A system (100) and a method for detecting fluorescence is disclosed. The system (100) essentially comprises a labelled sample wherein said labelled sample emits an electromagnetic radiation of a defined wavelength when irradiated by a LASER beam of a commensurate wavelength, a source (102) for emitting said LASER beam, oriented as to aim at said labelled sample, a chamber for holding said labelled sample during said LASER irradiation, a reflective layer (108) positioned to reflect said electromagnetic radiation, and a detector (112) positioned to detect and amplify said electromagnetic radiation. The method essentially comprises the steps of providing a labelled sample wherein said labelled sample emits an electromagnetic radiation of a defined wavelength when irradiated by a LASER beam of a commensurate wavelength, providing a source (102) for emitting said LASER beam, oriented as to aim at said labelled sample, providing a chamber for holding said labelled sample during said LASER irradiation, providing a reflective layer (108) positioned to reflect said electromagnetic radiation, providing a detector (112) positioned to detect and amplify said electromagnetic radiation, irradiating said sample with said LASER beam and analyzing said amplified electromagnetic radiation from said detector (112) with a signal processing block (114).

In a right-handed XYZ coordinate system, a dichroic-mirror array of the present disclosure includes a first group in which m (m≥2) dichroic mirrors DA1 to DAm are arranged parallel to each other along a positive direction of an X axis and a second group in which n (n≥2) dichroic mirrors DB1 to DBn are arranged parallel to each other along a negative direction of the X axis. Incident surfaces of the DA1 to DAm and incident surfaces of the DB1 to DBn are perpendicular to an XZ plane. A slope of straight lines with normal lines of the incident surfaces of the DA1 to DAm projected onto the XZ plane are negative, and a slope of straight lines with normal lines of incident surfaces of DB1 to DBn projected onto the XZ plane are positive.

The present invention relates to a method for detecting an analyte in a sample, comprising the steps of: forming on each of carrier particles a complex containing a first capture substance capable of binding to an analyte, one molecule of the analyte, a second capture substance capable of binding to the analyte, and a catalyst; immobilizing a reaction product on each of the carrier particles by reacting the catalyst in the compolex with a substrate; and detecting the analyte by detecting the carrier particles on each of which the reaction product is immobilized.

A method of fluorescence spectroscopy includes providing a high-performance sensor that combines imaging with high intrinsic time resolution and high-rate capability, and resolving fluorescence data in four dimensions.

A method of detecting a pathogen in a sample, comprising: mixing at least a portion of the sample with a plurality of capture particles functionalized with a molecular recognition element exhibiting specific binding to said pathogen to capture at least a portion of pathogen particles when present in the sample; exposing said captured pathogen particles to at least two fluorescent dyes, which emit fluorescent radiation at two different wavelengths in response to excitation, such that live pathogen particles among said captured pathogen particles are preferentially stained with one of the dyes and dead pathogen particles among said captured pathogen particles are preferentially stained with the other dye; irradiating the captured stained pathogen particles with excitation radiation to excite said fluorescent dyes; and detecting fluorescent radiation emitted by said excited fluorescent dyes; and distinguishing said live pathogen particles from said dead pathogen particles based on wavelengths of the detected fluorescent radiation.

A convective polymerase chain reaction apparatus and an optical detecting method thereof are provided. The optical detecting method includes the following steps. A substance in a tube to be tested is heated. At least two monochromatic lights are provided and are combined using a light combining element to irradiate the tube to be tested. At least two excited lights generated by exciting the substance in the tube to be tested by the at least two monochromatic lights are sensed.

There are provided a control device of an image reading apparatus, an operation method and an operation program thereof, and an image detection system capable of quickly and easily outputting an image having an appropriate density for analysis from an image reading apparatus. An image receiving unit receives a pre-image output in pre-scanning performed before main scanning for outputting a main image for analysis in an image reading apparatus. A region information receiving unit receives information of a region in the pre-image designated by a user. A calculation unit calculates an appropriate voltage value that is a voltage value of the photomultiplier at which a density of the region becomes an appropriate density for analysis. A scanning conditions setting unit sets the appropriate voltage value as temporary scanning conditions of main scanning.

Described herein are 3D single-molecule super-resolution imaging systems and methods. The provided systems and methods use modulation interferometry and phase-sensitive detection techniques that achieve less than 2 nanometer axial localization precision, which is well below the 5-10-nanometer-sized individual protein components. To illustrate the capability of this technique in probing the dynamics of complex macromolecular machines, (1) movement of individual multi-subunit E. coli RNA Polymerases were visualized through the complete transcription cycle, (2) kinetics of the initiation-elongation transition were dissected, (3) the conformational changes from the open initiation complex to the elongation complex were analyzed, and (4) the fate of σ.sup.70 initiation factors during promoter escape were determined.

Techniques are described for reducing the number of angles needed in structured illumination imaging of biological samples through the use of patterned flowcells, where nanowells of the patterned flowcells are arranged in, e.g., a square array, or an asymmetrical array. Accordingly, the number of images needed to resolve details of the biological samples is reduced. Techniques are also described for combining structured illumination imaging with line scanning using the patterned flowcells.

A light-emission detection apparatus is provided for individually condensing light emitted from each emission point of an emission-point array using each condensing lens of a condensing-lens array to forma light beam and detecting each light beam incident on a sensor in parallel. The light-emission detection apparatus can be downsized and high sensitivity and low crosstalk can be simultaneously accomplished when a certain relation between the diameter of each emission point, a focal length of each condensing lens, an interval of condensing lenses, and an optical path length between each condensing lens and a sensor is satisfied.