Abstract: A medical device analysis system includes: a medical device; a learning medical device; and a processor comprising hardware. The processor is configured to input multidimensional structural information of the medical device, estimate a residual contamination status after cleaning of the medical device from the input multidimensional structural information of the medical device, based on a learned model that learns about a relationship between the multidimensional structural information of the learning medical device and the residual contamination status after cleaning of the learning medical device, and output the estimated residual contamination status after cleaning of the medical device.

Abstract: A photoanalysis device includes: an optical system that scans a sample solution to detect light-emitting particles that are scattered in a sample solution and move randomly; a light detection data input part into which light detection data, which is a result of detection of the light-emitting particles by the optical system, is input; a signal processor that generates time-series light intensity data from the light detection data; a concentration calculator that calculates a concentration of the light-emitting particles detected by the optical system, from the time-series light intensity data generated by the signal processor, on the basis of a learned model learned about a relationship between a plurality of time-series light intensity data having different measurement conditions and a concentration of the light-emitting particles; and a concentration output part that outputs a calculation result of the concentration calculator.

Abstract: In the scanning molecule counting method of measuring light intensity from a light detection region while moving the position of the light detection region of a confocal or multiphoton microscope in a sample solution containing light-emitting particles, generating time series light intensity data and detecting each of signals of the light-emitting particles individually in the data, wherein the light-emitting particles are formed by binding to a particle to be observed a light-emitting probe which emits light through binding to the particle to be observed and in which a stochastic transition between a non-light-emitting state and a light-emitting state occurs in the unbound state, the moving speed of the position of the light detection region is adjusted to make the time during which the unbound probe is encompassed by the moving light detection region longer than an average lifetime during which the probe is in the light-emitting state.

Abstract: A method for detecting a target nucleic acid molecule of the present invention includes a step of associating a first and third probes labeled with a first fluorescent substance which is an energy donor with a second probe labeled with a second fluorescent substance which is an energy acceptor to form an associate in a nucleic acid molecule; and a step of emitting light with an excitation wavelength of the first fluorescent substance to the associate to detect the target nucleic acid molecule using fluorescence released from the second fluorescent substance in the associate as an indicator, wherein a region associating with the second probe is between a region associating with the first probe and a region associating with the third probe in the target nucleic acid molecule.

Abstract: In the scanning molecule counting method of measuring light intensity from a light detection region while moving the position of the light detection region of a confocal or multiphoton microscope in a sample solution containing light-emitting particles, generating time series light intensity data and detecting each of signals of the light-emitting particles individually in the data, wherein the light-emitting particles are formed by binding to a particle to be observed a light-emitting probe which emits light through binding to the particle to be observed and in which a stochastic transition between a non-light-emitting state and a light-emitting state occurs in the unbound state, the moving speed of the position of the light detection region is adjusted to make the time during which the unbound probe is encompassed by the moving light detection region longer than an average lifetime during which the probe is in the light-emitting state.

Abstract: This method for detecting a target particle comprises (a) preparing a solution containing a target particle, a luminescent probe that binds to the target particle and a particle for separation and recovery, or containing the target particle bound to the luminescent probe, the luminescent probe and the particle for separation and recovery, and forming a complex composed of the target particle, the luminescent probe and the particle for separation and recovery in the solution, (b) recovering the particle for separation and recovery from the solution by solid-liquid separation treatment after the (a) and preparing a sample solution containing the particle for separation and recovery, and (c) calculating the number of the complex present in the sample solution according to a scanning molecule counting method, wherein the particles for separation and recovery bind to a complex composed of the target particles and the luminescent probe.

Abstract: Provided is a method for detecting a target particle that is a method for detecting a non-luminescent target particle dispersed and randomly moving in a sample solution using an optical system of a confocal microscope or multi-photon microscope, having: (a) preparing a sample solution containing target particles, and labeling particles of which the average outer diameter is less than 15% of the diameter of a photodetection region of the optical system, binding two or more molecules of the labeling particles per molecule of the target particles in the sample solution, and forming a non-luminescent complex of which the outer diameter is 15% or more of the diameter of the photodetection region; and, (b) calculating the number of molecules of the complex in the sample solution prepared in the (a) using an inverse scanning molecule counting method.

