Abstract: To provide a method and kit for measurement of a target substance with high detection sensitivity, provided is a method of measuring at least any one of the presence or absence, and a concentration, of a target substance in a sample liquid, the method including the steps of: (a) preparing a first particle that specifically binds to the target substance and contains a rare earth complex, and a second particle that has a larger average particle diameter than that of the first particle and specifically binds to the target substance; (b) mixing the sample liquid, the first particle, and the second particle to provide a mixed liquid; and (c) determining at least any one of the presence or absence, and the concentration, of the target substance from polarization anisotropy of the mixed liquid obtained in the step (b).

Abstract: Provided is a particle having high detection sensitivity in the detection of a substance to be measured, such as an antigen or an antibody, from a body. The particle includes a rare earth complex, wherein the particle has a particle size distribution of 0.1 or less in terms of polydispersity index (pdi) measured by dynamic light scattering, and wherein the particle has a hydrophilic polymer on a surface thereof.

Abstract: A measuring method includes a first sequence for acquiring a first result about the anisotropy by performing a dispensing step and a measuring step and for measuring concentration of the measurement object from the first result based on a relationship between the anisotropy and a dispensing amount of the fluorescent reagent dispensed in the dispensing step, and a second sequence for acquiring a second result about the anisotropy by performing the dispensing step and the measuring step one or more times after the first sequence and for measuring the concentration of the measurement object from the second result based on the relationship between the anisotropy measured in the measuring step and the dispensing amount of the fluorescent reagent dispensed in the dispensing step.

Abstract: To perform measurement based on polarization anisotropy in which a reaction between a target substance and a luminescent reagent is performed within a short period of time, and in which high-sensitivity measurement can be performed, provided is an analysis method including measuring a value (R) for polarization anisotropy through use of a luminescent reagent that reacts with a target substance, to thereby determine at least any one of the presence or absence of the target substance and a concentration of the target substance, the analysis method including: a reaction step of mixing a sample containing the target substance with the luminescent reagent, and subjecting the mixture to a reaction to obtain a reaction liquid; a dilution step of diluting the reaction liquid to obtain a diluted liquid; and a measurement step of measuring the R of the diluted liquid, the luminescent reagent including luminescent particles.

Abstract: Provided are a reagent and a measurement method for enabling a specimen test based on polarization anisotropy to be performed with high sensitivity and within a short period of time. Specifically, provided is an analysis method including measuring a value (R) for polarization anisotropy through use of a luminescent reagent that binds with a target substance, the analysis method including: a reaction step including mixing a sample containing the target substance with the luminescent reagent and a sensitizer, and subjecting the mixture to a reaction to obtain a reaction liquid; and a measurement step of measuring the R of the reaction liquid, the luminescent reagent including a luminescent particle substrate and a hydrophilic layer arranged on an outside of the luminescent particle substrate, the sensitizer containing a hydrophilic polymer.

Abstract: A measuring apparatus is configured to acquire information on a target. The measuring apparatus includes an irradiating unit configured to irradiate a specific area of the target with irradiation light, a detecting unit configured to receive exit light from the target which is caused by irradiating the specific area with the irradiation light, and a processing unit configured to process a signal output from the detecting unit. The processing unit causes the irradiating unit to shape a wavefront of the irradiation light by feeding back a first signal output from the detecting unit that has received the exit light. The processing unit acquires information about the specific area using a second signal output from the detecting unit that has received exit light from the target which is by irradiating the specific area with irradiation light having a shaped wavefront.

Abstract: An automatic analysis apparatus includes a reaction vessel configured to contain a reaction liquid in which a measuring object and a reagent are mixed with each other, an irradiation unit configured to irradiate the reaction vessel with irradiation light as predetermined incident light polarization, a measurement unit configured to measure light emitted from the reaction vessel, and a processor configured to process a signal having a specific polarization component obtained from the measurement unit and to analyze the measuring object. The specific polarization component is determined based on the condition of the reaction liquid.

Abstract: A wavefront control apparatus includes a detector configured to detect a signal generated from a medium onto which light is irradiated, and a controller configured to control a wavefront of the light based on an output of the detector. The controller performs first processing for forming a first wavefront of the light based on the signal generated from a first measurement position in the medium, and second processing for forming a second wavefront of the light based on the signal generated from a second measurement position different from the first measurement position in the medium onto which the light having the first wavefront is irradiated.

Abstract: An image capturing apparatus includes a spatial light modulator configured to shape a wavefront of light traveling from a light source to an object, an image capturer configured to generate image data by capturing an image of the object, and a controller configured to control the spatial light modulator and to make the image capturer capture the image when object light among the light reaches the image capturer via the object. The controller performs an optimization control of the spatial light modulator so as to maximum or minimize a value of an objective function set by using a luminance value in a target area corresponding to the object light in the image data.

