Source: https://patents.google.com/patent/JP5132664B2/en
Timestamp: 2019-10-14 20:09:49
Document Index: 366817354

Matched Legal Cases: ['art, 32', 'art, 4', 'art) 32', 'art) 5', 'art) 4', 'art 2', 'art 2', 'art 5', 'art 4']

JP5132664B2 - Immunochromatographic method - Google Patents
Immunochromatographic method Download PDF
JP5132664B2
JP5132664B2 JP2009277643A JP2009277643A JP5132664B2 JP 5132664 B2 JP5132664 B2 JP 5132664B2 JP 2009277643 A JP2009277643 A JP 2009277643A JP 2009277643 A JP2009277643 A JP 2009277643A JP 5132664 B2 JP5132664 B2 JP 5132664B2
labeling substance
JP2009277643A
JP2011117906A (en
孝嘉 小山田
謙次 楢原
智規 竹重
暁彦 小野寺
2009-12-07 Application filed by 富士フイルム株式会社, 株式会社ミズホメディー filed Critical 富士フイルム株式会社
2009-12-07 Priority to JP2009277643A priority Critical patent/JP5132664B2/en
2011-06-16 Publication of JP2011117906A publication Critical patent/JP2011117906A/en
2013-01-30 Publication of JP5132664B2 publication Critical patent/JP5132664B2/en
The present invention relates to a measuring method using an immunochromatographic method and a test kit using the immunochromatographic method.
There are very many physiologically active substances or environmental pollutants such as natural products, toxins, hormones, or agricultural chemicals that act in extremely small amounts. Therefore, instrumental analysis methods capable of highly sensitive analysis have been widely used for qualitative and quantitative measurement of these substances. However, the instrumental analysis method has low specificity, requires time for analysis including the sample pretreatment step, and is complicated in operation, and thus is inconvenient for the purpose of quick and simple measurement that has been required in recent years. On the other hand, immunological measurement methods have high specificity and are much easier to operate than instrumental analysis, so that they have gradually spread to the field of measurement of physiologically active substances or environmental pollutants. However, conventional immunoassay methods such as an enzyme immunoassay method using a 96-well plate and a latex agglutination method do not always satisfy the rapid convenience or detection sensitivity of the measurement.
As another need, high sensitivity is achieved in tests that currently use relatively invasive specimens such as swab fluid and blood, and relatively low invasiveness such as runny nose, gargle, and urine. It can be expected that a test method with less burden on the patient can be realized by detecting a test sample contained in a very small amount in a simple sample.
In recent years, a test kit that uses an immunochromatographic method (also referred to as an immunochromatographic method or an immunochromatographic method) for testing an infectious disease that requires a particularly rapid diagnosis is referred to as an immunochromatographic kit in the following description. ) Has been used a lot. With the widespread use of these kits, it is possible to identify infections in patients by a quick and simple method, and to perform subsequent diagnosis and treatment quickly and accurately. For example, in an immunochromatography method using a sandwich method, an insoluble thin film support (for example, a glass fiber membrane, a nylon membrane) in which a first antibody that specifically binds to an analyte (for example, an antigen) is fixed to a specific region. A labeled second antibody that specifically binds to the analyte, and a sample solution that may contain the analyte, and the insoluble thin film support first On the region where one antibody is immobilized, an immune complex with an analyte can be formed, and a signal such as label coloring or color development can be detected to measure the analyte. As the label, for example, an enzyme-containing protein, colored latex particles, metal colloid, or carbon particles can be used.
The immunochromatographic method does not require heavy equipment and equipment for its determination and measurement, is easy to operate, and is allowed to stand for about 5 to 15 minutes after a sample solution that may contain an analyte is dropped. Measurement results can be obtained simply by doing. The immunochromatography method can obtain measurement results quickly, so it is widely used as a simple, rapid, and highly specific determination / measurement method in many situations, such as clinical tests in hospitals and laboratory tests. .
In addition, biologically active substances such as natural products, toxins, hormones, and agricultural chemicals, or environmental pollutants, and specimens in the early stages of viral infection are substances that act in extremely small amounts that cannot be detected by conventional general immunochromatographic methods. In many cases, development of a rapid, simple and highly sensitive immunochromatographic method is required.
On the other hand, using the principle of the immunochromatography method and using a reader that optically measures the optical density of the detection site, it is possible to qualitatively confirm that the test substance exists or to quantify the test substance. You can also go. An example in which the blood concentration of a protein called a myocardial marker is rapidly measured at about 15 minutes by quantifying using an immunochromatographic method, such as the Roche Diagnostics Cobas h232 series. There is also.
However, the conventional measurable range for immunochromatography using gold colloid or colored latex as a label has a limit in the low concentration range of the test substance due to the limit of absorbance per gold colloid or colored latex. It was. In addition, when the gold colloid signal is amplified with silver ions, for example, to solve the problem, the problem of the low concentration region is improved, but as the silver amount increases, the shielding area does not change so much. The problem of saturation of absorbance in the high concentration range and the use of a large amount of colloidal gold to secure the measurement range in the low concentration range, such as false amplification due to non-specifically adsorbed gold colloid label along with signal amplification In many cases, this problem occurs (Patent Document 1). For this reason, when the amount of the labeling substance is reduced until false positives are not generated, there is a time when a negative phenomenon in the ultrahigh concentration region of the antigen is observed due to a so-called prozone phenomenon.
Conventionally, high sensitivity methods using enzyme methods and silver amplification methods are known (Patent Documents 2 and 3). However, none of the systems has secured a wide enough measurement range from the low concentration range to the high concentration range.
JP 2009-098139 A Japanese Patent No. 3309977 Japanese Patent Laid-Open No. 2002-202307
As described above, the immunochromatographic method using the conventional label has a problem that the measurable range is narrow. In addition, in order to enable measurement at a low concentration, it is difficult to measure a high concentration sample simply by measuring the signal after amplification.
