Abstract: The assay apparatus includes a loading part into which a cartridge including a carrier and a case is attachably and detachably to be loaded, the carrier having an assay region in which a color development state changes depending on whether the sample is positive or negative, and an index region which is optically distinguishable from other regions regardless of whether a sample is positive or negative, the case accommodating the carrier; a light source that illuminates the observation region on the carrier including the assay region and the index region; an imaging unit that images the observation region; and a processor configured to acquire an image including the observation region from the imaging unit, detect a position of the index region from the acquired image, and specify a position of the assay region with reference to the detected position of the index region.

Abstract: There are provided a concentration device that makes it possible to concentrate a sample solution in a short time, a sample solution concentration method using the concentration device to concentrate a sample solution, a sample solution concentration method using the sample solution examination method, and an examination kit including the concentration device and the detection device. The concentration device for concentrating a sample solution which is an aqueous solution containing a high-molecular-weight molecule contained in a biological fluid is a concentration device including a first container containing a super absorbent polymer and a second container, in which a part of the first container is constituted of a discharge unit consisting of a porous membrane having a hole diameter of 0.

Abstract: There are provided a sample solution concentration method that makes it possible to obtain a sample solution concentrated solution having a desired concentration fold ratio and a sample solution examination method using the sample solution concentration method.

Abstract: There are provided a concentration device for concentrating a sample solution, which makes it possible to obtain a sample solution concentrated solution having a desired concentration fold ratio, a sample solution concentration method using the concentration device, a sample solution concentration method using the sample solution examination method, and an examination kit including the concentration device.

Abstract: An immunological test method includes a concentration step of mixing a solution capable of containing an antigen, a superabsorbent polymer, and a labeled antibody against the antigen, to obtain a concentrated and mixed solution which is a concentrated mixed solution containing composite bodies of the antigen and the labeled antibody and a detection step of detecting the composite bodies in the concentrated and mixed solution using an antigen-antibody reaction, in which a swelling ratio of the superabsorbent polymer is more than 0.2 g/g and less than 800 g/g.

Abstract: An immunochromatography includes steps of mixing a specimen capable of containing an antigen and a modified particle, which is a particle modified with a substance having a specific affinity to the antigen, to obtain a mixture containing particle composite bodies; sedimenting the particle composite bodies in the mixture using a centrifuge; dissociating the sedimented particle composite bodies into the particles and the antigen by mixing the sedimented particle composite bodies with a dissociation solution, recovering an antigen-concentrated solution by sedimenting the dissociated particles using a centrifuge; neutralizing the antigen-concentrated solution using a neutralization solution; spreading particle composite bodies for labeling on an insoluble carrier having a reaction site, in a state where the particle composite bodies for labeling, which are composite bodies of the antigen in the neutralized antigen-concentrated solution and a modified particle for labeling, are formed; and capturing the particle c

Abstract: An immunochromatography includes a concentration step of concentrating a solution capable of containing an antigen by ultrafiltration to obtain an antigen-concentrated solution; a spreading step of spreading particle composite bodies on an insoluble carrier having a reaction site at which a second binding substance capable of binding to an antigen in the antigen-concentrated solution has been immobilized, in a state where the particle composite bodies which are composite bodies of the antigen and a modified particle which is a particle modified with a first binding substance capable of binding to the antigen are formed; a capturing step of capturing the particle composite bodies at the reaction site of the insoluble carrier; and an amplification step of amplifying information of the particle composite bodies captured in the capturing step.

Abstract: An immunochromatography including steps of mixing an antigen-containable specimen and modified magnetic particles, which are magnetic particles modified with a substance having a specific affinity to the antigen; collecting the magnetic particles using magnetism; dissociating the modified magnetic particles to obtain an antigen-concentrated solution by mixing the collected magnetic particles with a dissociation solution, an amount of which is smaller than the antigen-containable specimen; obtaining a neutralized antigen-concentrated solution; spreading gold particle composite bodies on an insoluble carrier having a reaction site at which a second binding substance has been immobilized, in a state where the gold particle composite bodies which are composite bodies of an antigen in the neutralized antigen-concentrated solution and modified gold particles which are gold particles modified with a first binding substance are formed; capturing the gold particle composite bodies at the reaction site; and silver-ampl

Abstract: The immunological test method includes a concentration step of concentrating an antigen-containable solution by mixing the antigen-containable solution with a superabsorbent polymer to obtain an antigen-concentrated solution, and a detection step of detecting an antigen in the antigen-concentrated solution using an antigen-antibody reaction, in which a swelling ratio of the superabsorbent polymer is more than 0.2 g/g and less than 800 g/g, and an antibody that is used in the antigen-antibody reaction is a monoclonal antibody.

Abstract: An immunochromatography including steps of mixing an antigen-containable specimen and modified magnetic particles, which are magnetic particles modified with a monoclonal antibody X; collecting the magnetic particles from the mixture using magnetism; dissociating the modified magnetic particles to obtain an antigen-containing solution; neutralizing the antigen-containing solution to obtaina neutralized antigen-containing solution; spreading gold particle composite bodies on an insoluble carrier having a reaction site at which a monoclonal antibody Z has been immobilized, wherein the gold particle composite body is a composite body of the antigen and a modified gold particle which is a gold particle modified with a monoclonal antibody Y; capturing the gold particle composite bodies at the reaction site; and silver-amplifying the gold particle composite body, in which the antibody X and the antibody Y are different from each other, and the antibody X and the antibody Z are different from each other.