Abstract: Provided is a method for detecting a target particle that is a method for detecting a non-luminescent target particle dispersed and randomly moving in a sample solution using an optical system of a confocal microscope or multi-photon microscope, having: (a) preparing a sample solution containing target particles, and labeling particles of which the average outer diameter is less than 15% of the diameter of a photodetection region of the optical system, binding two or more molecules of the labeling particles per molecule of the target particles in the sample solution, and forming a non-luminescent complex of which the outer diameter is 15% or more of the diameter of the photodetection region; and, (b) calculating the number of molecules of the complex in the sample solution prepared in the (a) using an inverse scanning molecule counting method.

Abstract: There is provided a single particle detection technique based on a scanning molecule counting method, enabling individual detection of a single particle using light measurement with a confocal or multiphoton microscope, and quantitative observation of conditions or characteristics of the particle. The inventive technique of detecting a single particle in a sample solution detects light containing substantially constant background light from a light detection region with moving the position of the light detection region of the microscope in a sample solution to generate time series light intensity data; and detects individually a light intensity reduction occurred when a single particle which does not emit light (or a particle whose emitting light intensity in a detected wavelength band is lower than the background light) enters in the light detection region in the time series light intensity data as a signal indicating the existence of each single particle.

Abstract: There is provided a structure to make the setting of a criterion for eliminating noises easy in the scanning molecule counting method. In the inventive optical analysis technique of detecting light of a light-emitting particle in a sample solution, time series light intensity data of light from a light detection region detected with moving the position of the light detection region in the sample solution is generated, and a signal of a light-emitting particle individually is detected in the time series light intensity data, wherein a signal having a light intensity in a light intensity range set based upon a signal generation frequency integrated value distribution which is a distribution, obtained by using as a variable an intensity of a signal, of integrated values of generation frequencies of signals having an intensity not lower than the variable is extracted as the signal of the light-emitting particle.

Abstract: There is provided a single particle detection technique based on a scanning molecule counting method, enabling individual detection of a single particle using light measurement with a confocal or multiphoton microscope, and quantitative observation of conditions or characteristics of the particle. The inventive technique of detecting a single particle in a sample solution detects light containing substantially constant background light from a light detection region with moving the position of the light detection region of the microscope in a sample solution to generate time series light intensity data; and detects individually a light intensity reduction occurred when a single particle which does not emit light (or a particle whose emitting light intensity in a detected wavelength band is lower than the background light) enters in the light detection region in the time series light intensity data as a signal indicating the existence of each single particle.

Abstract: There is provided an optical analysis technique enabling the detection of the condition or characteristic of a particle to be observed contained at a low concentration or number density in a sample solution using a light-emitting probe. The inventive optical analysis technique uses an optical system capable of detecting light from a micro region in a solution, such as an optical system of a confocal microscope or a multiphoton microscope, to detect the light from the light-emitting probe having bound to a particle to be observed while moving the position of the micro region in the sample solution (while scanning the inside of the sample solution with the micro region), thereby detecting individually the particle crossing the inside of the micro region to enable the counting of the particle(s) or the acquisition of the information on the concentration or number density of the particle.

Abstract: There is provided a single particle detection technique based on a scanning molecule counting method, enabling individual detection of a single particle using light measurement with a confocal or multiphoton microscope, and quantitative observation of conditions or characteristics of the particle. The inventive technique of detecting a single particle in a sample solution detects light containing substantially constant background light from a light detection region with moving the position of the light detection region of the microscope in a sample solution to generate time series light intensity data; and detects individually a light intensity reduction occurred when a single particle which does not emit light (or a particle whose emitting light intensity in a detected wavelength band is lower than the background light) enters in the light detection region in the time series light intensity data as a signal indicating the existence of each single particle.