That is, the present invention has an object to be solved by providing an immunochromatographic method that enables measurement in a low concentration region and a high concentration region by greatly expanding the measurable range of a sample than before. . In addition, in an amplification system, it is necessary to cause an amplification reaction using a substrate or a reagent. After a sample is dropped and development is performed by capillary action, these substrates and reagents are developed again after a certain period of time. There was a need. Generally, in order to reduce noise, the sensitivity before amplification must be set low, so that it cannot be judged visually, and as a result, a certain amount of time must be set regardless of the concentration of the test substance in the sample. I had to wait. Furthermore, if the amount of labeling substances was decreased in order to reduce noise, the problem of false negatives in the ultrahigh concentration region also occurred due to the prozone phenomenon.
In the present invention, amplification is performed by using two different labels, for example, using one label, visually or using an appropriate instrument, and then amplifying another label and measuring again. By performing the measurement twice before and after amplification, the measurement in the low concentration range and the high concentration range became possible, and the measurable range of the specimen could be greatly expanded compared to the conventional case.
As a result, in the diagnosis of infectious diseases and the like, it is possible to confirm the signal in a short time even before amplification in a high-concentration sample, so a positive determination is made at an early time before amplification processing. The measurement can be terminated as necessary. On the other hand, it is possible to judge the result without a false negative problem even in a low concentration region where the amount of the test substance is very small or in an extremely high concentration region where the prozone phenomenon occurs. In addition, diagnostic items that require quantitative measurement can be measured in a very wide range.
That is, according to the present invention, the test substance, the first labeling substance modified with the first binding substance for the test substance, the second labeling substance modified with the first binding substance for the test substance, In a reaction site on the insoluble carrier having a second binding substance to the test substance or a substance having a binding property to the first binding substance to the test substance. An immunochromatographic method for detecting the test substance by capturing the test substance and the first labeling substance and / or the second labeling substance, wherein the first labeling substance generates an amplification reaction. The immunochromatographic method is provided which is a substance and the second labeling substance is a labeling substance that does not substantially affect the amplification reaction.
Preferably, the first labeling substance is a substance having a property of reacting with silver ions and a reducing agent for silver ions to generate metallic silver, and the second labeling substance is a reduction for silver ions and silver ions. An agent is a substance that has substantially no reactivity.
Preferably, metallic silver is produced by an amplification reaction using silver ions and a reducing agent for silver ions.
Preferably, the first labeling substance is a metal colloid.
Preferably, the number of metal colloid particles contained in the insoluble carrier is 1 × 10 5 or more and 1 × 10 8 or less.
Preferably, the metal colloid comprises gold, silver or platinum.
Preferably, the first labeling substance is an enzyme, and the amplification reaction is an enzyme reaction.
Preferably, the second labeling substance is a colored particle.
Preferably, the second labeling substance is a colored latex.
Preferably, the first labeling substance is an immunochromatography method in which the average particle size of the labeling substance at the time of measurement is 1 μm or more and 20 μm or less.
According to the chromatographic method of the present invention, the measurable range of the sample can be expanded by about two digits, and measurement from a low concentration range to a high concentration range is possible. Also, detection of prozone phenomenon in the ultra-high concentration range that occurs in a labeling substance system for amplification with reduced labeling can be detected without generating false negatives by adding a second labeling product. It becomes possible.
In addition, the determination time when using an amplification system is fixed, but in the case of a high-concentration sample in a region that can be visually determined, determination using a labeling substance without amplification is possible, and a short time is required. Judgment can be made possible.
It is a longitudinal cross-sectional view which shows typically the longitudinal cross-section of the immunochromatography kit which can be used by this invention. 1 is a back adhesive sheet, 2 is a labeled antibody holding pad, 3 is an antibody-immobilized membrane, 3a is a capture site, 31 is a detection part, 32 is a control part, 4 is an absorption pad (liquid absorption part), and 5 is a sample addition pad (Drip part) is shown. It is the typical top view seen from the state in which the pad for washing | cleaning was attached to the immunochromatography kit which can be used by this invention. 2 is a labeled antibody holding pad, 3 is an antibody-immobilized membrane, 31 is a detection unit, 32 is a control unit, 4 is an absorption pad, 5 is a sample addition pad, 6 is a washing solution addition pad, and 7 is a washing solution water absorption pad. .
As a mode for carrying out the present invention, a test substance and a labeling substance modified with a first binding substance for the test substance are mixed and developed on an insoluble carrier, and a second test substance is applied to the test substance. Immunochromatography for detecting the test substance by capturing the test substance and the labeling substance at a reaction site on an insoluble carrier having a binding substance of the substance or a substance capable of binding to the first binding substance to the test substance This is a graph method, and can be carried out by using an immunochromatographic method having a first labeling substance that generates an amplification reaction and a second labeling substance that does not substantially affect the amplification reaction.
In implementation, (a) a substance having a property of reacting with a reducing agent for silver ions and silver ions as a first labeling substance, and (b) a silver ion and silver as a second labeling substance. It is preferable to use at least two kinds of labeling substances which are different from the reducing agent for ions and which have a property of having very low reactivity.
As a label used in the present invention to produce silver metal with silver ions and a reducing agent for silver ions, a metal colloid containing gold, silver, or platinum can be used. In the practice of the present invention, the number of metal colloid particles contained in one test strip as the first labeling substance is preferably 1 × 10 5 or more and 1 × 10 8 or less.
As the second labeling substance that is not reactive with silver ions and the reducing agent for silver ions, colored particles that are not metal colloids can be used. The colored particles are not particularly limited, but colored latex is preferable.
