A glucose monitoring method and a glucose sensor, both of which use glucose dehydrogenase having a Michaelis constant (Km) for xylose of 600 mM or more and 3000 mM or less, and a Km for glucose of 0.1 mM or more and 100 mM or less, which provide for evaluating FADGDH in an aqueous system while reducing the practical influence of FADGDH on D-xylose.

A glucose monitoring method and a glucose sensor, both of which use glucose dehydrogenase having a Michaelis constant (Km) for xylose of 600 mM or more and 3000 mM or less, and a Km for glucose of 0.1 mM or more and 100 mM or less, which provide for evaluating FADGDH in an aqueous system while reducing the practical influence of FADGDH on D-xylose.

An agent according to the present invention comprises as an effective component any of (1) disulfiram, diethyldithiocarbamate, or a metal complex of diethyldithiocarbamate; (2) a pharmaceutically acceptable salt of (1); or (3) a solvate of (1) or (2), and is used for inhibition of interaction between CR2B or CCR5 and FROUNT protein, inhibition of macrophages, control of cells constituting a cancer microenvironment or inflammatory microenvironment, or enhancement of anticancer activity of an anticancer drug. It is also possible to provide a compound with a reduced side effect and an increased pharmacological effect by identifying a disulfiram derivative having a lower aldehyde dehydrogenase-inhibiting activity and a higher FROUNT-inhibiting activity among derivatives prepared by structural modification of disulfiram.

An agent according to the present invention comprises as an effective component any of (1) disulfiram, diethyldithiocarbamate, or a metal complex of diethyldithiocarbamate; (2) a pharmaceutically acceptable salt of (1); or (3) a solvate of (1) or (2), and is used for inhibition of interaction between CR2B or CCR5 and FROUNT protein, inhibition of macrophages, control of cells constituting a cancer microenvironment or inflammatory microenvironment, or enhancement of anticancer activity of an anticancer drug. It is also possible to provide a compound with a reduced side effect and an increased pharmacological effect by identifying a disulfiram derivative having a lower aldehyde dehydrogenase-inhibiting activity and a higher FROUNT-inhibiting activity among derivatives prepared by structural modification of disulfiram.

The present invention pertains to an enzymatic measurement method using an antibody-enzyme complex or a nucleic acid probe measurement method using an enzyme-labeled nucleic acid probe, in both of which the quantification of a product of a reaction by an enzyme in the antibody-enzyme complex or the enzyme-labeled nucleic acid probe is performed by generating thio-NAD(P)H by an enzymatic cycling reaction using NAD(P)H, thio-NAD(P), and a dehydrogenase (DH), and measuring the amount of the generated thio-NAD(P)H or measuring a change in color caused by the generated thio-NAD(P)H. An enzymatic reaction system in which NAD(P) generated from NAD(P)H by the enzymatic cycling reaction is selectively reduced, is caused to coexist with the enzymatic cycling reaction. The present invention also pertains to a kit for enzyme immunoassay, and a kit for nucleic acid probe measurement. In the enzymatic cycling reaction, the detection sensitivity is increased by increasing the amount of thio-NAD(P)H generated per unit time with respect to a predetermined amount of a substrate (reduced), and combining the same with an enzyme immunoassay, etc., enables quantification, etc., of a protein or nucleic acid with high sensitivity.

The present invention pertains to an enzymatic measurement method using an antibody-enzyme complex or a nucleic acid probe measurement method using an enzyme-labeled nucleic acid probe, in both of which the quantification of a product of a reaction by an enzyme in the antibody-enzyme complex or the enzyme-labeled nucleic acid probe is performed by generating thio-NAD(P)H by an enzymatic cycling reaction using NAD(P)H, thio-NAD(P), and a dehydrogenase (DH), and measuring the amount of the generated thio-NAD(P)H or measuring a change in color caused by the generated thio-NAD(P)H. An enzymatic reaction system in which NAD(P) generated from NAD(P)H by the enzymatic cycling reaction is selectively reduced, is caused to coexist with the enzymatic cycling reaction. The present invention also pertains to a kit for enzyme immunoassay, and a kit for nucleic acid probe measurement. In the enzymatic cycling reaction, the detection sensitivity is increased by increasing the amount of thio-NAD(P)H generated per unit time with respect to a predetermined amount of a substrate (reduced), and combining the same with an enzyme immunoassay, etc., enables quantification, etc., of a protein or nucleic acid with high sensitivity.

Described is a method for associating with the expression level of an AKR1C3 enzyme via the content of prostaglandin, and the use of screening for drug administration. In particular, the content of prostaglandin is measured to associate with the expression level of the AKR1C3 enzyme in a biological sample; and the change in the content and the change rate of the content of prostaglandin before and after administering interfering drugs are measured to associate with the expression level of the AKR1C3 enzyme in the biological sample.

Described is a method for associating with the expression level of an AKR1C3 enzyme via the content of prostaglandin, and the use of screening for drug administration. In particular, the content of prostaglandin is measured to associate with the expression level of the AKR1C3 enzyme in a biological sample; and the change in the content and the change rate of the content of prostaglandin before and after administering interfering drugs are measured to associate with the expression level of the AKR1C3 enzyme in the biological sample.

The present invention relates to methods of detecting a neural injury biomarker in a biological sample. The method includes subjecting a biological sample to an assay according to the present invention that produces a measurable signal and detecting the measurable signal. The presence or absence of the measurable signal indicates the presence or absence of the biomarker in the sample. The present invention also relates to methods of determining the state of a subject's neural injury. The present invention also relates to systems and devices useful in carrying out the methods of the present invention.

The present invention relates to methods of detecting a neural injury biomarker in a biological sample. The method includes subjecting a biological sample to an assay according to the present invention that produces a measurable signal and detecting the measurable signal. The presence or absence of the measurable signal indicates the presence or absence of the biomarker in the sample. The present invention also relates to methods of determining the state of a subject's neural injury. The present invention also relates to systems and devices useful in carrying out the methods of the present invention.