JP2017129381A - Reagent and method for measuring anti-glycolipid antibody in sample - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method that can obtain an accurate measurement result by allowing a highly sensitive measurement of an anti-glycolipid antibody in a sample by causing an antigen antibody reaction with a glycolipid antigen.SOLUTION: In the reagent and the method for measuring an anti-glycolipid antibody in a sample by causing an antigen antibody reaction of the antibody with a glycolipid antigen, the ion intensity is set to be 0.17 mol/L or lower.SELECTED DRAWING: None

Description

The present invention relates to measurement of an anti-glycolipid antibody in a sample using a glycolipid antigen.
The present invention is important in the glycolipid field, biochemical field, analytical chemistry field, clinical laboratory field, life science field, and the like, but is particularly important in the diagnosis of neurological diseases and the like.

Glycolipids have been known to be present in a large amount in nerve tissues, and it has been known that severe neurological symptoms occur when antibodies that react with glycolipids in nerve tissues are produced in body fluids. I came.
These autoantibodies are produced in the body against the pre-infected cells, which are known to cross-react with glycolipid antigens in nerve tissue and cause autoimmune neurological diseases that damage the nerves as autoantibodies. ing.

For example, an IgG-type anti-GM1a antibody that is one of antibodies against glycolipid antigens (anti-glycolipid antibodies) is known to be involved in motor neurological diseases such as acute axillary Guillain-Barre syndrome.
In the case of acute axillary Guillain-Barre syndrome, the bacterial body Campylobacter jejuni, which is known as a food poisoning organism, is pre-infected, and an antibody against a sugar chain structure part similar to GM1a on the lipopolysaccharide (LPS) of the bacterial body is produced in the body. (For example, nonpatent literature 1).
This antibody has been found to be found in blood (for example, Non-Patent Document 2 and Non-Patent Document 3).

Another anti-glycolipid antibody, IgG-type anti-GQ1b antibody, is involved in neurological diseases such as Fisher syndrome and Vickerstaff type brainstem encephalitis, and the findings are related to other central nervous system diseases such as brainstem infarction. Although similar, the treatment is quite different.
This antibody has also been found to be found in patient serum (for example, Non-Patent Document 4 and Non-Patent Document 5).
In addition, there are reports that anti-GD2 antibody, anti-GT1b antibody and anti-GQ1b antibody are elevated in sensory ataxia polyneuropathy, and that anti-sulfatide antibody is high in sensory neurological diseases.
There are also reports that antibodies that react with glycolipid antigens are detected from samples derived from cancer patients.

  As described above, at the research level, the relationship between various diseases and anti-glycolipid antibodies has been elucidated, and measurement by ELISA has been put to practical use as a method for measuring anti-glycolipid antibodies that can be used in clinical practice (for example, non-patented Reference 6).

However, the ELISA method used as a method for measuring anti-glycolipid antibodies has a problem that the sensitivity of the measurement is not sufficient depending on the specimen. For this reason, when trying to use the measured value of the anti-glycolipid antibody in the sample for the examination of the disease, there is a possibility that the diagnosis of the disease is mistaken.
Therefore, when measurement is performed by reacting an anti-glycolipid antibody in a sample with an antigen-antibody reaction with a glycolipid antigen, further improvement in measurement sensitivity has been desired.

Yuki et al. Exp. Med. 178, 1771-1775, 1993. A. J. et al. Kornberg et al., Ann. Neurol. 35, 234-237, 1994 L. H. Visser et al., Brain, 118, 841-847, 1995. Chiba et al., Ann. Neurol. 31, 677-679, 1992 Yuki et al. Neurol. Sci. 118, 83-87, 1993 Kotaka et al., Modern Media, Vol. 54, No. 3, pp. 82-86, 2008

  Accordingly, an object of the present invention is to provide a method capable of measuring an anti-glycolipid antibody in a sample by an antigen-antibody reaction with a glycolipid antigen with high sensitivity and obtaining an accurate measurement result.

  As a result of intensive studies aimed at solving the above problems, the present inventor determined the ionic strength in a measurement reagent and a measurement method for measuring an anti-glycolipid antibody in a sample by reacting with an antigen-antibody with a glycolipid antigen. It was found for the first time that the sensitivity of measurement can be improved by setting it to 0.17 mol / L or less, and the present invention has been completed.

That is, the present invention provides the following inventions.
(1) A measuring reagent for measuring an anti-glycolipid antibody in a sample by reacting an antigen-antibody with a glycolipid antigen, wherein the ionic strength is 0.17 mol / L or less.
(2) The measuring reagent according to (1), wherein the glycolipid antigen is a ganglioside antigen.
(3) The measuring reagent according to (1) or (2) above, wherein the glycolipid antigen is immobilized on a carrier.
(4) In the method of measuring an anti-glycolipid antibody in a sample by reacting with a glycolipid antigen and an antigen-antibody, the ionic strength at the time of the antigen-antibody reaction is 0.17 mol / L or less, Measuring method to do.
(5) The measuring method according to (4) above, wherein the glycolipid antigen is a ganglioside antigen.
(6) The measurement method according to (4) or (5) above, wherein the glycolipid antigen is immobilized on a carrier.

  According to the present invention, in a measurement reagent and a measurement method for measuring an anti-glycolipid antibody in a sample by reacting an antigen-antibody with a glycolipid antigen, the ionic strength is adjusted to 0.17 mol / L or less. Lipid antibodies can be measured with high sensitivity, and accurate measurement results can be obtained.

It is the figure which showed the result of having measured the anti- glycolipid antibody in a sample with the measuring reagent of this invention. It is the figure which showed the result of having measured the anti- glycolipid antibody in a sample with the measuring reagent of this invention. It is the figure which showed the result of having measured the anti- glycolipid antibody in a sample with the measuring reagent of this invention. It is the figure which showed the result of having measured the anti- glycolipid antibody in a sample with the measuring reagent of this invention. It is the figure which showed the result of having measured the anti- glycolipid antibody in a sample with the measuring reagent of this invention. It is the figure which showed the result of having measured the anti- glycolipid antibody in a sample with the measuring reagent of this invention.

  Hereinafter, the present invention will be described in detail. However, the following embodiments are examples for explaining the present invention, and the present invention is not limited to these embodiments. Moreover, this invention can be implemented with various forms, unless it deviates from the summary.

[1] Basic Requirements of the Invention In the measurement reagent and measurement method of the present invention, it is essential that the ionic strength is 0.17 mol / L or less in the measurement of the anti-glycolipid antibody in the sample.
This can increase the measurement sensitivity in measuring the anti-glycolipid antibody in the sample.

[2] Glycolipid antigen In the present invention, a glycolipid antigen is a substance (glycolipid) containing both a water-soluble sugar chain and a fat-soluble group in its molecule, and an anti-glycolipid antibody to be measured It is a substance that can bind specifically.

  The glycolipid antigen in the present invention includes sphingoglycolipid, glyceroglycolipid and the like.

  The glycolipid antigen in the present invention includes ganglioside, which is a glycolipid containing sialic acid, sulfatide (sulfolipid), which is a glycolipid containing sulfuric acid, glycolipid containing uronic acid, or glycolipid containing phosphoric acid. A glycolipid, a neutral glycolipid, and the like are included.