In the amplification reaction of the present invention, the label size before the start of the test and at the end of the test may be different. For example, when metal colloid is used as the first labeling substance and silver is produced with silver ions and a reducing agent for silver ions, the size of colloidal particles before amplification is generally 0.01 μm or more and 0.10 μm or less. On the other hand, the average particle size of the labeling substance after amplification at the end of the test is preferably 1 μm or more and 20 μm or less.
1. Chromatography In general, the chromatographic method is a method for determining and measuring an analyte simply, quickly, and specifically by the following method. That is, a chromatographic carrier having at least one reaction site containing an immobilization reagent (antibody, antigen, etc.) that can bind to an analyte is used as a stationary phase. On this chromatographic carrier, a dispersion liquid in which a labeling substance modified with a reagent capable of binding to the analyte is dispersed is used as a moving layer to move chromatographically in the chromatographic carrier, and the analyte and It reaches the reaction site while specifically binding to the labeling substance. In the reaction site, the complex of the analyte and the labeling substance specifically binds to the immobilization reagent, so that the immobilization reagent part is labeled only when the analyte is present in the analyte liquid. This is a technique for qualitatively and quantitatively analyzing the presence of an object to be detected in a liquid to be analyzed by using the fact that substances are concentrated and visually or using an appropriate instrument.
The kit or apparatus for performing the chromatographic method in the present invention may contain a compound containing silver and a reducing agent for silver ions, and the complex of the analyte and the labeling substance bound to the immobilization reagent. The signal can be amplified by an amplification reaction using as a nucleus, and as a result, high sensitivity can be achieved. According to the present invention, a rapid and highly sensitive chromatograph can be performed.
2. Test Sample The test sample that can be analyzed by the chromatographic method of the present invention is not particularly limited as long as it is a sample that may contain an analysis target. For example, a biological sample, In particular, animal (especially human) body fluids (eg blood, serum, plasma, spinal fluid, tears, sweat, urine, pus, runny nose or sputum) or excreta (eg feces), organs, tissues, mucous membranes, Mention may be made of the skin, a rubbed specimen (swab), a mouthwash, or the flora and fauna itself or their dry bodies.
3. Pretreatment of test sample In the chromatographic method of the present invention, the test sample is used as it is or in the form of an extract obtained by extracting the test sample using an appropriate extraction solvent. The extract can be used in the form of a diluted solution obtained by diluting the extract with an appropriate diluent, or in the form obtained by concentrating the extract by an appropriate method. As the solvent for extraction, a solvent (for example, water, physiological saline, or buffer solution) used in usual immunological analysis methods, or direct antigen-antibody reaction by diluting with the solvent It is also possible to use a water-miscible organic solvent capable of
4). Configuration The chromatographic strip that can be used in the chromatographic method of the present invention is not particularly limited as long as it is a chromatographic strip that can be used in a normal chromatographic method. For example, FIG. 1 schematically shows a cross-sectional view of an example of the chromatographic strip of the present invention.
This will be described with reference to FIG. The chromatographic strip of the present invention comprises a sample addition pad 5, a labeled substance holding pad (for example, a colloidal gold antibody holding pad) 2, and a chromatographic carrier (for example, an antibody-immobilized membrane) 3 from upstream to downstream in the developing direction. , And the absorbent pad 4 are arranged on the adhesive sheet 1 in this order.
The chromatographic carrier 3 has a detection zone (which may be referred to as a detection unit) 31 that has a capture site 3a and is an area in which an antibody or antigen that specifically binds to an analyte is immobilized, If desired, it further has a control zone (which may be referred to as a control part) 32 which is a region where a control antibody or antigen is immobilized.
The labeling substance holding pad 2 is prepared by preparing a suspension containing the labeling substance, applying the suspension to an appropriate absorbent pad (for example, a glass fiber pad), and then drying the suspension. be able to.
As the sample addition pad 5, for example, a glass fiber pad can be used.
4-1. Labeling substance The present invention is characterized in that at least two kinds of labeling substances are used. The first labeling substance is a labeling substance that can generate an amplification reaction. For example, enzyme labeling is performed so that a dye is continuously formed with an enzyme and its substrate (dye amplification solution), or metal colloid particle labeling is performed so that silver particles are formed by a reduction reaction in the presence of silver ions. it can.
On the other hand, the second labeling substance is a substance that does not substantially affect the amplification reaction. For example, colored particles used for immunoagglutination and immunostaining can be used. Specifically, colored latex particles that are polymer polymer fine particles, liposomes containing dyes, microcapsules, and the like can be used. It is desirable that these have a strong signal directly in the visible region and do not substantially affect the amplification reaction described above, and all of them generate an immune reaction specific to the test substance in the immunochromatography method. Used in combination with components, particularly antibodies.
A particularly desirable labeling substance is colored latex particles made of polystyrene having a particle size of about 0.2 to 0.5 μm. Further, when an enzyme label is used as the first labeling substance, a metal colloid particle label can also be used as the second labeling substance.
According to the present invention, in the immunochromatographic method using a metal colloid label or a metal sulfide label, other metal alloy label (hereinafter sometimes referred to as a metal-based label), or a polymer particle label containing a metal as the labeling substance, Metal labels can be amplified.
Specifically, after the complex of the analyte and the labeling substance is formed, a reducing agent is contacted for silver ions and silver ions supplied from a compound containing silver such as an inorganic silver salt or an organic silver salt, When silver particles are generated by reducing silver ions with a reducing agent, the silver particles are deposited on the metal label using the metal label as a nucleus, so that the metal label is amplified and analysis of the analysis object is performed. Can be implemented with high sensitivity.
Therefore, in the immunochromatography method of the present invention, the reaction of depositing on the label of the immune complex is performed using silver particles generated by the reducing action of silver ions by the reducing agent, and the thus amplified label is analyzed. Except for, conventionally known immunochromatographic methods can be applied as they are.