Abstract: An automatic analysis apparatus includes a reaction vessel configured to contain a reaction liquid in which a measuring object and a reagent are mixed with each other, an irradiation unit configured to irradiate the reaction vessel with irradiation light as predetermined incident light polarization, a measurement unit configured to measure light emitted from the reaction vessel, and a processor configured to process a signal having a specific polarization component obtained from the measurement unit and to analyze the measuring object. The specific polarization component is determined based on the condition of the reaction liquid.

Abstract: A method for irradiating a medium includes irradiating the medium with an electromagnetic wave which is scattered in the medium and modulated in frequency at a position in the medium; obtaining information corresponding to an interference pattern generated by interference between the modulated electromagnetic wave and a reference wave; and generating a phase conjugate wave, based on the obtained information, which irradiates the medium.

Abstract: A control apparatus includes a data acquiring unit configured to acquire a measured signal obtained by measuring light emitted from a test object onto which light is irradiated, a processing unit configured to calculate an objective function that varies in accordance with a statistical value obtained by statistically processing the measured signal, and a controller configured to control a modulation amount of a wavefront of the light irradiated onto the test object so as to minimize the objective function.

Abstract: An image capturing apparatus includes a spatial light modulator configured to shape a wavefront of light traveling from a light source to an object, an image capturer configured to generate image data by capturing an image of the object, and a controller configured to control the spatial light modulator and to make the image capturer capture the image when object light among the light reaches the image capturer via the object. The controller performs an optimization control of the spatial light modulator so as to maximum or minimize a value of an objective function set by using a luminance value in a target area corresponding to the object light in the image data.

Abstract: A wavefront control apparatus includes a detector configured to detect a signal generated from a medium onto which light is irradiated, and a controller configured to control a wavefront of the light based on an output of the detector. The controller performs first processing for forming a first wavefront of the light based on the signal generated from a first measurement position in the medium, and second processing for forming a second wavefront of the light based on the signal generated from a second measurement position different from the first measurement position in the medium onto which the light having the first wavefront is irradiated.

Abstract: A control apparatus includes a data acquiring unit configured to acquire a measured signal obtained by measuring light emitted from a test object onto which light is irradiated, a processing unit configured to calculate an objective function that varies in accordance with a statistical value obtained by statistically processing the measured signal, and a controller configured to control a modulation amount of a wavefront of the light irradiated onto the test object so as to minimize the objective function.

Abstract: A method for irradiating a medium with a wave which is designed to focus on a particular portion in the medium, the method includes: irradiating the medium with an electromagnetic wave which is scattered in the medium, and is not designed to focus on the particular portion in the medium; detecting a first signal caused by irradiating the medium with the electromagnetic waver; irradiating the medium with a reconstructed wave which is designed to focus on the particular portion in the medium; detecting a second signal caused by irradiating the medium with the reconstructed wave; and monitoring, based on the first and second signals, that the particular portion is irradiated by the reconstructed wave.

Abstract: A method for irradiating a medium includes irradiating the medium with an electromagnetic wave which is scattered in the medium and modulated in frequency at a position in the medium; obtaining information corresponding to an interference pattern generated by interference between the modulated electromagnetic wave and a reference wave; and generating a phase conjugate wave, based on the obtained information, which irradiates the medium.

Abstract: A system and method for irradiating a medium including irradiating the medium with an electromagnetic wave which is scattered in the medium and modulated in frequency at a position in the medium; obtaining information corresponding to an interference pattern generated by interference between the modulated electromagnetic wave and a reference wave; and generating a phase conjugate wave, based on the obtained information, which irradiates the medium.

Abstract: An apparatus includes a low-coherent light source configured to emit an electromagnetic wave; a spatial light modulator configured to modulate a wavefront of the electromagnetic wave; an interferometer including a movable mirror to set a depth of a medium to be irradiated by the electromagnetic wave and a beam splitter configured to the electromagnetic wave into a reference beam and an object beam; a detector to detect information about an interference pattern formed by the object beam coming from the medium via the beam splitter and the reference beam reflected by the movable mirror; and a controller configured to control the spatial light modulator, based on the information, to form a modulated wavefront for irradiating the medium.

Abstract: A method for irradiating a medium includes irradiating the medium with an electromagnetic wave which is scattered in the medium and modulated in frequency at a position in the medium; obtaining information corresponding to an interference pattern generated by interference between the modulated electromagnetic wave and a reference wave; and generating a phase conjugate wave, based on the obtained information, which irradiates the medium.