Abstract: There is provided a single particle detection technique based on the scanning molecule counting method which individually detects single particles using light measurement with a confocal or multiphoton microscope, where the existences of a non-light-emitting particle and a light-emitting particle can be detected while being discriminated from one another in a sample solution. The inventive technique of detecting a single particle detects light from a light detection region during moving the position of the light detection region of the microscope in a sample solution containing a non-light-emitting particle and a light-emitting particle to generate time series light intensity data; and detects in the time series light intensity data a light intensity increase relative to background light intensity as a signal indicating the existence of the light-emitting particle and a light intensity reduction relative to the background light intensity as a signal indicating the existence of the non-light-emitting particle.

Abstract: There is provided a single particle detection technique based on the scanning molecule counting method which individually detects single particles using light measurement with a confocal or multiphoton microscope, where the existences of a non-light-emitting particle and a light-emitting particle can be detected while being discriminated from one another in a sample solution. The inventive technique of detecting a single particle detects light from a light detection region during moving the position of the light detection region of the microscope in a sample solution containing a non-light-emitting particle and a light-emitting particle to generate time series light intensity data; and detects in the time series light intensity data a light intensity increase relative to background light intensity as a signal indicating the existence of the light-emitting particle and a light intensity reduction relative to the background light intensity as a signal indicating the existence of the non-light-emitting particle.

Abstract: The inventive technique of detecting and analyzing light from a light-emitting particle in accordance with the scanning molecule counting method using an optical measurement with a confocal microscope or a multiphoton microscope is characterized by detecting intensities of components of two or more wavelength bands of light from a light detection region of an optical system with moving the position of the light detection region in a sample solution by changing the optical path of the optical system of the microscope; detecting individually signals of the light from each light-emitting particle in the intensities of the components of the two or more wavelength bands of the detected light; and identifying a kind of light-emitting particle based on the intensities of the components of the two or more wavelength bands of the signals of the light of the detected light-emitting particle.

Abstract: Provided a target particle determining method of detecting a non-light emitting particle, including the steps of: (a) combining a non-light emitting observation particles, a solid phase carriers and a target particles in a first solution; (b) forming a complex of the target particle bound with a non-light emitting observation particle and a solid phase carrier; (c) removing the observation particles that are not bound to the target particles; (d) separating observation particles from solid phase carriers; (e) dispersing the separated observation particles in a second sample solution; (f) detecting the separated observation particles; and (g) determining the target particles that correspond to each of the detected observation particles in step (f).

Abstract: There is provided a single particle detection technique based on the scanning molecule counting method which individually detects single particles using light measurement with a confocal or multiphoton microscope, where the existences of a non-light-emitting particle and a light-emitting particle can be detected while being discriminated from one another in a sample solution. The inventive technique of detecting a single particle detects light from a light detection region during moving the position of the light detection region of the microscope in a sample solution containing a non-light-emitting particle and a light-emitting particle to generate time series light intensity data; and detects in the time series light intensity data a light intensity increase relative to background light intensity as a signal indicating the existence of the light-emitting particle and a light intensity reduction relative to the background light intensity as a signal indicating the existence of the non-light-emitting particle.

Abstract: There is provided an optical analysis technique enabling identification of a kind of light-emitting particle corresponding to a signal on a time series light intensity data or identification of a signal corresponding to light-emitting particles other than a particle to be observed in an optical measurement using a confocal microscope or a multiphoton microscope. The inventive optical analysis technique measures simultaneously and separately intensities of lights of two or more wavelength bands from a light detection region in a sample solution containing light-emitting particles of two or more kinds to generate time series light intensity data of the respective wavelength bands; detects signals simultaneously generated on the time series light intensity data of at least two wavelength bands; and identifies the simultaneously generated signals as signals of a light-emitting particle of at least one specific kind.

Abstract: Provided is a method for detecting a target particle that is a method for detecting a non-luminescent target particle dispersed and randomly moving in a sample solution using an optical system of a confocal microscope or multi-photon microscope, having: (a) preparing a sample solution containing target particles, and labeling particles of which the average outer diameter is less than 15% of the diameter of a photodetection region of the optical system, binding two or more molecules of the labeling particles per molecule of the target particles in the sample solution, and forming a non-luminescent complex of which the outer diameter is 15% or more of the diameter of the photodetection region; and, (b) calculating the number of molecules of the complex in the sample solution prepared in the (a) using an inverse scanning molecule counting method.