In the chromatographic method of the present invention, a metal colloid label or a metal sulfide label is used as a label used to label an antibody or antigen that specifically binds to an analyte (antigen or antibody) or a standard compound.
The metal colloid label or the metal sulfide label is not particularly limited as long as it is a label that can be used in a usual chromatographic method. Examples of the metal colloid label include platinum colloid, gold colloid, and palladium. Mention may be made of colloids or silver colloids and mixtures thereof. Examples of the metal sulfide label include iron, silver, palladium, lead, copper, cadmium, bismuth, antimony, tin, and mercury sulfides. In the immunochromatographic method of the present invention, one or more of these metal colloid labels and / or metal sulfide labels can be used as labels.
4-2. Binding substance In the present invention, the labeling substance is modified with a first binding substance for the test substance. The first binding substance includes, for example, an antibody to the test substance (antigen), an antigen to the test substance (antibody), an aptamer to the test substance (protein, low molecular compound, etc.), and the like. Any compound having an affinity for it may be used.
In the present invention, the porous carrier has (a) a second binding substance to the test substance, or (b) a substance having binding properties to the first binding substance. The second binding substance to the test substance is, for example, an antibody to the test substance (antigen), an antigen to the test substance (antibody), an aptamer to the test substance (protein, low molecular compound, etc.), etc. Any compound having an affinity for the test substance may be used. Further, the second binding substance and the first binding substance may be different or the same. The substance having the binding property to the first binding substance to the test substance may be the test substance itself or a compound having a site recognized by the first binding substance. For example, a derivative of the test substance and a protein A compound or the like in which (for example, BSA or the like) is bound to this.
Preferably, the first binding substance is an antibody and / or the second binding substance is an antibody. In the immunochromatographic method of the present invention, the antibody having specificity for the analyte is not particularly limited. For example, an antiserum prepared from the serum of an animal immunized with the analyte, An immunoglobulin fraction purified from the antiserum, a monoclonal antibody obtained by cell fusion using spleen cells of an animal immunized with the analyte, or a fragment thereof [eg, F (ab ′) 2, Fab, Fab ′ or Fv] can be used. These antibodies can be prepared by a conventional method.
4-3. Chromatographic carrier The chromatographic carrier is preferably a porous carrier. In particular, a nitrocellulose film, a cellulose film, an acetylcellulose film, a polysulfone film, a polyethersulfone film, a nylon film, a glass fiber, a nonwoven fabric, a cloth, or a thread is preferable.
Usually, a detection zone is prepared by immobilizing a detection substance on a part of a chromatographic carrier. The detection substance may be directly immobilized on a part of the chromatographic carrier by physical or chemical bonding, or the detection substance may be physically or chemically bonded to fine particles such as latex particles. The fine particles may be trapped and immobilized on a part of the chromatographic carrier. The chromatographic carrier is preferably used after immobilizing the detection substance and then subjecting it to nonspecific adsorption prevention treatment by treatment with an inactive protein or the like.
4-4. Sample addition pad Examples of the material of the sample addition pad include, but are not limited to, cellulose filter paper, glass fiber, polyurethane, polyacetate, cellulose acetate, nylon, and cotton cloth having uniform characteristics. The sample addition unit not only accepts a sample containing the added analysis target, but also has a function of filtering insoluble matter particles and the like in the sample. In addition, in order to prevent the analyte in the sample from adsorbing nonspecifically on the material of the sample addition part and reducing the accuracy of the analysis, the material constituting the sample addition part is preliminarily nonspecific. In some cases, the anti-adsorption treatment is used.
4-5. Labeling substance holding pad Examples of the material of the labeling substance holding pad include cellulose filter paper, glass fiber, and non-woven fabric. The labeling substance holding pad is impregnated with a certain amount of the labeling substance prepared as described above and dried.
4-6. Absorption pad The absorption pad is a part that absorbs and removes unreacted labeling substances that are not insolubilized in the detection part of the chromatographic carrier while the added sample is physically absorbed by the chromatographic movement. Cellulose filter paper, non-woven fabric Water-absorbing materials such as cloth and cellulose acetate are used. The chromatographic speed after the chromatographic tip of the added sample reaches the absorber varies depending on the material, size, etc. of the absorbent, so it is possible to set a speed that suits the measurement of the analyte. it can.
5. Hereinafter, the sandwich method, which is a specific embodiment of the chromatographic method of the present invention, will be described.
The sandwich method is not particularly limited. For example, the test substance can be analyzed by the following procedure. First, a first antibody and a second antibody having specificity for a test substance (antigen) are prepared in advance by the method described above. The first antibody is labeled in advance. The second antibody may be immobilized on a suitable first insoluble carrier (for example, a nitrocellulose membrane, a glass fiber membrane, a nylon membrane, or a cellulose membrane) and may contain a test substance (antigen). When contacted with a test sample (or an extract thereof), an antigen-antibody reaction occurs when a test substance is present in the test sample. This antigen-antibody reaction can be performed in the same manner as a normal antigen-antibody reaction. At the same time as or after the antigen-antibody reaction, when an excessive amount of the labeled first antibody is further contacted, when the test substance is present in the test sample, the immobilized second antibody and the test substance (antigen (antigen) ) And a labeled first antibody is formed.
In the sandwich method, after the reaction between the immobilized second antibody, the test substance (antigen), and the first antibody is completed, the labeled first antibody that did not form the immune complex is removed. By performing the first optical density measurement on the region where the immobilized second antibody is immobilized on one insoluble carrier, the labeled substance can be quantified and the amount of the test substance in the test sample can be measured. Then, by supplying a metal ion and a reducing agent, after amplifying a signal from the label of the labeled first antibody that has formed the immune complex, a second optical density measurement is performed, thereby performing the amplified label. The substance can be quantified and the amount of the test substance in the test sample can be measured.