Ganglioside (sialoglycolipid) is a general term for glycosphingolipids containing sialic acid.
Examples of the ganglioside include GM1, GM1b, GM1-Fuc, GM2, GM3, GM3 (NeuGc), GM4, GD1a, GD1b, GD2, GD3, GD3 (NeuAc / NeuGc), GD3 (NeuGc, T1G, T1G1). , GT1c, GQ1a, GQ1b, GQ1c, GP1a, GP1b, GP1c, or LM1.

  In the present invention, it is suitable when the glycolipid antigen is ganglioside (ganglioside antigen).

[3] Anti-glycolipid antibody In the present invention, the anti-glycolipid antibody is an antibody that can specifically bind to the aforementioned glycolipid antigen.

  Examples of the anti-glycolipid antibody in the present invention include an antibody against glycosphingolipid and an antibody against glyceroglycolipid.

  Furthermore, in the present invention, examples of the anti-glycolipid antibody include an antibody against acidic glycolipid, an antibody against neutral glycolipid, and the like.

  Examples of antibodies against acidic glycolipids include antibodies against gangliosides, antibodies against sulfatides, antibodies against glycolipids containing uronic acid, and antibodies against glycolipids containing phosphoric acid.

  Examples of antibodies against ganglioside include anti-GM1 antibody, anti-GM1b antibody, anti-GM1-Fuc antibody, anti-GM2 antibody, anti-GM3 antibody, anti-GM3 (NeuGc) antibody, anti-GM4 antibody, anti-GD1a antibody, anti-GD1b antibody. Anti-GD2 antibody, anti-GD3 antibody, anti-GD3 (NeuAc / NeuGc) antibody, anti-GD3 (NeuGc) 2 antibody, anti-GT1a antibody, anti-GT1b antibody, anti-GT1c antibody, anti-GQ1a antibody, anti-GQ1b antibody, anti-GQ1c antibody, Examples thereof include an anti-GP1a antibody, an anti-GP1b antibody, an anti-GP1c antibody, and an anti-LM1 antibody.

  In the present invention, it is suitable when the anti-glycolipid antibody is an antibody against ganglioside.

[4] Ionic strength In the present invention, the measurement sensitivity can be increased by setting the ionic strength to 0.17 mol / L or less in the measuring reagent and measuring method for the anti-glycolipid antibody in the sample.

  And it is preferable to make ionic strength into 0.15 mol / L or less since a measurement sensitivity can be raised more. For the same reason, the ionic strength is more preferably 0.10 mol / L or less.

  In the measurement of the anti-glycolipid antibody in the sample of the present invention, in order to reduce the ionic strength to 0.17 mol / L or less, for example, the measurement reagent and the measurement method for the glycolipid antibody in the sample include cation and anion. What is necessary is just to carry out by containing or making ion exist.

  The ionic strength in the present invention is, for example, when a preservative such as a buffer or sodium azide is present during the measurement reaction, the total ionic strength including the ionic strength is 0.17 mol / L. It only has to be as follows.

[5] Cation and anion In the present invention, the cation and the anion contained or present in the measurement reagent and measurement method of the anti-glycolipid antibody in the sample for adjusting the ionic strength will be described below.

(1) Cation In the present invention, the cation can be used without particular limitation as long as it is an ion having a positive charge.

  The cation may be a monovalent cation or a divalent or higher valent cation.

  And as this cation, a metal ion, an ammonium ion, or another cation etc. can be mentioned, for example.

Examples of the metal ions include alkali metal ions, alkaline earth metal ions, and other metal ions.
Examples of alkali metal ions include lithium ions, sodium ions, or potassium ions.
Examples of alkaline earth metal ions include beryllium ions, magnesium ions, calcium ions, and the like.
Examples of other metal ions include manganese ions, iron ions, cobalt ions, nickel ions, copper ions, zinc ions, and aluminum ions.

  Examples of ammonium ions include primary ammonium ions, secondary ammonium ions, tertiary ammonium ions, and quaternary ammonium ions.

As other cations, for example, carbon atoms, silicon atoms, boron atoms, nitrogen atoms (in cases other than ammonium ions), phosphorus atoms, sulfur atoms, etc. are positively charged atoms or atomic groups Can be mentioned.
Specific examples thereof include a choline ion in which a carbon atom has a positive charge.

  In addition, as this cation, only one type may be used, or a plurality of types may be used simultaneously.

(2) Anion In the present invention, the anion is not particularly limited as long as it is an ion having a negative charge.

  The anion may be a monovalent anion or a divalent or higher polyvalent anion.

  And as this anion, the acid group which consists of an organic compound, a halogen ion, or another inorganic compound etc. can be mentioned, for example.

  Examples of the acid group made of this organic compound include acetate ion, citrate ion, gluconate ion, or oxalate ion.

  As a halogen ion, a fluorine ion, a chlorine ion, a bromine ion, an iodine ion etc. can be mentioned, for example.

  Examples of acid groups composed of other inorganic compounds include sulfate ion, sulfite ion, pyrosulfite ion, dithionite ion, thiosulfite ion, nitrate ion, nitrite ion, hyponitrite ion, peroxonitrite ion, Examples include phosphate ion, phosphite ion, pyrophosphite ion, hypophosphite ion, diphosphate ion, borate ion, carbonate ion, cyanate ion, isocyanate ion, or silicate ion. it can.

  Moreover, as this anion, only one type may be used, or a plurality of types may be used simultaneously.

  Further, it is a method of containing or existing the cation and anion, the cation and anion are used in a measurement reaction in which an antigen-antibody reaction between a glycolipid antigen and an anti-glycolipid antibody in a sample is performed. Any method may be used as long as the ionic strength can be 0.17 mol / L or less.

For example, the measurement reagent may be prepared by adding or allowing a compound containing the cation and a compound containing the anion to be added separately.
Alternatively, the measurement reagent may be prepared by adding or containing a compound containing both the cation and the anion.
As a result, the cation and the anion may be present in the measurement reagent and measurement method for the anti-glycolipid antibody in the sample so that the ionic strength is 0.17 mol / L or less.

  Moreover, as a compound containing both the said cation and an anion, the salt etc. which consist of this cation and an anion can be mentioned, for example.

  In the present invention, for example, a sample diluent containing the cation and anion described above so as to have an ionic strength of 0.17 mol / L or less is prepared, and a mixture of the sample diluent and the sample is prepared. , A measurement reaction in which an antigen-antibody reaction between a glycolipid antigen immobilized on a carrier and an anti-glycolipid antibody contained in a sample is performed by mixing a reagent containing a carrier on which a glycolipid antigen is immobilized Sometimes it is preferred to have cations and anions present.

[6] Carrier In the present invention, the carrier can be used without particular limitation as long as it can immobilize the glycolipid antigen.

  That is, any carrier may be used as long as it is a carrier that can be used or used in a measuring reagent and a measuring method for measuring an anti-glycolipid antibody in a sample using an antigen-antibody reaction with a glycolipid antigen.

  The material of this carrier is not particularly limited. For example, polystyrene, polycarbonate, polyvinyl toluene, polypropylene, polyethylene, polyvinyl chloride, nylon, polymethacrylate, polyacrylamide, latex, liposome, gelatin, agarose, cellulose, sepharose, glass, A solid support in the form of a microcapsule, a bead, a microplate (microtiter plate), a test tube, a stick, or a test piece made of a material such as metal, ceramics, or a magnetic material can be used.

  In the present invention, the glycolipid antigen can be immobilized on the carrier by a known method such as a physical adsorption method, a chemical binding method, or a combination thereof.