Abstract: An object of the present invention is to provide immunochromatography exhibiting excellent magnetic detection sensitivity.

Abstract: Provided are a photocatalyst electrode, an artificial photosynthesis module, and an artificial photosynthesis device that have low electrical resistance, even in a case where the area is increased, in a case where a transparent conductive layer is used. The photocatalyst electrode is a photocatalyst electrode that has a substrate, a transparent conductive layer, a photocatalyst layer, and a linear metal electrical conductor, and splits water with light to produce a gas. The substrate, the transparent conductive layer, and the photocatalyst layer are laminated in this order, and the linear metal electrical conductor is in contact with the transparent conductive layer. The artificial photosynthesis module has the oxygen evolution electrode that splits the water with the light to produce oxygen, and a hydrogen evolution electrode that splits the water with the light to produce hydrogen.

Abstract: An object of the present invention is to provide a composite particle for an immunochromatography which has excellent spreadability, a method for manufacturing the same, and an immunochromatography using the composite particle for an immunochromatography. A composite particle for an immunochromatography of the present invention is a composite particle for an immunochromatography in which magnetic particles having an average particle size of 500 nm or less and gold particles having an average particle size of 500 nm or less are bound via an organic substance.

Abstract: An object of the invention is to provide a method for detecting an objective substance, by which a plurality of kinds of objective substances can be detected by a single detection, in the detection of an objective substance from an analyte by utilizing magnetic force.

Abstract: An object of the present invention is to provide a method for producing a plant in order to obtain a plant having a high content of a caffeoylquinic acid compound. Another object of the present invention is to provide a method for producing a processed plant product. The method for producing a plant according to the present invention includes a step of growing at least one plant selected from the group consisting of a tuber other than a sweet potato, a plant belonging to the family Convolvulaceae, and a plant belonging to the family Asteraceae; and a step of subjecting the grown plant to nutriculture using a culture solution which is substantially free of a nitrate ion and a phosphate ion.

Abstract: Provided are an artificial photosynthesis module electrode with high efficiency and an artificial photosynthesis module having the artificial photosynthesis module electrode. The artificial photosynthesis module electrode has a first electrode that decomposes a raw material fluid with light to obtain a first fluid, a first conductive member connected to the first electrode, a second electrode that decomposes the raw material fluid with light to obtain the second fluid, and a second conductive member connected to the second electrode. The first electrode has a plurality of first electrode parts connected to the first conductive member and disposed with a gap in a first direction on a first plane. The second electrode has a plurality of second electrode parts connected to the second conductive member and disposed with a gap in the first direction on a second plane parallel to or identical to the first plane.

Abstract: Provided are a photocatalyst electrode, an artificial photosynthesis module, and an artificial photosynthesis device that have low electrical resistance, even in a case where the area is increased, in a case where a transparent conductive layer is used. The photocatalyst electrode is a photocatalyst electrode that has a substrate, a transparent conductive layer, a photocatalyst layer, and a linear metal electrical conductor, and splits water with light to produce a gas. The substrate, the transparent conductive layer, and the photocatalyst layer are laminated in this order, and the linear metal electrical conductor is in contact with the transparent conductive layer. The artificial photosynthesis module has the oxygen evolution electrode that splits the water with the light to produce oxygen, and a hydrogen evolution electrode that splits the water with the light to produce hydrogen.

Abstract: Provided is a method of producing a composite, which is capable of preventing a silicone coating solution, which becomes a silicone resin layer that prevents an acidic gas separation layer from entering a porous support, from entering the porous support, preventing a porous film and an auxiliary support film from being peeled off, and suitably forming a dense silicone resin layer on the surface of the porous support. The method thereof includes a coating process of coating the surface of the porous film side of the porous support with the silicone coating solution which becomes a silicone resin layer according to a roll-to-roll system. In the coating process, the conveying speed of the porous support is in a range of 0.5 m/min to 200 m/min, the viscosity of the silicone coating solution is in a range of 100 cP to 1000000 cP, and the peel force between the porous film and the auxiliary support film is 10 mN/min or greater.

Abstract: There is provided a method of producing a composite which is capable of suitably forming a silicone resin layer for preventing the facilitated transport film from entering the porous support in an acidic gas separation film formed by forming a facilitated transport film on a porous support, and the composite. The problem is solved by the method of producing a composite including hydrophilizing the surface of the porous support using a roll-to-roll system; and coating the hydrophilized surface of the porous support with a silicone coating solution that becomes the silicone resin layer using the roll-to-roll system.

Abstract: Preparing forming coating liquid for an acid gas separation facilitated transport membrane which includes a hydrophilic compound, an acid gas carrier, and water, coating the forming coating liquid, using a layered film layered in the order of a hydrophilic porous film, a hydrophobic porous film, and an auxiliary support film as a porous support, on a surface of the hydrophilic porous film of the layered film with a liquid film thickness of 0.3 mm to 1.0 mm and drying the coated liquid to form a first acid gas separation facilitated transport membrane, and further coating the forming coating liquid for the acid gas separation facilitated transport membrane on the surface of the hydrophilic porous film with the previously formed acid gas separation facilitated transport membrane and drying the coated liquid to form a next acid gas separation facilitated transport membrane.