6). Washing In the present invention, there are a step for measuring at least one kind of captured labeling substance and a step for measuring a different labeling substance. The label can be amplified between these steps. In this case, washing can be performed by developing a washing solution between these steps.
(Cleaning solution)
The washing solution for removing the labeled first antibody that has not formed the immune complex may have any washing function.
The washing solution is not particularly limited as long as it is a liquid for washing the labeling substance remaining in the chromatographic carrier other than the specific binding reaction, that is, nonspecifically remaining, and is not limited to mere water or A solvent such as ethanol alone may be used, and for example, a PBS buffer containing 1% BSA, a solution of a surfactant, or the like may be used. Further, as the cleaning liquid, a liquid containing silver ions, which will be described later, or a liquid containing a silver ion reducing agent can be used. Since the washing solution is developed while washing the non-specifically remaining labeling substance in the middle of the development, the washing solution is developed while containing the labeling substance. Use liquids that do not contain substances. In order to enhance the cleaning effect, a cleaning solution in which the pH is adjusted, or a surfactant component, a protein such as BSA, or a polymer compound such as polyethylene glycol is added may be used.
(Development of cleaning liquid, direction)
After the sample liquid is developed, the washing liquid is added to the chromatographic strip, and the labeling substance other than that bound by the antigen-antibody reaction remaining on the chromatographic strip is washed. As a method of feeding the cleaning liquid, after the sample liquid is developed, it is added to the sample dropping portion as it is, or a cleaning liquid addition pad and a water absorption pad are attached to the strip in advance, and the cleaning liquid addition pad is attached to the strip. There are a method of adding and feeding the liquid in the direction of the pad of water absorption, a method in which a strip is previously provided with a site for adding a cleaning liquid, and a method of adding the cleaning liquid to the site of adding the cleaning liquid after spreading the sample liquid. In this method, after the liquid is spread on the strip, a cleaning liquid addition pad and a water absorption pad for feeding the cleaning liquid are attached to the strip, the cleaning liquid is supplied to the cleaning liquid addition pad, and the cleaning liquid is developed. As a method of supplying the cleaning liquid to the cleaning liquid addition pad, the cleaning liquid addition pad may be inserted into a pot containing the cleaning liquid, or the cleaning liquid may be dropped into the cleaning liquid addition pad.
In this specification, the development direction of the liquid of the test substance is defined as the direction connecting the sample addition pad and the absorption pad, and the development direction of the cleaning liquid is the cleaning liquid addition pad and the water absorption for feeding the cleaning liquid. It is defined as the direction connecting the pads.
When the angle between the development direction of the test substance liquid and the development direction of the cleaning liquid is 45 degrees to 170 degrees, the cleaning effect is increased. Furthermore, the angle formed by the development direction of the test substance liquid and the development direction of the cleaning liquid is preferably 60 degrees to 170 degrees, more preferably 60 degrees to 150 degrees.
The washing liquid addition pad (also referred to as a second insoluble carrier) may be anything as long as the washing liquid can be added, and a glass fiber pad, a cellulose membrane, a nitrocellulose membrane or the like can be used.
The water absorption pad may be any substance that can absorb water, and cellulose, nitrocellulose, glass fiber, a mixture thereof, and the like can be used.
7). Amplification solution An amplification solution is a solution that can cause signal amplification by producing a colored compound, light emission, and the like when a drug contained therein reacts catalytically by the action of a labeling substance or a test substance. Examples thereof include a silver ion solution that causes metal silver to be precipitated by physical development on a metal label, and a solution of a phenylenediamine compound and a naphthol compound that become a dye by the action of a peroxidase label and hydrogen peroxide.
Details include general books in the field of photographic chemistry (for example, “Basics of Revised Photo Engineering-Silver Salt Photo Edition” (Japan Photographic Society, Corona), “Photochemistry” (Akira Sakurai, Photo Industry Publishing) ), “Latest Prescription Handbook” (Shinichi Kikuchi et al., Amico Publishing Co., Ltd.)), so-called developer can be used, and the solution contains silver ions and the silver ions in the solution are developed. As long as it is a so-called physical developer that is reduced mainly with a metal colloid or the like that becomes the core of the above, it can be used as an amplification solution without any particular limitation.
As a specific example of the amplification solution, an amplification solution containing a compound containing silver and a reducing agent for silver ions can be used. Hereinafter, the compound containing silver and the reducing agent for silver ions will be described.
(Compound containing silver (ion))
As the silver ion-containing compound, an organic silver salt, an inorganic silver salt, or a silver complex can be used. Preferably, it is a silver ion-containing compound having high solubility in a solvent such as water, and examples thereof include silver nitrate, silver acetate, silver lactate, silver butyrate, and silver thiosulfate. Particularly preferred is silver nitrate. The silver complex is preferably a silver complex coordinated to a ligand having a water-soluble group such as a hydroxyl group or a sulfone group, and examples thereof include hydroxythioether silver.
The inorganic silver salt or silver complex is generally contained in an amount of 0.001 mol / m 2 to 0.2 mol / m 2 , preferably 0.01 mol / m 2 to 0.05 mol / m 2 as silver.
(Reducing agent for silver ions)
As the reducing agent for silver ions, any inorganic or organic material or a mixture thereof can be used as long as silver ions can be reduced to silver.
Preferred examples of the inorganic reducing agent include reducible metal salts and reducible metal complex salts whose valence can be changed by metal ions such as Fe 2+ , V 2+ and Ti 3+ . When using an inorganic reducing agent, it is necessary to complex or reduce the oxidized ions to remove or render them harmless. For example, in a system using Fe 2+ as a reducing agent, a complex of Fe 3+ that is an oxide can be formed using citric acid or EDTA, and can be rendered harmless. In this system, it is preferable to use such an inorganic reducing agent, more preferably a metal salt of Fe 2+ .