  For example, when the chemical binding method is used, the Japanese Society of Clinical Pathology “Special Issue on Extraordinary Clinical Pathology No. 53: Immunoassay for Clinical Tests—Technology and Applications”, Clinical Pathology Publications, 1983; Japan Biochemical Society In accordance with a known method described in ed. “Shinsei Kagaku Kenkyu Ken 1 Protein IV”, published by Tokyo Kagaku Dojin, published in 1991, etc., the glycolipid antigen and carrier are divalent such as glutaraldehyde, carbodiimide, imide ester or maleimide. It is carried out by mixing and bringing into contact with the above-mentioned cross-linking reagent, and reacting the glycolipid antigen with each of the amino group, carboxyl group, thiol group, aldehyde group or hydroxyl group of the carrier and the above-mentioned divalent cross-linking reagent. be able to.

  Further, if it is necessary to carry out treatment to suppress the spontaneous aggregation of the carrier on which the glycolipid antigen is immobilized, non-specific reaction, etc., bovine serum is applied to the surface or inner wall surface of the carrier on which the glycolipid antigen is immobilized. Treatment with a known method such as albumin (BSA), human serum albumin (HSA), protein such as casein, gelatin, ovalbumin or a salt thereof, a surfactant or nonfat dry milk, etc. You may perform a blocking process (masking process).

[7] Sample In the present invention, the sample may be an anti-glycolipid antibody, and if it is intended to measure the presence / absence or content (concentration) of the anti-glycolipid antibody. Anything can be used.
Examples of such samples include body fluids such as human or animal blood, serum, plasma, spinal fluid or ascites, or extracts such as organs, tissues or muscles, extracts such as cells or fungi, and the like. Mention may be made of those that may contain glycolipid antibodies.

[8] Measuring method The measuring method of the present invention is a method for measuring an anti-glycolipid antibody in a sample by reacting with a glycolipid antigen and an antigen-antibody, and the ionic strength at the time of the antigen-antibody reaction is 0.17 mol. / L or less.

  In the measurement method of the present invention, the measurement principle of the method for measuring an anti-glycolipid antibody in a sample by reacting with an antigen-antibody with a glycolipid antigen is not particularly limited. Also good.

  For example, enzyme immunoassay (ELISA, EIA), fluorescence immunoassay (FIA), radioimmunoassay (RIA), luminescence immunoassay (LIA), enzyme antibody method, fluorescent antibody method, immunochromatography method, immune ratio Turbidity method, latex turbidimetric method, latex agglutination reaction measurement method, erythrocyte agglutination reaction method, particle agglutination reaction method, measurement target substances described in JP-A-9-229936, JP-A-10-132919, etc. A specific binding substance to the substance (substance), a measurement method using a carrier having a surface coated with the substance, and particles to which the specific binding substance to the substance to be measured (test substance) is immobilized, or Dahlbeack et al. ELSA method (Enzyme-linked Ligandsorbent Assay) (Thromb. Haemost., Volume 79) , Pp. 767-772, published in 1998; WO 98/23963).

  When the measurement method of the present invention is carried out by a method that uses a labeled immunoassay method such as enzyme immunoassay as a measurement principle, in any method such as a sandwich method, a competitive method, or a homogeneous method (homogeneous method) The present invention can also be applied.

  In the measurement method of the present invention, the measurement may be performed by a method or using an apparatus such as an analyzer.

  Further, the measurement may be performed by a one-step method (one-reagent method) or a method performed by a plurality of operation steps such as a two-step method (two-reagent method).

  In the measurement method of the present invention, the measurement method (measurement method) may be performed based on any known measurement principle (measurement method) according to a known method.

The measurement method of the present invention will be specifically described below, taking as an example the case where the measurement method of the present invention is performed by a method based on a labeled immunoassay method such as an enzyme immunoassay.
An example in the case of measuring by the sandwich method of labeled immunoassay is shown.

(1) First, prepare the following.
Carrier: a carrier on which a glycolipid antigen that can specifically bind to the anti-glycolipid antibody to be measured is immobilized (for example, in the measurement of anti-GM1 antibody, a microtiter plate in which GM1 is immobilized on a well)
Sample diluent: a solution having an ionic strength of 0.17 mol / L or less

(2) A predetermined amount of the mixture of the sample (human serum) and the sample diluent is added to the site of the carrier where the glycolipid antigen is immobilized, and is contacted for a certain period of time.
Thus, when an anti-glycolipid antibody that is a measurement target substance exists in the sample, a bond of “carrier-glycolipid antigen-anti-glycolipid antibody” is formed by an antigen-antibody reaction. (For example, “well of microtiter plate-GM1-anti-GM1 antibody”)

(3) A labeling substance such as an enzyme is bound to a substance that can specifically bind to the anti-glycolipid antibody at the same time as the addition, contact, or within a certain period of time or after washing. A certain amount of the product is added to the site of the carrier where the glycolipid antigen is immobilized, and contacted for a certain period of time.

  Examples of the substance that can specifically bind to the anti-glycolipid antibody include an antibody against the anti-glycolipid antibody or an antigen that can bind to the anti-glycolipid antibody.

  More specifically, examples of the antibody against the anti-glycolipid antibody include one or two selected from anti-human IgG antibody, anti-human IgA antibody, anti-human IgM antibody, anti-human IgD antibody, and anti-human IgE antibody. More than one type of antibody can be mentioned.

  Examples of the antigen that can bind to the anti-glycolipid antibody include a glycolipid antigen that can bind to the anti-glycolipid antibody. (For example, when the anti-glycolipid antibody is an anti-GM1 antibody, GM1 can be mentioned.)

  By this operation, when an anti-glycolipid antibody as a substance to be measured is present in the sample, “carrier-glycolipid antigen-anti-glycolipid antibody-anti-glycolipid antibody-specific substance— A “labeling substance” bond is formed. (For example, "well of microtiter plate-GM1-anti-GM1 antibody-anti-human IgG antibody-labeled enzyme")

(4) Next, the unbound “substance that can specifically bind to the anti-glycolipid antibody bound to the labeling substance” that is not bound to the carrier is washed and removed.

(5) And by detecting the labeling substance bound to the carrier by the binding of “carrier-glycolipid antigen-antiglycolipid antibody-substance that can specifically bind to anti-glycolipid antibody” -labeling substance, The anti-glycolipid antibody contained in the sample is measured.

  In this measurement, the carrier and the labeling substance are able to specifically bind to “carrier-glycolipid antigen-anti-glycolipid antibody-anti-glycolipid antibody” via the anti-glycolipid antibody contained in the sample. Since it binds to “substance-labeling substance”, the presence or amount of the anti-glycolipid antibody contained in the sample can be measured by measuring the amount of the labeling substance bound to the carrier.

In addition, as the “substance that can specifically bind to the anti-glycolipid antibody bound to the labeling substance” used in the above (4), “an antibody against a class-specific human immunoglobulin bound to the labeling substance” is used. By doing so, it becomes possible to measure the anti-glycolipid antibody in the sample for each immunoglobulin class.
Examples of antibodies against human immunoglobulins by class include anti-human IgG antibodies, anti-human IgA antibodies, anti-human IgM antibodies, anti-human IgD antibodies, and anti-human IgE antibodies.

  In addition, anti-glycolipid antibodies that do not depend on the immunoglobulin class can be measured by using these "antibodies against human immunoglobulins classified by class, to which a labeling substance is bound", in an appropriate ratio. Can do.

