Method for chemiluminescent detection

Details Method for chemiluminescent detection Method for chemiluminescent detection

2002-07-16

2004-07-20

Leary, Louise N. (Department: 1654)

Chemistry: molecular biology and microbiology

Measuring or testing process involving enzymes or...

C435S021000, C435S028000, C435S968000, C435S975000

Reexamination Certificate

active

06764819

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates to chemiluminescent assays that incorporate a film which includes a chemiluminescent precursor component immobilized therewith which produces a triggerable chemiluminescent compound for detection of a target molecule.
BACKGROUND OF RELATED TECHNOLOGY
Recently a variety of non-isotopic labeling methods have been developed to replace radioactive labels in DNA probe-based assays. It is most common in such methods to use marker enzymes to detect nucleic acid probes using either colormetric, chemiluminescent, bioluminescent or fluorescent methods. Each of these methods have been used reliably for both hybridization of DNA probe-based assays for nucleic acid detection as well as in solid-phase immunochemical assays wherein the target molecule is typically an antigen of interest.
Regardless of the type of non-isotopic detection method used, the labels are typically measured directly with fluorophores (without use of enzymes) or indirectly using enzyme amplification schemes. A clear advantage of an indirect labeling scheme is the increased sensitivity one achieves through enzymatic amplification of the signal. However, a disadvantage of such methods as they are currently practiced in the field is that many steps are required in the assay protocol, requiring more time to complete the assay. Moreover, a greater number of reagents are required which means greater cost. In addition, where the method of detection is enzyme-based, the enzyme's activity, stability and its shelf life need to be considered if one is to expect optimum performance of the assay.
Chemiluminescence detection relies on a chemical reaction that generates light. It is this method which is now widely used for both nucleic acid detection as well as solid-based immunodetection due to its high sensitivity and wide variety of analysis methods ranging from manual film reading to instrumentation for processing images. Most commercially available chemiluminescent detection systems employ enzyme conjugates to increase detection sensitivity through amplification of the signal and, therefore, suffer from the same disadvantages described above.
In view of the simplicity of chemical reactions relative to enzymatic reactions, it would be desirable to achieve chemiluminescent signal amplification by chemical as opposed to enzymatic means. Moreover, non-enzymatic systems have the advantage over enzyme-mediated systems of faster kinetics which result in peak light output within seconds. U.S. Pat. No. 5,516,636 to McCapra and a later publication by Schubert (Nucleic Acids Research, 1995, Vol. 23, No. 22 p. 4657) describe the use of sensitizer-labeled oligonucleotide probes for the detection of nucleic acid target molecules. In a solid phase DNA probe assay, a DNA target molecule is bound to a membrane and hybridized to a sensitizer-labeled oligonucleotide complementary in sequence to the target DNA. The membrane is subsequently contacted with an olefin. Upon exposure of the membrane to ambient oxygen and light, the sensitizer molecules become excited and transfer their excess energy to ambient oxygen for formation of singlet oxygen. The singlet oxygen therein produced reacts with the olefin on the membrane to form a stable 1,2-dioxetane in the area of the hybridization zone which when subsequently exposed to heat, chemical treatment or enzymatic treatment decomposes to emit light. Thus, oligonucleotides labeled with sensitizer are able to amplify the dioxetane concentration based on repeated excitation/oxygen quenching cycles to achieve a high level of sensitivity.
Prior art chemiluminescent assays employing sensitizers have generally required that a sensitizer-labeled probe hybridized to an analyte on a membrane be brought in contact with olefin for reaction to form a decomposable dioxetane. The membrane containing the analyte is then triggered by an activating source (e.g. base and/or heat) to produce a signal. The disadvantage of this format is that, because the analyte must be subjected to heat and/or base, it is not further utilized for additional testing and analysis.
U.S. Pat. No. 6,143,514 discloses a matrix having incorporated therein a label capable of being modified by a singlet oxygen and a non-photoactivatable catalyst (e.g. an enzyme) that is capable of catalyzing the formation of singlet oxygen from hydrogen peroxide. The catalyst coated matrix is incubated with assay medium suspected of containing hydrogen peroxide to permit the hydrogen peroxide to react with the catalyst to form singlet oxygen. The reaction of singlet oxygen with the label is determined, the reaction thereof indicating the presence of a compound capable of generating hydrogen peroxide. One disadvantage of this assay is that, because it is enzyme-based, the activity of the enzyme, its stability and its shelf-life need to be monitored as discussed above.
It would be advantageous to provide a method of performing a sensitizer-mediated solid phase chemiluminescent assay which would allow for reuse of a membrane-bound analyte. This is particularly desirable when amounts of available analyte for testing are limited. Such a method would preferably employ a membrane containing a solid olefin immobilized on or impregnated with, the membrane being suitable for use in both solid phase nucleic acid assays and immunoassays and, further, being able to be analyzed by methods ranging from manual film reading to instrumentation for processing images.
SUMMARY OF THE INVENTION
In one aspect of the invention, there is provided a film component for chemiluminescent assays including a solid film substrate and at least one chemiluminescent precursor immobilized therewith which produces a triggerable chemiluminescent compound, the film component being free of compounds which generate singlet oxygen and being adapted for use with a sensitizer-labeled analyte or a sensitizer-labeled agent probative of the analyte.
The invention further provides a method of detecting target molecules using chemiluminescence, the method including the steps of: (a) providing a first film having a complex that includes a target molecule bound to a sensitizer or a sensitizer-labeled probe; (b) providing a second film comprising at least one solid chemiluminescent precursor component immobilized therewith that is capable of producing a triggerable chemiluminescent compound; (c) placing the first and second films in sufficient proximity to each other to permit singlet oxygen produced from excitation of the sensitizer on the first film and to react with the chemiluminescent precursor on the second film; (d) exposing the films to suitable conditions (e.g., light and oxygen) to form the triggerable chemiluminescent compound on the second film; (e) allowing the triggerable chemiluminescent compound to be triggered by an activating source to produce a detectable light signal on the second film; and (f) detecting and/or recording the resultant signal on the second film.
Furthermore, another aspect of the present invention relates to a method of preparing a chemiluminescent assay that includes the steps of: (a) providing a first film having a complex that includes a target molecule bound to a sensitizer or a sensitizer-labeled probe; (b) providing a second film including at least one solid chemiluminescent precursor component immobilized therewith that is capable of producing a triggerable chemiluminescent compound; (c) positioning the first and second films in overlapping contact with each other; (d) exposing the contacted films to suitable conditions (e.g., light and oxygen) to form the triggerable chemiluminescent compound on the second film; and (e) allowing the triggerable chemiluminescent compound to be triggered by an activating source to produce a detectable light signal on the second film.
Also provided is a chemiluminescent assay kit that includes: (a) a film component including a solid film substrate and at least one chemiluminescent precursor immobilized therewith that is capable of producing a triggerable chemiluminescent compound, the

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