The developing agents used in wet silver halide photographic materials (for example, methyl gallate, hydroquinone, substituted hydroquinone, 3-pyrazolidones, p-aminophenols, p-phenylenediamines, hindered phenols, amidoximes , Azines, catechols, pyrogallols, ascorbic acid (or derivatives thereof, and leuco dyes), and other materials apparent to those skilled in the art, such as US Pat. No. 6,020,117 The materials described in 1) can also be used.
As the reducing agent, an ascorbic acid reducing agent is also preferable. Useful ascorbic acid reducing agents include ascorbic acid analogs, isomers and derivatives thereof, such as D- or L-ascorbic acid and sugar derivatives thereof (eg γ-lactoascorbic acid, glucoascorbic acid, fucoscorbic acid). , Glucoheptascorbic acid, maltoascorbic acid), sodium salt of ascorbic acid, potassium salt of ascorbic acid, isoascorbic acid (or L-erythroascorbic acid), salts thereof (eg alkali metal salts, ammonium salts or the art) Salt), enediol type ascorbic acid, enaminol type ascorbic acid, thioenolic type ascorbic acid and the like, and particularly D, L or D, L-ascorbic acid (and Its alkali metal salt) Ku is isoascorbic acid (or alkali metal salts) is preferably, sodium salts are preferred salts. A mixture of these reducing agents can be used as necessary.
8). Dye amplification solution The dye amplification solution is preferably a chromogenic substrate for detection of horseradish peroxidase, as described in `` Staining using clinical tests Vol.41 no.9 1020 H 2 O 2 -POD system ''. Can be used.
9. Detection solution A detection solution means a solution in which the contained drug reacts with a labeling substance or a test substance, resulting in a change in color, generation of a colored compound, luminescence, etc. For example, a calcium ion that is a test substance and a complex Examples include orthocresolphthalein complexone that develops color by conversion to copper, and a copper ion solution that reacts and changes color with a protein as a test substance. This also includes a solution of a labeled complex that specifically binds to the test substance. Examples thereof include labeled DNA and labeled RNA for detecting DNA and RNA by hybridization, antibody-sensitized particles and antibody-labeled enzyme for detecting antigen.
10. Other auxiliaries Other auxiliaries for the amplification solution may include buffers, preservatives such as antioxidants or organic stabilizers, rate regulators. As a buffering agent, for example, a buffering agent using acetic acid, citric acid, sodium hydroxide or any salt thereof, tris (hydroxymethyl) aminomethane, or a buffering agent used for general chemical experiments is used. Can do. These buffers can be used as appropriate to adjust the pH to the optimum value for the amplification solution. Alkylamine can be used as an additive as an antifoggant, and dodecylamine is particularly preferable. In order to improve the solubility of these additives, a surfactant can be used, and C 9 H 19 —C 6 H 4 —O— (CH 2 CH 2 O) 50 H is particularly preferable.
11. Calculation method of average particle size at the time of detection At the time of detection (after amplification), cut out the test line part, attach the back of the sample to the sample stage with carbon paste, cut the cross section, deposit carbon, and with a scanning electron microscope, Observe the shape and size. For example, with the FE-STEM S-5500 manufactured by Hitachi High-Technologies, the sample surface can be observed by reflected electrons at an acceleration voltage of 10 KV. Thereafter, 100 signal particles are selected, the equivalent circle diameter of the projected area of the particles is measured, the average value is calculated, and the average particle size at the time of detection is obtained.
The following examples further illustrate the present invention, but the present invention is not limited to the examples.
(Influenza antigen detection)
(Preparation of labeling components)
Anti-influenza A type monoclonal antibody (Bios Pacific, clone number: A60010044P) with 0.3 μm colored latex (Bungs Laboratories: DC02B) and 0.06 μm gold colloid (British Biocell International: GC60) as labeling components Were combined. The procedure for joining was in accordance with the ordinary method.
(Preparation of labeled antibody holding pad 2)
A preparation solution containing anti-influenza A monoclonal antibody-binding colored latex and anti-influenza A monoclonal antibody-binding gold colloid at an arbitrary OD concentration is coated on a glass fiber pad, dried, and coated with an anti-influenza A monoclonal antibody labeling component coating pad. (Labeled antibody holding pad 2) was prepared.
(Preparation of detector 31)
Anti-influenza type A monoclonal antibody (Fitzgerald: clone number: M2110169) is applied to a predetermined position of a nitrocellulose membrane (Millipore: SCHF ™), which is an antibody-immobilized membrane 3 that is a porous carrier, per test. The detection unit 31 was formed by applying 0.5 μl in a line. Further, an anti-mouse antibody was similarly applied at 0.5 μl per test on the downstream side of the detection unit 31 to form a control unit 32 for confirming the reaction. After application, the membrane was air-dried and immobilized to prepare an anti-influenza A type monoclonal antibody solid-phase membrane (antibody-immobilized membrane 3 on which the detection unit 31 is arranged).
(Preparation of detection device)
Filter paper as reagent addition pad (dropping part) 5, anti-influenza A type monoclonal antibody labeling component application pad 2, anti-influenza A type monoclonal antibody solid-phase membrane 3 and filter paper as absorption pad (liquid absorption part) 4 An influenza A type detection device was prepared by pasting on an adhesive-attached resin (back adhesive sheet 1) such that each end overlapped by about 3 mm.