Further, as the “substance that can specifically bind to the anti-glycolipid antibody bound to the labeling substance” used in (4) above, “an antibody against human immunoglobulin by subclass to which the labeling substance is bound” is used. By doing so, it is possible to measure the anti-glycolipid antibody in the sample for each immunoglobulin subclass.
Examples of antibodies against human immunoglobulins by subclass include anti-human kappa (κ) antibodies, anti-human lambda (λ) antibodies, anti-human IgG1 antibodies, anti-human IgG2 antibodies, anti-human IgG3 antibodies, and anti-human IgG4 antibodies. Can be mentioned.

  In addition, anti-glycolipid antibodies that do not depend on the immunoglobulin subclass should be measured by using these "antibodies against human immunoglobulins by subclass to which a labeled substance is bound" in an appropriate ratio. Can do.

  The detection of the labeling substance bound to the carrier by the binding of “carrier-glycolipid antigen-anti-glycolipid antibody-substance specifically capable of binding to anti-glycolipid antibody-labeling substance” was performed. In methods and reagents that measure using an enzyme as a labeling substance, such as a method, the substrate reacts with the labeling enzyme under the optimum conditions, and the amount of the reaction product is measured by measuring the absorbance of the reaction promoting substance. Measurements are made using a manual method.

  In a method and a reagent for measuring using a fluorescent substance as a labeling substance such as a fluorescent immunoassay, the measurement is performed by measuring the fluorescence intensity of the labeled fluorescent substance.

  In the method and reagent for measuring using a radioactive substance as a labeling substance such as radioimmunoassay, the measurement is performed by measuring the radiation dose by the labeled radioactive substance.

  In a method and reagent for measuring using a substance related to a luminescence reaction as a labeling substance such as a luminescence immunoassay, the measurement is performed by measuring the amount of luminescence in a luminescence reaction system involving the labeling substance.

  In addition, although it is said label | marker substance, when measuring by the enzyme immunoassay etc. which use an enzyme as a label | marker substance, peroxidase (POD), alkaline phosphatase (ALP), (beta) -galactosidase, urease, catalase, glucose Enzymes such as oxidase, lactate dehydrogenase, or α-amylase can be used.

  In addition, when measurement is performed by a fluorescent immunoassay method using a fluorescent substance as a labeling substance, a fluorescent substance such as fluorescein isothiocyanate, tetramethylrhodamine isothiocyanate, substituted rhodamine isothiocyanate, or dichlorotriazine isothiocyanate may be used. it can.

  When measurement is performed by a radioimmunoassay method using a radioactive substance as a labeling substance, a radioactive substance such as tritium, iodine 125, or iodine 131 can be used.

  Further, when the measurement is performed by a luminescence immunoassay method, acridinium ester, alkaline phosphatase, peroxidase, glucose oxidase or the like is used as a labeling substance, and acridinium ester, dioxetane compound, luminol-hydrogen peroxide is used. The labeling substance bound to the carrier can be detected by the -POD system or NADH-FMNH2-luciferase system.

[9] Measurement Reagent The measurement reagent of the present invention is a measurement reagent for measuring an anti-glycolipid antibody in a sample by reacting with an antigen-antibody with a glycolipid antigen, and has an ionic strength of 0.17 mol / L or less. It is a feature.

  By using a reagent having an ionic strength of 0.17 mol / L or less according to the present invention, measurement sensitivity can be increased in measuring an anti-glycolipid antibody in a sample.

  In addition, about a cation and an anion, it is as having described in said [4] and [5], and it is as having described in said [8] about the measuring method of the antiglycolipid antibody in a sample.

  Moreover, the measurement reagent of the present invention is suitable when the glycolipid antigen is ganglioside (ganglioside antigen).

  The measurement reagent of the present invention is suitable when the glycolipid antigen is immobilized on a carrier.

Note that the reagent for measuring anti-glycolipid antibody in the sample of the present invention can be sold alone or used for measurement of the anti-glycolipid antibody in the sample.
The reagent for measuring an anti-glycolipid antibody in a sample of the present invention can be sold in combination with other reagents or used for measuring an anti-glycolipid antibody in a sample.

  Examples of the other reagent include a buffer solution, a sample diluent, a reagent diluent, a reagent containing a labeling substance, a reagent containing a substance that generates a signal such as color development, or calibration (calibration). The reagent of the substance containing these substances can be mentioned.

[10] Other components at the time of measurement In measuring the anti-glycolipid antibody in the sample in the present invention, various aqueous solvents can be used as the solvent.
Examples of the aqueous solvent include purified water, physiological saline, and various buffer solutions such as Tris buffer, phosphate buffer, and phosphate buffered saline.
About the pH of this buffer solution, an appropriate pH may be appropriately selected and used. Although there is no particular limitation, it is general to select and use a pH within the range of pH 3-12.

In the measurement of the present invention, the glycolipid antigen, the cation and anion, the carrier on which the glycolipid antigen is immobilized, and / or the antibody and enzyme such as the anti-glycolipid antibody, etc. Protein components such as bovine serum albumin (BSA), human serum albumin (HSA), casein or a salt thereof, in addition to reagent components such as a labeled antibody to which a labeling substance is bound; various salts; various sugars; skim milk powder; normal rabbit serum Various animal serums; various preservatives such as sodium azide or antibiotics; activating substances; reaction promoting substances; sensitivity increasing substances such as polyethylene glycol; nonspecific reaction inhibiting substances; or nonionic surfactants, You may use suitably 1 type (s) or 2 or more types, such as various surfactants, such as an amphoteric surfactant or anionic surfactant.
And the density | concentration at the time of using these for a measurement is although it does not specifically limit, 0.001 to 10% (W / V) is preferable, and 0.01 to 5% (W / V) is especially preferable.

  Examples of the surfactant include sorbitan fatty acid ester, glycerin fatty acid ester, decaglycerin fatty acid ester, polyoxyethylene sorbitan fatty acid ester, polyoxyethylene glycerin fatty acid ester, polyethylene glycol fatty acid ester, polyoxyethylene alkyl ether, Nonionic surfactants such as polyoxyethylene phytosterol, phytostanol, polyoxyethylene polyoxypropylene alkyl ether, polyoxyethylene alkylphenyl ether, polyoxyethylene castor oil, hydrogenated castor oil or polyoxyethylene lanolin; betaine acetate, etc. Amphoteric surfactants; or polyoxyethylene alkyl ether sulfate or polyoxyethylene alkyl ether acetic acid Anionic surfactants, such as and the like.

[11] Method for Increasing Measurement Sensitivity In the present invention, the method for increasing the measurement sensitivity for measuring an anti-glycolipid antibody in a sample is an ionic strength of 0.17 mol / L or less in the measurement of the anti-glycolipid antibody in the sample. It is because.
In the measurement of the anti-glycolipid antibody in the sample, the measurement sensitivity of the anti-glycolipid antibody can be increased by performing the measurement at an ionic strength of 0.17 mol / L or less.
In addition, the components, samples, conditions, and the like of the reagents used in the method for increasing the measurement sensitivity in the present invention are as described above.

  EXAMPLES Hereinafter, although an Example demonstrates this invention more specifically in detail, this invention is not limited by these Examples.

[Example 1] (Measurement of anti-glycolipid antibodies at different ionic strengths)
The ionic strength was changed by changing the sodium chloride concentration, and the anti-GM1 antibody (anti-glycolipid antibody) in the sample was measured by a labeled immunoassay.

