Abstract: A particle recovery device for recovering particles contained in a liquid sample, the particle recovery device comprising: a flow cell having a flow path through which the liquid sample flows; standing wave generating means that applies, in the flow path, an ultrasonic wave that sweeps between a second frequency that is a frequency lower than a first frequency that is a frequency of the ultrasonic wave that generates a standing wave having a predetermined number of nodes in the flow path and a third frequency that is a frequency higher than the first frequency; and recovery means that recovers the particles focused in the flow path by the standing wave generated by the standing wave generating means.

Abstract: An analysis method using a microchip which is provided with a capillary flow path, and a sample reservoir connected to the capillary flow path, in which the capillary flow path is filled with a first liquid for electrophoresis, and a second liquid containing a sample is stored in the sample reservoir, and including a pressurization process in which the first liquid is pressurized into the capillary flow path from a side of the capillary flow path that is opposite from the side connected to the sample reservoir, and a separation process in which a voltage is applied between the sample reservoir storing the second liquid and the capillary flow path filled with the first liquid, such that components in the sample contained in the second liquid move in the capillary flow path and the components are separated in the capillary flow path.

Abstract: A determination method includes: using a microchip, including a capillary flow path and a sample reservoir connected to the capillary flow path at an upstream side, to fill the capillary flow path with a first solution for electrophoresis, and supply the sample reservoir with a second solution containing an analyte; applying a voltage between the sample reservoir supplied with the second solution and the inside of the capillary flow path filled with the first solution, to move a component contained in the second solution in the capillary flow path and separate the component in the capillary flow path; optically detecting a value related to a component difference between the first solution and the second solution, other than a value related to the analyte, for the separated component; and determining whether the optical detection is favorable or poor by comparing the optically detected value with a predetermined threshold value.

Abstract: A biosensor for measuring a measuring object component contained in a sample includes a substrate having an upper surface on which a measurement region is formed, a spacer which has a cutout portion obtained by cutting out a part of the spacer and which is stacked on the upper surface so that the measurement region is located inside the cutout portion, and a cover which has an air hole obtained by cutting out a part of the cover and which is stacked on the spacer while covering the cutout portion.

Abstract: An analysis device employs an analysis kit including a chip provided with a capillary through which a sample flows and a cartridge superimposed on the chip and provided with a liquid reservoir. The analysis device includes a guide-in section into which the analysis kit is guided, a placement section on which the analysis kit placed so as to be supported, a pusher member that pushes the analysis kit from one side face of the analysis kit, contact members that oppose another side face on an opposite side in the horizontal direction to the one side face of the analysis kit placed on the placement section, and contact the other side face of the analysis kit being pushed in by the pusher member so as to position the analysis kit in the horizontal direction, and a measurement member that measures a component present in the sample in the analysis kit.

Abstract: By using a mutant glucose oxidase comprising an amino acid sequence in which a residue corresponding to isoleucine at position 489 or arginine at position 335 in the amino acid sequence of SEQ ID NO:1 is substituted with an amino acid residue having a reactive functional group in a side chain, and binding an electron acceptor to the mutant glucose oxidase through the amino acid residue having a reactive functional group, an electron acceptor-modified glucose oxidase is obtained.

Abstract: The present disclosure provides an analysis chip device used in capillary electrophoresis.

Abstract: A mutant cytochrome protein originated from a cytochrome protein having three heme-binding domains, which mutant cytochrome protein lacks the first heme-binding domain and the second heme-binding domain as counted from the N-terminus, is provided. The mutant cytochrome protein may lack a region(s) containing the first and second heme-binding domains.

Abstract: An analysis device employs an analysis kit including a chip provided with a capillary through which a sample flows and a cartridge superimposed on the chip and provided with a liquid reservoir. The analysis device includes a guide-in section into which the analysis kit is guided, a placement section on which the analysis kit placed so as to be supported, a pusher member that pushes the analysis kit from one side face of the analysis kit, contact members that oppose another side face on an opposite side in the horizontal direction to the one side face of the analysis kit placed on the placement section, and contact the other side face of the analysis kit being pushed in by the pusher member so as to position the analysis kit in the horizontal direction, and a measurement member that measures a component present in the sample in the analysis kit.

Abstract: The present disclosure provides component analysis methods including a measurement process and an analysis process.

Abstract: The present invention provides a mutant FAD-dependent glucose dehydrogenase comprising: a catalytic subunit; an electron transfer subunit; and a hitchhiker subunit; wherein each of the amino acid sequence of the catalytic subunit and the amino acid sequence of the electron transfer subunit comprises a cysteine residue introduced therein, the catalytic subunit and the electron transfer subunit being bound to each other through a disulfide bond between the cysteine residues to achieve improved thermal stability of the FAD-dependent glucose dehydrogenase.