(Reactivity test)
(Judgment before amplification)
Influenza virus type A antigen was dissolved in Tris buffer containing 5% Tween 20 to prepare test influenza virus type A solutions at various concentrations. 140 μl thereof was dropped onto the dropping unit 5, and the line coloring (gold colloid particle-derived color, colored latex particle-derived color or mixed color thereof) derived from the labeling component that appears in the detection unit 31 by 10 minutes later was visually determined. The determination was made according to “++” with dark coloring, “+” with coloring, “+ w” with light coloring, and “−” without coloring. In addition, when line coloring was observed after the antigen solution was dropped, the time when the coloring intensity became + w was measured as the determination possible time.
(Judgment after amplification)
(Preparation of silver amplification solution)
(Preparation of amplification solution A-1)
40 mL of 1 mol / L iron nitrate aqueous solution prepared by dissolving iron (III) nitrate nonahydrate (Wako Pure Chemical, 095-00995) in water in 325 g of water, citric acid (Wako Pure Chemical, 038-06925) 10.5 g, dodecylamine (Wako Pure Chemicals, 123-00246) 0.1 g, and surfactant C 9 H 19 —C 6 H 4 —O— (CH 2 CH 2 O) 50 H 0.44 g are dissolved. When all are dissolved, add 40 mL of nitric acid (10 wt%) while stirring with a stirrer. 80 mL of this solution was measured, and 11.76 g of ammonium iron (II) sulfate hexahydrate (Wako Pure Chemical Industries, Ltd., 091-00855) was added to obtain an amplification solution A-1.
(Preparation of amplification solution A-2)
Water was added to 10 mL of a silver nitrate solution (containing 10 g of silver nitrate) to make the total amount 100 g, and an amplification solution A-2 (10 wt% aqueous silver nitrate solution) was prepared.
(Preparation of amplification solution A)
Amplification solution A-1 (40 mL) was measured, and amplification solution A-2 (4.25 mL) was added and stirred to obtain amplification solution A.
(Preparation of cleaning solution)
A PBS buffer containing 1% BSA in which 1% by weight of BSA (Sigma) was dissolved in PBS buffer (Wako Pure Chemical Industries) was used as a washing solution.
Ten minutes after the dropping, the membrane of the test immunochromatography kit determined by the detection unit 31 was placed on the upstream end of the development of the washing solution at the end of the washing solution addition pad 6 (glass fiber filter paper (GE cut to 12 mm × 10 mm) (GE Healthcare (GF / F)), 12mm end each of the wash water absorption pad 7 (12 mm x 15 mm glass fiber filter paper (GE Healthcare (GF / F))) at the downstream end The side of the membrane was pressed so that the side was upstream and downstream of the membrane cleaning solution, and the angle between the developing direction of the cleaning solution and the developing direction of the test substance was 90 degrees. Developed and washed for 3 minutes.
In this experiment, the height of the liquid surface depends on the shape of the cleaning liquid container at the time of cleaning, the shape and material of the sample addition pad of the immunochromatography kit, the experimental environment (temperature and humidity), the material and thickness of the absorption pad, and the absorption pad. Bonding between the nitrocellulose membrane and the nitrocellulose membrane is a factor that changes the water absorption speed and amount of the cleaning liquid, and it is necessary to keep it constant in the experiment. The water absorption speed and amount of the cleaning liquid are factors that influence the final cleaning effect (reduction of the remaining amount of gold fine particles). This experiment was conducted at an air temperature of 22 ± 3 ° C and humidity of 50 ± 15%.
(Signal amplification with amplification solution)
Following washing, 100 μL of amplification solution A was added so that the detection zone and control zone of the membrane were filled, and an amplification reaction was performed for 1 minute.
After the amplification reaction, the membrane was taken out and washed well with water for 1 minute. At this time, the coloring degree of the detection unit 31 was visually determined. The determination was made according to “++” with dark coloring, “+” with coloring, “+ w” with light coloring, and “−” without coloring.
(Example 1, Comparative Examples 1-4)
A kit in which the amount of colored latex and the amount of colloidal gold were changed by the above preparation method was prepared and evaluated (Table 1). In Example 1, the anti-influenza A type monoclonal antibody labeling component has an OD = 0.050 at an absorbance of 520 nm (corresponding to 1/30 of the normal concentration in the visual kit, 4 × 10 7 gold colloid amount per kit) and Anti-influenza A monoclonal antibody-conjugated colored latex was prepared using an equivalent amount of OD = 0.4 at an absorbance of 850 nm wavelength. On the other hand, in Comparative Examples 1 to 3, the amount of colloidal gold without coloring latex was OD = 1.5 at a wavelength of 520 nm (ordinary concentration in visual kit, equivalent to 1.3 × 10 9 gold colloid amount per kit), 0.15, 0.050 As a prototype. Further, in Comparative Example 4, only a colored latex without a colloidal gold was prototyped using an equivalent amount of OD = 0.4 at an absorbance of 850 nm.
From the results shown in Table 1, when the amount of colloidal gold is reduced in order to suppress the occurrence of false positives after silver amplification (line coloring at zero antigen concentration), the sensitivity before silver amplification is significantly reduced (Comparative Examples 1 and 2). 3) By mixing labeled particles having a low silver amplification activity (Comparative Example 4), it was possible to compensate for the decrease in sensitivity before silver amplification (Example 1). Further, from the results shown in Table 2, an antigen concentration range in which line determination can be performed without waiting for the silver amplification reaction occurs, and determination in a shorter time becomes possible. Note that N.I. T.A. Indicates that no experiment was conducted.
(HCG (human chorionic gonadotropin) antigen detection)
Anti-hCG monoclonal antibody (specific Intact-hCG) was bound to 0.3 μm colored latex (Bungs Laboratories: DC02B) and 0.06 μm gold colloid (British Biocell International: GC60) as the labeling components. The procedure for joining was in accordance with the ordinary method.