1. Reagent preparation

(1) Preparation of sample diluent A 10 mM phosphate buffer [pH 7.5] containing 1% (w / v) bovine serum albumin (BSA) was prepared. Here, sodium chloride was added so as to have a concentration of 50 mM, 100 mM, 150 mM, and 200 mM, and four types of sample dilutions having different sodium chloride concentrations were prepared.

(2) Preparation of GM1 antigen-immobilized carrier Ganglioside GM1 (Carbosy Limited) was dispensed at 200 ng per well into a well of a polystyrene plate [PolySorp (Nunk)] and allowed to stand for a certain period of time to allow the ganglioside GM1 to stand. The solution was immobilized on each well of the polystyrene plate.

  Next, 200 μL of 1.5% BSA solution (pH 7.7) is dispensed into each well in which ganglioside GM1 is solid-phased and allowed to stand for a certain period of time to perform blocking treatment. A modified carrier was prepared.

(3) Preparation of washing solution Phosphate buffered saline (pH 7.5) containing 0.05% Tween 20 (Tween 20) was prepared and used as a washing solution.

(4) Enzyme-labeled antibody Peroxidase-labeled rabbit anti-human IgG polyclonal antibody [P0214] (Dako) was used as the enzyme-labeled antibody.

(5) Coloring solution 2.5 mM hydrogen peroxide containing 0.02% peroxidase substrate solution [3,3 ′, 5,5′-tetramethylbenzidine] (Dojindo Laboratories) was used as the coloring solution.

2. Sample Anti-GM1 antibody positive serum:
Eleven types of sera confirmed to contain anti-GM1 antibodies were prepared as anti-GM1 antibody positive sera.

3. Measurement of anti-glycolipid antibody in sample (1) Eleven types of anti-GM1 antibody-positive sera of 2 of this example, which are samples, were respectively added to 4 types of sample dilution solutions of 1 (1) of this example. A mixed solution was prepared by doubling.

(2) Dispense 100 μL of each of the mixed solutions prepared in the above (1) into each well of the GM1 antigen-immobilized carrier of (2) of this Example, and leave this at 4 ° C. overnight. did.
As a result, the GM1 antigen immobilized on the carrier was brought into contact with the anti-GM1 antibody contained in the sample and reacted.

(3) Next, the mixed solution was sucked and removed from the well.
And this well was wash | cleaned with the washing | cleaning liquid of (3) of 1 of a present Example.

(4) The enzyme-labeled antibody of (4) of Example 1 was diluted 2,000 times with a Tris buffer containing 1% BSA. Next, 100 μL of this was dispensed into each well subjected to the above washing operation, and reacted at room temperature for 2 hours.

(5) Thereafter, unbound enzyme-labeled antibody was aspirated and removed from the well. And this well was wash | cleaned with the washing | cleaning liquid of 1 of this Example (3).

(6) Next, 100 μL of the color developing solution of (5) of Example 1 was dispensed into the wells and allowed to react at room temperature for 20 minutes.
As a result, the coloring enzyme was reacted with the labeling enzyme (peroxidase) immobilized on the carrier to produce a dye.

(7) 20 minutes after the addition of the color developing solution, 100 μL of 0.35 M sulfuric acid was dispensed into the wells to stop the reaction.

(8) The absorbance (main wavelength: 450 nm, subwavelength: 550 nm) of the liquid in the well was measured with a microplate reader [680 type] (Bio-Rad) to obtain an absorbance measurement value.

4). Measurement Results These measurement results (absorbance measurement values) are shown in Table 1 and FIG. In Table 1, numerical values in parentheses indicate ionic strength (mol / L) of a reagent containing sodium chloride of each concentration.

5. Discussion As is apparent from Table 1, when the sodium chloride concentration is 200 mM (that is, the ionic strength is 0.226 mol / L), the sodium chloride concentration is 150 mM (that is, the ionic strength is 0.176 mol / L). Thus, it can be seen that the measured value (absorbance) obtained by the measurement has decreased in all the samples. That is, it can be seen that the signal generation is greatly reduced and the sensitivity of the measurement is lowered.

  On the other hand, when the sodium chloride concentration is 100 mM (that is, the ionic strength is 0.126 mol / L), compared with the case where the sodium chloride concentration is 150 mM (that is, the ionic strength is 0.176 mol / L), The decrease in the measured value (absorbance) obtained is small, and it can be seen that the signal generated, that is, the sensitivity of the measurement is increased.

  Further, when the sodium chloride concentration is 50 mM (that is, the ionic strength is 0.076 mol / L), the measurement is obtained by measurement as compared with the case where the sodium chloride concentration is 150 mM (that is, the ionic strength is 0.176 mol / L). None of the values (absorbance) decreased, and it can be seen that the increase in the generated signal, that is, the increase in the sensitivity of the measurement is remarkable.

Therefore, in the measurement reagent and measurement method for measuring the anti-glycolipid antibody in the sample by reacting the antigen-antibody with a glycolipid antigen, the ionic strength is 0.17 mol / L or less in the sample. It was confirmed that anti-glycolipid antibodies can be measured with high sensitivity.
Therefore, it was confirmed that the anti-glycolipid antibody measurement reagent and measurement method in the sample of the present invention can prevent a decrease in the generated signal, increase the sensitivity of measurement, and obtain an accurate measurement result.

[Example 2] (Measurement of anti-glycolipid antibodies at different ionic strengths)
The ionic strength was changed by changing the sodium chloride concentration, and the anti-GQ1b antibody (anti-glycolipid antibody) in the sample was measured by a labeled immunoassay.

1. Reagent preparation

(1) Preparation of sample diluent The sample diluent prepared in (1) of Example 1 was used as it was.

(2) Preparation of GQ1b antigen-immobilized carrier Ganglioside GQ1b (Hytest) was dispensed at 200 ng per well into wells of a polystyrene plate [PolySorp] (Nungk) and allowed to stand for a certain period of time to allow said ganglioside GQ1b to be It was immobilized on each well of the polystyrene plate.

  Next, 200 μL of 1.5% BSA solution (pH 7.7) is dispensed into each well on which ganglioside GQ1b is immobilized, and is allowed to stand for a certain period of time for blocking treatment. A carrier was prepared.

(3) Preparation of cleaning solution The cleaning solution prepared in (1) of Example 1 was used as it was.

(4) Enzyme-labeled antibody The enzyme-labeled antibody of (4) of Example 1 was used as it was.

(5) Coloring solution The enzyme-labeled antibody of (1) of Example 1 was used as it was.

2. Sample Anti-GQ1b antibody positive serum:
Ten sera confirmed to contain anti-GQ1b antibodies were prepared as anti-GQ1b antibody-positive sera.

3. Measurement of anti-glycolipid antibody in sample (1) Ten types of anti-GQ1b antibody-positive sera of 2 of this example, which are samples, were respectively added to 4 types of sample dilution solutions of 1 (1) of this example. A mixed solution was prepared by doubling.

(2) Dispense 100 μL of each of the mixed solutions prepared in (1) above into each well of the GQ1b antigen-immobilized carrier of (2) of Example 1 and place it overnight at 4 ° C. Left to stand.
As a result, the GQ1b antigen immobilized on the carrier was brought into contact with the anti-GQ1b antibody contained in the sample and reacted.

(3) Next, the mixed solution was sucked and removed from the well.
And this well was wash | cleaned with the washing | cleaning liquid of (3) of 1 of a present Example.

