Method of determination of fluorescent substance and method of assay of enzyme activity
| Title: | Method of determination of fluorescent substance and method of assay of enzyme activity |
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| Patent Number: | 5,792,662 |
| Publication Date: | August 11, 1998 |
| Appl. No: | 08/842,405 |
| Application Filed: | April 24, 1997 |
| Abstract: | A method for determining a fluorescent substance in a broader concentration range with higher measurement accuracy is provided which is applicable to assay of enzyme activity in enzyme-label immunoassay, enzyme-label DNA hybridization, etc. A method for assaying enzyme activity is also provided which employs the above fluorescence measurement. In the method, a specimen containing an objective fluorescent substance to be determined and a reference substance is irradiated with excitation light capable of exciting both the objective fluorescent substance and the reference fluorescent substance; measuring a first fluorescence intensity at a first wavelength where fluorescence is emitted mainly by the objective fluorescent substance; measuring a second fluorescence intensity at a second wavelength where fluorescence is emitted mainly by the reference fluorescent substance; and calculating the concentration of the objective fluorescent substance from the equation: [equation included] where x is the concentration of the objective fluorescent substance, and y is a ratio of the first fluorescence intensity to the second fluorescence intensity. |
| Inventors: | Hayashi, Hidechika (Kanagawa, JPX); Kamata, Kazuya (Toyama, JPX) |
| Assignees: | Tosoh Corporation (Shinnanyo, JPX) |
| Claim: | What is claimed is |
| Claim: | 1. A method for determining the concentration of a fluorescent substance, comprising adding a known amount of a reference fluorescent substance to a specimen containing an objective fluorescent substance to be determined; irradiating the specimen with excitation light capable of exciting both the objective fluorescent substance and the reference fluorescent substance; measuring a first fluorescence intensity at a first wavelength where fluorescence is emitted mainly by the objective fluorescent substance; measuring a second fluorescence intensity at a second wavelength where fluorescence is emitted mainly by the reference fluorescent substance; and calculating the concentration of the objective fluorescent substance from the equation: [equation included] |
| Claim: | where x is the concentration of the objective fluorescent substance, y is a ratio of the first fluorescence intensity to the second fluorescence intensity, and a, b and c are constants determined by measuring fluorescence intensities of reference specimens containing at least three different concentrations of the objective fluorescent substance. |
| Claim: | 2. A method for assaying activity of an enzyme by measuring change with time of concentration of an objective fluorescent substance by action of the enzyme, comprising adding a known concentration of a reference fluorescent substance to a specimen containing an objective fluorescent substance to be determined; irradiating the specimen with excitation light capable of exciting both the objective fluorescent substance and the reference fluorescent substance; measuring a first fluorescence intensity at a first wavelength where fluorescence is emitted mainly by the objective fluorescent substance; measuring a second fluorescence intensity at a second wavelength where fluorescence is emitted mainly by the reference fluorescent substance; calculating the concentration of the objective fluorescent substance from the equation |
| Claim: | where x is the concentration of the objective fluorescent substance, y is a ratio of the first fluorescence intensity to the second fluorescence intensity, and a, b and c are constants determined by measuring fluorescence intensities of reference specimens containing at least three different concentrations of the objective fluorescent substance; and deriving the activity of the enzyme or the concentration of the enzyme from the change with time of the value of x. |
| Claim: | 3. The method according to claim 1 or claim 2, wherein the fluorescence intensities of reference specimens contain three different known concentrations (x=x.sub.1, x=x.sub.2, and x.sub.3) of the objective fluorescent substance and a fixed concentration of a reference fluorescent substance are measured to obtain the first fluorescence intensities and the second fluorescence intensities at the respective concentrations, the ratios of the first fluorescent intensity to the second fluorescence intensity at the respective concentrations (y.sub.1, y.sub.2, and y.sub.3) are derived, and therefrom a, b, and c in the conversion formula, 1/(y-c)=a/x+b, are determined, and thereby calculating the value of x. |
| Claim: | 4. The method according to claim 1 or claim 2, wherein the fluorescence intensities of reference specimens contain three different known concentrations including concentration of zero (x=0, x=x.sub.1 and x=x.sub.2) of the objective fluorescent substance and a find concentration of a reference fluorescent substance are measured to obtain the first fluorescence intensities and the second fluorescence intensities at the respective concentrations, the ratios of the first fluorescent intensity to the second fluorescence intensity at the respective concentrations (y.sub.0, y.sub.1, and y.sub.2) are derived, and therefrom, a and b in the conversion formula are determined, by letting c=y.sub.0 and solving the simultaneous equations: 1/(y.sub.1 -c)=a/x.sub.1 +b, and 1/(y.sub.2 -c)=a/x+b, and thereby calculating the value of x according to the equation: 1/(y-c)=a/x+b. |
| Claim: | 5. The method according to claim 1 or claim 2, wherein the fluorescence intensities of reference specimens containing four or more different known concentrations including concentration of zero (x=0, x=x.sub.1, x=x.sub.2, . . . , x.sub.n, where n is an integer of 3 or more) of the objective fluorescent substance and a fixed concentration of a reference fluorescent substance are measured to obtain the first fluorescence intensities and the second fluorescence intensities at the respective concentrations, the ratios of the first fluorescent intensity to the second fluorescence intensity at the respective concentrations (y.sub.0, y.sub.1, y.sub.2, . . . , y.sub.n) are derived, a and b in the conversion formula are determined by least square regression to Y=aX+b with weighting of data sets of (X.sub.i, Y.sub.i) where c=y.sub.0, Y.sub.i =1/(y.sub.i -c), and X.sub.i =1/x.sub.i with factors which increase with increase of x.sub.i, and calculating the value of x according to the equation: 1/(y-c)=a/x+b. |
| Current U.S. Class: | 436/8; 436/172; 435/4; 2504/591 |
| Current International Class: | G01N 2164 |
| Patent References Cited: | 4788138 November 1988 Tung et al. 4990784 February 1991 Dukes et al. 5460943 October 1995 Hayashi et al. |
| Other References: | Mickley, H.S. et al. "Applied Mathematics in Chemical Engineering" Second Edition, McGraw Hill Book Company, New York, pp. 8-15 (1957). |
| Primary Examiner: | Snay, Jeffrey |
| Attorney, Agent or Firm: | Oblon, Spivak, McClelland, Maier & Neustadt, P.C. |
| Accession Number: | edspgr.05792662 |
| Database: | USPTO Patent Grants |
| Language: | English |
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