(Preparation of label part 2)
A preparation solution containing anti-hCG monoclonal antibody-conjugated colored latex and anti-hCG monoclonal antibody-conjugated gold colloid at an arbitrary OD concentration is applied to a glass fiber pad, dried, and anti-hCG monoclonal antibody labeling component coating pad 2 (labeling part 2). Was prepared.
An anti-hCG monoclonal antibody (specific β-hCG) was applied in a line at 0.5 μl per test on a predetermined position of a nitrocellulose membrane (Millipore: SCHF (trademark)), which is a porous carrier, and the detection unit 31 Formed. Further, an anti-mouse antibody was similarly applied at 0.5 μl per test on the downstream side of the detection unit 31 to form a control unit 32 for confirming the reaction. After coating, it was air-dried and immobilized to prepare an anti-hCG monoclonal antibody solid-phased membrane 3 (a porous carrier on which the detection unit 31 is arranged).
Adhere the filter paper as the dripping part 5, the anti-hCG monoclonal antibody labeling component coating pad 2, the anti-hCG monoclonal antibody solid-phased membrane 3 and the filter paper as the liquid absorption part 4 so that each end part overlaps by about 3 mm. The hCG antigen detection device was prepared by pasting on a resin with an agent.
HCG was dissolved in PBS buffer containing 0.1% BSA to prepare test hCG solutions of various concentrations. 140 μl thereof was dropped onto the dropping unit 5, and the line coloring (gold colloid particle-derived color, colored latex particle-derived color or mixed color thereof) derived from the labeling component that appears in the detection unit 31 by 10 minutes later was visually determined. The determination was made according to “++” with dark coloring, “+” with coloring, “+ w” with light coloring, and “−” without coloring. In addition, when line coloring was observed after the antigen solution was dropped, the time when the coloring intensity became + w was measured as the determination possible time.
Ten minutes after the dropping, the membrane of the test immunochromatography kit determined by the detection unit 31 was placed on the upstream end of the development of the washing solution at the end of the washing solution addition pad 6 (glass fiber filter paper (GE cut to 12 mm × 10 mm) (GE (Healthcare (GF / F)), 12mm end of each pad for washing water absorption (glass fiber filter paper (GE Healthcare (GF / F)) cut into 12mm x 15mm) at the downstream end The side of the membrane was pressed so that the side was upstream and downstream of the membrane cleaning solution, and the angle between the developing direction of the cleaning solution and the developing direction of the test substance was 90 degrees. Developed and washed for 3 minutes.
(Example 2, Comparative Examples 5-9)
A kit in which the amount of colored latex and the amount of colloidal gold were changed by the above preparation method was prepared and evaluated (Table 3). In Example 2, the anti-hCG monoclonal antibody labeling component has an OD = 0.010 (corresponding to 1/250 of the normal concentration in the visual kit, 1.0 × 10 7 gold colloid amount per kit) at an absorbance of 520 nm and anti-hCG. Monoclonal antibody-bound colored latex was prepared using an equivalent amount of OD = 0.7 at an absorbance of 850 nm wavelength. In Comparative Examples 5 to 8, the colloidal gold amount was OD = 2.5 at a wavelength of 520 nm without a colored latex (ordinary concentration in visual kit, equivalent to 2.5 × 10 9 gold colloid amount per kit), 0.25, 0.125, and 0.010. did. In Comparative Example 9, only a colored latex without a colloidal gold was prototyped using an equivalent amount of OD = 0.7 at an absorbance of 850 nm.
From the results shown in Table 3, when the amount of colloidal gold was reduced in order to suppress false positive generation (line coloring at zero antigen concentration) after silver amplification, the sensitivity before silver amplification was significantly reduced (Comparative Examples 5, 6, 7, 8). In addition, although the prozone phenomenon occurs in a high concentration antigen specimen (Comparative Example 8), the mixing of labeled particles having a low silver amplification activity (Comparative Example 9) can compensate for the decrease in sensitivity before silver amplification, Prozone phenomenon could also be avoided (Example 2). Furthermore, from the results shown in Table 4, an antigen concentration range in which line determination can be performed without waiting for the silver amplification reaction occurs, and determination in a shorter time becomes possible.
Insoluble carrier in a state in which a test substance, a first labeling substance modified with a first binding substance for the test substance, and a second labeling substance modified with the first binding substance for the test substance are mixed The test substance and the first substance at a reaction site on an insoluble carrier having a second binding substance to the test substance or a substance having a binding property to the first binding substance to the test substance. An immunochromatographic method for capturing the labeling substance and / or the second labeling substance and detecting the test substance, wherein the first labeling substance is a labeling substance that generates an amplification reaction, and An immunochromatographic method, wherein the labeling substance is a labeling substance that does not substantially affect the amplification reaction.
The first labeling substance is a substance that has the property of reacting with silver ions and a reducing agent for silver ions to produce metallic silver, and the second labeling substance is a reducing agent for silver ions and silver ions. The immunochromatographic method according to claim 1, wherein the immunochromatographic method is a substance having substantially no reactivity.
The immunochromatographic method according to claim 2, wherein metallic silver is produced by an amplification reaction using silver ions and a reducing agent for silver ions.
The immunochromatographic method according to any one of claims 1 to 3, wherein the first labeling substance is a metal colloid.
The immunochromatographic method according to claim 4, wherein the number of particles of the metal colloid contained in the insoluble carrier is 1 × 10 5 or more and 1 × 10 8 or less.
The immunochromatographic method according to claim 4 or 5, wherein the metal colloid contains gold, silver, or platinum.
The immunochromatography method according to any one of claims 1 to 6, wherein the first labeling substance is an enzyme and the amplification reaction is an enzyme reaction.
The immunochromatographic method according to any one of claims 1 to 7, wherein the second labeling substance is a colored particle.
The immunochromatographic method according to any one of claims 1 to 8, wherein the second labeling substance is colored latex.
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