(4) The enzyme-labeled antibody of (4) of Example 1 was diluted 2,000 times with a Tris buffer containing 1% BSA. Next, 100 μL of this was dispensed into each well subjected to the above washing operation, and reacted at room temperature for 2 hours.

(5) Thereafter, unbound enzyme-labeled antibody was aspirated and removed from the well. And this well was wash | cleaned with the washing | cleaning liquid of (3) of 1 of a present Example.

(6) Next, 100 μL of the coloring solution of 1) (5) of [1] of this example was dispensed into the wells and reacted at room temperature for 20 minutes.
As a result, the coloring enzyme was reacted with the labeling enzyme (peroxidase) immobilized on the carrier to produce a dye.

(7) 20 minutes after the addition of the color developing solution, 100 μL of 0.35 M sulfuric acid was dispensed into the wells to stop the reaction.

(8) The absorbance (main wavelength: 450 nm, subwavelength: 550 nm) of the liquid in the well was measured with a microplate reader [680 type] (Bio-Rad) to obtain an absorbance measurement value.

4). Measurement Results These measurement results (absorbance measurement values) are shown in Table 2 and FIG. In Table 2, the numerical value in parentheses indicates the ionic strength (mol / L) of the reagent containing each concentration of sodium chloride.

5. Discussion As is apparent from Table 2, when the sodium chloride concentration is 200 mM (ie, the ionic strength is 0.226 mol / L), the sodium chloride concentration is 150 mM (ie, the ionic strength is 0.176 mol / L). Thus, it can be seen that the measured value (absorbance) obtained by the measurement has decreased in all the samples. That is, it can be seen that the signal generation is greatly reduced and the sensitivity of the measurement is lowered.

  On the other hand, when the sodium chloride concentration is 100 mM (that is, the ionic strength is 0.126 mol / L), compared with the case where the sodium chloride concentration is 150 mM (that is, the ionic strength is 0.176 mol / L), The decrease in the measured value (absorbance) obtained is small, and it can be seen that the signal generated, that is, the sensitivity of the measurement is increased.

  In addition, when the sodium chloride concentration is 50 mM, the measured value (absorbance) obtained by measurement is less than that when the sodium chloride concentration is 150 mM (that is, the ionic strength is 0.176 mol / L). It can be seen that the increase in the generated signal, that is, the increase in the sensitivity of the measurement is remarkable.

Therefore, in the measurement reagent and measurement method for measuring the anti-glycolipid antibody in the sample by reacting the antigen-antibody with a glycolipid antigen, the ionic strength is 0.17 mol / L or less in the sample. It was confirmed that anti-glycolipid antibodies can be measured with high sensitivity.
Therefore, it was confirmed that the anti-glycolipid antibody measurement reagent and measurement method in the sample of the present invention can prevent a decrease in the generated signal, increase the sensitivity of measurement, and obtain an accurate measurement result.

[Example 3] (Measurement of anti-glycolipid antibodies at different ionic strengths)
The concentration of the buffer in the sample diluent was changed, and the anti-GM1 antibody (anti-glycolipid antibody) in the sample was measured by a labeled immunoassay.

1. Preparation of Reagent (1) Preparation of Sample Diluent 5 mM, 10 mM, 50 mM and 100 mM Phosphate Buffer [pH 7.5], Bovine Serum Albumin (BSA) 1% (w / v), Sodium Chloride 100 mM Thus, four types of sample dilutions having different buffer concentrations were prepared.

(2) Preparation of GM1 antigen-immobilized carrier The GM1 antigen-immobilized carrier prepared in (1) of Example 1 (1) was used as it was.

(3) Preparation of cleaning solution The cleaning solution prepared in (1) of Example 1 was used as it was.

(4) Enzyme-labeled antibody The enzyme-labeled antibody of (4) of Example 1 was used as it was.

(5) Coloring solution The enzyme-labeled antibody of (1) of Example 1 was used as it was.

2. Sample (1) Anti-GM1 Antibody Positive Sera Six types of sera confirmed to contain anti-GM1 antibodies were prepared as anti-GM1 antibody positive sera.

3. Measurement of anti-glycolipid antibody in sample (1) Six types of anti-GM1 antibody-positive sera of 2 in this example, which are samples, were respectively added to 4 types of sample dilution solutions in 1 (1) of this example. A mixed solution was prepared by doubling.

(2) Dispense 100 μL of each of the mixed solutions prepared in the above (1) into each well of the GM1 antigen-immobilized support carrier of (2) of Example 1 and overnight at 4 ° C. Left to stand.
As a result, the GM1 antigen immobilized on the carrier was brought into contact with the anti-GM1 antibody contained in the sample and reacted.

(3) Next, the mixed solution was sucked and removed from the well.
And this well was wash | cleaned with the washing | cleaning liquid of (3) of 1 of a present Example.

(4) The enzyme-labeled antibody of (4) of Example 1 was diluted 2,000 times with a Tris buffer containing 1% BSA. Next, 100 μL of this was dispensed into each well subjected to the washing operation of (2), and reacted at room temperature for 2 hours.

(5) Thereafter, unbound enzyme-labeled antibody was aspirated and removed from the well. And this well was wash | cleaned with the washing | cleaning liquid of (3) of 1 of a present Example.

(6) Next, 100 μL of the color developing solution of (5) of Example 1 was dispensed into the wells and allowed to react at room temperature for 20 minutes.
As a result, the coloring enzyme was reacted with the labeling enzyme (peroxidase) immobilized on the carrier to produce a dye.

(7) 20 minutes after the addition of the color developing solution, 100 μL of 0.35 M sulfuric acid was dispensed into the wells to stop the reaction.

(8) The absorbance (main wavelength: 450 nm, subwavelength: 550 nm) of the liquid in the well was measured with a microplate reader [680 type] (Bio-Rad) to obtain an absorbance measurement value.

4). Measurement Results These measurement results (absorbance measurement values) are shown in Table 3 and FIG. In Table 3, the numerical value in parenthesis indicates the ionic strength (mol / L) of the reagent containing the buffer solution of each concentration.

5. Discussion As is apparent from Table 3, when the buffer concentration is 100 mM (ie, the ionic strength is 0.356 mol / L), the buffer concentration is 50 mM (ie, the ionic strength is 0.228 mol / L). Thus, it can be seen that the measured value (absorbance) obtained by the measurement has decreased in all the samples. That is, it can be seen that the signal generation is greatly reduced and the sensitivity of the measurement is lowered.

  On the other hand, when the buffer solution concentration is 10 mM (that is, the ionic strength is 0.126 mol / L), compared with the case where the buffer solution concentration is 50 mM (that is, the ionic strength is 0.228 mol / L), The decrease in the measured value (absorbance) obtained is small, and it can be seen that the signal generated, that is, the sensitivity of the measurement is increased.

  Furthermore, when the buffer concentration is 5 mM (that is, the ionic strength is 0.113 mol / L), the measurement obtained by measurement is greater than when the buffer concentration is 50 mM (that is, the ionic strength is 0.228 mol / L). None of the values (absorbance) decreased, and it can be seen that the increase in the generated signal, that is, the increase in the sensitivity of the measurement is remarkable.

