaction products is a coreactant of a chemiluminescence reaction. In this respect, chemiluminescent systems that require H2O2 for the light emission are of particular interest in biochemical analysis. Hydrogen peroxide is in fact a product of several enzymatic reactions, which can be then coupled to a chemiluminescent detection. 

Immunoassay analysis of the extracts was performed using Syva assay kits and an AutoLab system. The extract (50 /jL) and assay buffer (250 /jL) were delivered into a reaction cup, followed by 50 jiL reagent A (antibody and substrate) plus another 250 /uL assay buffer, incubated for 50 sec, and mixed with 50 /./I. reagent B (drug-labeled enzyme) plus 250 /uL assay buffer. The change in absorbance of this final mixture was monitored at a wavelength of 340 nm by a spectrophotometer. 

Other immunoassays are based on the same antibody-antigen binding reaction but use a different labeling system for detection. Instead of an enzyme label, there are radioactive isotopes, and fluorescent and luminescent labels. Some important immunoassays are defined below ... 

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