Abstract: An analysis device includes a guide-in section, a piercing member, an airtight member, a gas introduction member, and a measurement member. The guide-in section is configured to guide a rectangular block shaped analysis kit containing a sample. The piercing member pierces a sealing film at an upper face of a liquid reservoir formed in the analysis kit. The airtight member forms an airtight space against the analysis kit at the periphery of a location pierced by the piercing member. The gas introduction member introduces gas into the airtight space. The measurement member measures a component present in the sample in the analysis kit guided into the guide-in section.

Abstract: The present disclosure provides, in one aspect, a target substance detection method in which a trapping substance that indirectly binds to both an immobilization side (support side) and a detection side (reporter side), which is a method for detecting a target substance in a sample. The method includes a reaction step of reacting the sample, a support including a first binding portion, a reporter substance including a second binding portion, a first trapping substance that includes a first binding partner portion capable of binding to the first binding portion and that can bind to the target substance, and a second trapping substance that includes a second binding partner portion capable of binding to the second binding portion and that can bind to the target substance; and a detection step of detecting a signal from the reporter substance.

Abstract: A method of measuring stable A1c in a blood sample based on a time distribution of an optical measured value of hemoglobin at a flow path which separates hemoglobin in the blood sample on a basis of amounts of the charges of hemoglobin is provided. The method may include a step of obtaining a correction factor, based on a peak area (A) of a fraction including HbA0 and either a peak area (G) of a first fraction including chemically-modified HbA0, or a peak area (D) of a second fraction including a component having a smaller amount of positive charge than HbA0 adjacent to a fraction identified as HbA0, in the time distribution; and a step of correcting, based on the correction factor a peak area of a fraction including stable A1c in the time distribution.

Abstract: A method for recovering a metal that uses a reduced amount of a chelating agent is described, where the method includes a complex forming step of forming, in a mixture, a complex between a metal in a sample and a chelating agent; a complex depositing step of depositing the complex in the mixture; and a metal recovering step of recovering the deposited complex from the mixture, thereby recovering the metal in the sample.

Abstract: A reagent for use in the measurement of hemoglobins by liquid chromatography, the reagent comprising a nonionic surfactant selected from the group consisting of: (i) polyoxyethylene (10) decyl ether; (ii) polyoxyethylene (6) 2-ethylhexyl ether; (iii) polyoxyethylene (9) isodecyl ether; (iv) polyoxyethylene (10) nonyl ether; (v) polyoxyethylene (16) isostearyl ether; (vi) polyoxyethylene (20) behenyl ether; and (vii) polyoxyethylene (20) polyoxypropylene (6) decyltetradecyl ether.

Abstract: A dry test piece for albumin measurement is based on the improved BCP method as a principle, and enables the measurement of albumin at a high sensitivity. The test piece includes a support; and a reagent holding layer provided on the support and on which a sample is spotted. The reagent holding layer contains a protein denaturation agent (component A), an SH reagent (component B), bromcresol purple (component C), and a nonionic surfactant (component D). In the reagent holding layer, a weight ratio (D/C) of the component D to the component C is 0.3 to 13, a content of the component C relative to an amount of the spotted sample is 0.4 ?g/?L to 5.4 ?g/?L, a content of the component D relative to the amount of the spotted sample is 25 ?g/?L or less.

Abstract: A method for processing a blood sample is provided that can improve the recovery rate of deformable rare cells that would easily pass through a filter and small rare cells while reducing the filtration area of the filter, and that can recover the rare cells alive. In one aspect, the present disclosure relates to a method for separating or detecting rare cells in a blood sample using a filter including holes with a hole density of at least 200 holes/mm2 to 40000 holes/mm2, wherein the holes are in the form of an ellipse with a minor axis diameter of 3.0 ?m to 15 ?m and a major axis diameter of 1.1 times to 3 times as long as the minor axis diameter, or the holes have a shape that contains the ellipse and is in contact with the ellipse on at least two points including both ends of the major axis of the ellipse. The method includes separating or detecting rare cells by filtering the blood sample in a volume of 6 ?l/hole or less with respect to a hole of the filter.

Abstract: An analysis device includes a guide-in section, a placement section, an illumination member, a pressing member, and a measurement member. The guide-in section is configured to guide a rectangular block shaped analysis kit containing a sample. The analysis kit is placed on the placement section in the guide-in section. The illumination member is inserted into an insertion hole formed in the analysis kit, contacts a bottom of the insertion hole, and illuminates light onto the sample. The pressing member is configured by a separate body to the illumination member and presses the analysis kit such that the analysis kit placed on the placement section is sandwiched between the pressing member and the placement section and retained at a predetermined position. The measurement section measures a component present in the sample using light illuminated from the illumination member onto the sample in the analysis kit placed on the placement section.