Therefore, in the measurement reagent and measurement method for measuring the anti-glycolipid antibody in the sample by reacting the antigen-antibody with a glycolipid antigen, the ionic strength is 0.17 mol / L or less in the sample. It was confirmed that anti-glycolipid antibodies can be measured with high sensitivity. Further, it was confirmed that the ionic strength in the present invention should be such that the total ionic strength including the ionic strength of the buffer existing during the measurement reaction is 0.17 mol / L or less.
Therefore, it was confirmed that the anti-glycolipid antibody measurement reagent and measurement method in the sample of the present invention can prevent a decrease in the generated signal, increase the sensitivity of measurement, and obtain an accurate measurement result.

[Example 4] (Measurement of anti-glycolipid antibodies at different ionic strengths)
The concentration of the buffer was changed, and the anti-GM1 antibody (anti-glycolipid antibody) in the sample was measured by a labeled immunoassay.

1. Reagent preparation

(1) Preparation of sample dilution solution To 5 mM, 10 mM, 50 mM and 100 mM Tris buffer [pH 7.5], bovine serum albumin (BSA) is added to 1% (w / v) and sodium chloride to 100 mM. Then, four types of sample dilutions with different buffer concentrations were prepared.

(2) Preparation of GM1 antigen-immobilized carrier The GM1 antigen-immobilized carrier prepared in (1) of Example 1 (1) was used as it was.

(3) Preparation of cleaning solution The cleaning solution prepared in (1) of Example 1 was used as it was.

(4) Enzyme-labeled antibody The enzyme-labeled antibody of (4) of Example 1 was used as it was.

(5) Coloring solution The enzyme-labeled antibody of (1) of Example 1 was used as it was.

2. Sample (1) Anti-GM1 Antibody Positive Serum The sample of 2 in Example 3 was used as it was.

3. Measurement of anti-glycolipid antibody in sample (1) Six types of anti-GM1 antibody-positive sera of 2 in this example, which are samples, were respectively added to 4 types of sample dilution solutions in 1 (1) of this example. A mixed solution was prepared by doubling.

  Measurement of anti-GM1 antibody in the sample in the same manner as in (3) (1) to (8) of Example 3 except that the four types of sample diluents of (1) of Example 1 are used as the sample diluent. Went.

4). Measurement Results These measurement results (absorbance measurement values) are shown in Table 4 and FIG. In Table 4, the numerical value in parentheses indicates the ionic strength (mol / L) of the reagent containing each concentration of buffer solution.

5. Discussion As is apparent from Table 4, when the buffer concentration is 100 mM (that is, the ionic strength is 0.180 mol / L), the buffer concentration is 50 mM (that is, when the ionic strength is 0.140 mol / L). Thus, it can be seen that the measured value (absorbance) obtained by the measurement has decreased in all the samples. That is, it can be seen that the signal generation is greatly reduced and the sensitivity of the measurement is lowered.

  On the other hand, when the buffer solution concentration is 10 mM (that is, the ionic strength is 0.108 mol / L), compared with the case where the buffer solution concentration is 50 mM (that is, the ionic strength is 0.140 mol / L), The decrease in the measured value (absorbance) obtained is small, and it can be seen that the signal generated, that is, the sensitivity of the measurement is increased.

  Furthermore, when the buffer concentration is 5 mM (that is, the ionic strength is 0.104 mol / L), the measurement is obtained by measurement compared to when the buffer concentration is 50 mM (that is, the ionic strength is 0.140 mol / L). None of the values (absorbance) decreased, and it can be seen that the increase in the generated signal, that is, the increase in the sensitivity of the measurement is remarkable.

Therefore, in the measurement reagent and measurement method for measuring the anti-glycolipid antibody in the sample by reacting the antigen-antibody with a glycolipid antigen, the ionic strength is 0.17 mol / L or less in the sample. It was confirmed that anti-glycolipid antibodies can be measured with high sensitivity. Further, it was confirmed that the ionic strength in the present invention should be such that the total ionic strength including the ionic strength of the buffer existing during the measurement reaction is 0.17 mol / L or less.
Therefore, it was confirmed that the anti-glycolipid antibody measurement reagent and measurement method in the sample of the present invention can prevent a decrease in the generated signal, increase the sensitivity of measurement, and obtain an accurate measurement result.

[Example 5] (Measurement of anti-glycolipid antibodies at different ionic strengths)
The ionic strength was changed by changing the sodium chloride concentration, and the anti-GD1a antibody (anti-glycolipid antibody) in the sample was measured by a labeled immunoassay.

1. Reagent preparation

(1) Preparation of sample diluent The sample diluent prepared in (1) of Example 1 was used as it was.

(2) Preparation of GD1a antigen-immobilized carrier Ganglioside GD1a (Sigma) was dispensed at 200 ng per well into a well of a polystyrene plate [PolySorp] (Nunk) and allowed to stand for a certain period of time, and the ganglioside GD1a was It was immobilized on each well of the polystyrene plate.

  Next, after removing the liquid in the well in which the ganglioside GD1a was immobilized, 200 μL of 1.5% BSA solution (pH 7.7) was dispensed into each well and left for a certain period of time. A blocking treatment was performed to prepare a GD1a antigen-immobilized carrier.

(3) Preparation of cleaning solution The cleaning solution prepared in (1) of Example 1 was used as it was.

(4) Enzyme-labeled antibody The enzyme-labeled antibody of (4) of Example 1 was used as it was.

(5) Coloring solution The coloring solution of (5) of Example 1 was used as it was.

2. Sample Anti-GD1a antibody positive serum:
Three types of sera confirmed to contain anti-GD1a antibodies were prepared as anti-GD1a antibody positive sera.

3. Measurement of anti-glycolipid antibody in sample (1) The three types of anti-GD1a antibody positive sera of 2 of this example, which are samples, were each added to 4 types of sample dilutions of (1) of 1 of this example. A mixed solution was prepared by doubling.

(2) Dispense 100 μL of each of the four types of mixed solutions prepared in (1) above into each well of the GD1a antigen-immobilized carrier in (2) of this Example. I left still overnight.
As a result, the GD1a antigen immobilized on the carrier was brought into contact with the anti-GD1a antibody contained in the sample and reacted.

(3) Next, the mixed solution was sucked and removed from the well.
And this well was wash | cleaned with the washing | cleaning liquid of (3) of 1 of a present Example.

(4) The enzyme-labeled antibody of (4) of Example 1 was diluted 2,000 times with a Tris buffer containing 1% BSA. Next, 100 μL of this was dispensed into each well subjected to the above washing operation, and reacted at room temperature for 2 hours.

(5) Thereafter, unbound enzyme-labeled antibody was aspirated and removed from the well. And this well was wash | cleaned with the washing | cleaning liquid of (3) of 1 of a present Example.

(6) Next, 100 μL of the color developing solution of (5) of Example 1 was dispensed into the wells and allowed to react at room temperature for 20 minutes.
As a result, the coloring enzyme was reacted with the labeling enzyme (peroxidase) immobilized on the carrier to produce a dye.

(7) 20 minutes after the addition of the color developing solution, 100 μL of 0.35 M sulfuric acid was dispensed into the wells to stop the reaction.

(8) The absorbance (main wavelength: 450 nm, subwavelength: 550 nm) of the liquid in the well was measured with a microplate reader [680 type] (Bio-Rad) to obtain an absorbance measurement value.

4). Measurement Results These measurement results (absorbance measurement values) are shown in Table 5 and FIG. In Table 5, the numerical values in parentheses indicate the ionic strength (mol / L) of the reagent containing sodium chloride of each concentration.

5. Discussion As is apparent from Table 5, when the sodium chloride concentration is 200 mM (that is, the ionic strength is 0.226 mol / L), the sodium chloride concentration is 150 mM (that is, the ionic strength is 0.176 mol / L). Thus, it can be seen that the measured value (absorbance) obtained by the measurement has decreased in all the samples. That is, it can be seen that the signal generation is greatly reduced and the sensitivity of the measurement is lowered.

  On the other hand, when the sodium chloride concentration is 100 mM (that is, the ionic strength is 0.126 mol / L), compared with the case where the sodium chloride concentration is 150 mM (that is, the ionic strength is 0.176 mol / L), The decrease in the measured value (absorbance) obtained is small, and it can be seen that the signal generated, that is, the sensitivity of the measurement is increased.

  Further, when the sodium chloride concentration is 50 mM (that is, the ionic strength is 0.076 mol / L), the measurement is obtained by measurement as compared with the case where the sodium chloride concentration is 150 mM (that is, the ionic strength is 0.176 mol / L). None of the values (absorbance) decreased, and it can be seen that the increase in the generated signal, that is, the increase in the sensitivity of the measurement is remarkable.

Therefore, in the measurement reagent and measurement method for measuring the anti-glycolipid antibody in the sample by reacting the antigen-antibody with a glycolipid antigen, the ionic strength is 0.17 mol / L or less in the sample. It was confirmed that anti-glycolipid antibodies can be measured with high sensitivity.
Therefore, it was confirmed that the anti-glycolipid antibody measurement reagent and measurement method in the sample of the present invention can prevent a decrease in the generated signal, increase the sensitivity of measurement, and obtain an accurate measurement result.

[Example 6] (Measurement of anti-glycolipid antibodies at different ionic strengths)
The ionic strength was changed by changing the sodium chloride concentration, and the anti-GD1b antibody (anti-glycolipid antibody) in the sample was measured by a labeled immunoassay.

1. Reagent preparation

(1) Preparation of sample diluent The sample diluent prepared in (1) of Example 1 was used as it was.

(2) Preparation of GD1b antigen-immobilized carrier Ganglioside GD1b (Sigma) was dispensed at 200 ng per well into a well of a polystyrene plate [PolySorp] (Nungk) and allowed to stand for a certain period of time, and the ganglioside GD1b was It was immobilized on each well of the polystyrene plate.

  Next, 200 μL of 1.5% BSA solution (pH 7.7) was dispensed into each well on which ganglioside GD1b was immobilized, and allowed to stand for a certain period of time for blocking treatment. A carrier was prepared.

(3) Preparation of cleaning solution The cleaning solution prepared in (1) of Example 1 was used as it was.

(4) Enzyme-labeled antibody The enzyme-labeled antibody of (4) of Example 1 was used as it was.

(5) Coloring solution The enzyme-labeled antibody of (1) of Example 1 was used as it was.

2. Sample Anti-GD1b antibody positive serum:
Two types of sera confirmed to contain anti-GD1b antibodies were prepared as anti-GD1b antibody-positive sera.

3. Measurement of anti-glycolipid antibody in sample (1) Two types of anti-GD1b antibody-positive sera of 2 of this example, which are samples, were respectively added to 4 types of sample dilution solutions of 1 (1) of this example. A mixed solution was prepared by doubling.

(2) Dispense 100 μL of each of the mixed solutions prepared in (1) above into each well of the GD1b antigen-immobilized support of (2) of Example 1 and place it overnight at 4 ° C. Left to stand.
As a result, the GD1b antigen immobilized on the carrier was brought into contact with the anti-GD1b antibody contained in the sample and reacted.

(3) Next, the mixed solution was sucked and removed from the well.
And this well was wash | cleaned with the washing | cleaning liquid of (3) of 1 of a present Example.

(4) The enzyme-labeled antibody of (4) of Example 1 was diluted 2,000 times with a Tris buffer containing 1% BSA. Next, 100 μL of this was dispensed into each well subjected to the above washing operation, and reacted at room temperature for 2 hours.

(5) Thereafter, unbound enzyme-labeled antibody was aspirated and removed from the well. And this well was wash | cleaned with the washing | cleaning liquid of 1 of this Example (3).

(6) Next, 100 μL of the color developing solution of (5) of Example 1 was dispensed into the wells and allowed to react at room temperature for 20 minutes.
As a result, the coloring enzyme was reacted with the labeling enzyme (peroxidase) immobilized on the carrier to produce a dye.

(7) 20 minutes after the addition of the color developing solution, 100 μL of 0.35 M sulfuric acid was dispensed into the wells to stop the reaction.

(8) The absorbance (main wavelength: 450 nm, subwavelength: 550 nm) of the liquid in the well was measured with a microplate reader [680 type] (Bio-Rad) to obtain an absorbance measurement value.

4). Measurement Results These measurement results (absorbance measurement values) are shown in Table 6 and FIG. In Table 6, the numerical value in parentheses indicates the ionic strength (mol / L) of a reagent containing sodium chloride of each concentration.

5. Discussion As is apparent from Table 6, when the sodium chloride concentration is 200 mM (ie, the ionic strength is 0.226 mol / L), the sodium chloride concentration is 150 mM (ie, the ionic strength is 0.176 mol / L). Thus, it can be seen that the measured value (absorbance) obtained by the measurement of each sample has decreased. That is, it can be seen that the signal generation is greatly reduced and the sensitivity of the measurement is lowered.

  On the other hand, when the sodium chloride concentration is 100 mM (that is, the ionic strength is 0.126 mol / L), compared with the case where the sodium chloride concentration is 150 mM (that is, the ionic strength is 0.176 mol / L), The decrease in the measured value (absorbance) obtained is small, and it can be seen that the signal generated, that is, the sensitivity of the measurement is increased.

  Further, when the sodium chloride concentration is 50 mM (that is, the ionic strength is 0.076 mol / L), the measurement is obtained by measurement as compared with the case where the sodium chloride concentration is 150 mM (that is, the ionic strength is 0.176 mol / L). None of the values (absorbance) decreased, and it can be seen that the increase in the generated signal, that is, the increase in the sensitivity of the measurement is remarkable.

Therefore, in the measurement reagent and measurement method for measuring the anti-glycolipid antibody in the sample by reacting the antigen-antibody with a glycolipid antigen, the ionic strength is 0.17 mol / L or less in the sample. It was confirmed that anti-glycolipid antibodies can be measured with high sensitivity.
Therefore, it was confirmed that the anti-glycolipid antibody measurement reagent and measurement method in the sample of the present invention can prevent a decrease in the generated signal, increase the sensitivity of measurement, and obtain an accurate measurement result.

Claims (6)

A measuring reagent for measuring an anti-glycolipid antibody in a sample by reacting an antigen-antibody with a glycolipid antigen, wherein the ionic strength is 0.17 mol / L or less. The measurement reagent according to claim 1, wherein the glycolipid antigen is a ganglioside antigen. The measurement reagent according to claim 1 or 2, wherein the glycolipid antigen is immobilized on a carrier. A method for measuring an anti-glycolipid antibody in a sample by causing an antigen-antibody reaction with a glycolipid antigen, wherein the ionic strength at the time of the antigen-antibody reaction is 0.17 mol / L or less. . The measurement method according to claim 4, wherein the glycolipid antigen is a ganglioside antigen. The measurement method according to claim 4 or 5, wherein the glycolipid antigen is immobilized on a carrier.

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