Disclosed is an apparatus and method for fluorescence excitation and detection. The apparatus comprises one or more light sources for providing excitation light for fluorescence excitation at an observation spot along an optical axis for excitation, an optical collection element for collecting fluorescence light generated by the excitation light at two or more different observation spots into two or more different measurement channels with an optical axis for collecting non-parallel to the optical axis for excitation of each of the one or more light sources, and, for each of the two or more measurement channels and thereby for each of the two or more observation spots, a dedicated optical detector for detecting fluorescence from the fluorescence light collected by the optical collection element.

A fluorescence observation apparatus (1) includes an irradiation unit (10) that applies a plurality of kinds of excitation light (L11, L21) of mutually different wavelengths to a plurality of spatially or temporally different positions in a biological sample (5) that is labeled with a composite phosphor containing two or more kinds of fluorescent molecules (A, B) at a predetermined composition ratio, a detection unit (20) that detects fluorescence (L12, L22) generated at each of the plurality of positions by application of the irradiation unit (10), and a calculation unit (33) that determines a distribution of pieces of the composite phosphor on the basis of a fluorescence signal (S1, S2) that is obtained from a detection result of the detection unit (20) and that shows a fluorescence intensity corresponding to a position in the biological sample (5) of each piece of the fluorescence (L12, L22).

A chromatographic testing device which is configured to select an imaging scheme according to the type of fluorescent dye in an immunochromatographic test cartridge and a method for controlling the same are disclosed. The chromatographic testing device can include: a body; a code expression recognition unit provided in the body and recognizing a code expression in which a type of fluorescent dye of an immune strip provided on an immunochromatographic test cartridge mounted on the body is recorded; an excitation light source emission unit for emitting light from an excitation light source to the immunochromatographic test cartridge; an image sensor unit for recognizing excitation light generated by the excitation light source; and a control unit for controlling the image sensor unit in a single imaging scheme or a cumulative light imaging scheme according to the type of fluorescent dye of an immune strip, recognized by the code expression recognition unit.

An example system for inspecting a surface includes a laser, an optical system, a gated camera, and a control system. The laser is configured to emit pulses of light, with respective wavelengths of the pulses of light varying over time. The optical system includes at least one optical element, and is configured to direct light emitted by the laser to points along a scan line one point at a time. The gated camera is configured to record a fluorescent response of the surface from light having each wavelength of a plurality of wavelengths at each point along the scan line. The control system is configured to control the gated camera such that an aperture of the gated camera is open during fluorescence of the surface but closed during exposure of the surface to light emitted by the laser.

An apparatus has a transducer with a storage phosphor that is chargeable to emit light of a first wavelength in response to an excitation light of a second wavelength from an object scene, wherein the second wavelength is longer than the first wavelength. A digital light sensor is disposed to accumulate energy from the emitted light of the transducer and to generate a signal according to the accumulated energy. A charging illumination source is configured to direct a pulsed charging illumination of a third wavelength, shorter than the first wavelength, to the storage phosphor. A control logic processor is in signal communication with the digital light sensor and the charging illumination source and controls synchronization of the timing of pulsed charging illumination and energy acquisition and readout of the digital light sensor.

The present disclosure provides methods, apparatus and systems for time-gated fluorescent-based detection. Time-based fluorescence analysis can be used in certain biochemical assays by measuring the emitted photon flux from fluorophores after an individual excitation pulse.

An example system for inspecting a surface includes a laser, an optical system, a gated camera, and a control system. The laser is configured to emit pulses of light, with respective wavelengths of the pulses of light varying over time. The optical system includes at least one optical element, and is configured to direct light emitted by the laser to points along a scan line one point at a time. The gated camera is configured to record a fluorescent response of the surface from light having each wavelength of a plurality of wavelengths at each point along the scan line. The control system is configured to control the gated camera such that an aperture of the gated camera is open during fluorescence of the surface but closed during exposure of the surface to light emitted by the laser.

An example system for inspecting a surface includes a laser, an optical system, a gated camera, and a control system. The laser is configured to emit pulses of light, with respective wavelengths of the pulses of light varying over time. The optical system includes at least one optical element, and is configured to direct light emitted by the laser to points along a scan line one point at a time. The gated camera is configured to record a fluorescent response of the surface from light having each wavelength of a plurality of wavelengths at each point along the scan line. The control system is configured to control the gated camera such that an aperture of the gated camera is open during fluorescence of the surface but closed during exposure of the surface to light emitted by the laser.

The present disclosure provides methods, apparatus and systems for time-gated fluorescent-based detection. Time-based fluorescence analysis can be used in certain biochemical assays by measuring the emitted photon flux from fluorophores after an individual excitation pulse.

An example system for inspecting a surface includes a laser, an optical system, a gated camera, and a control system. The laser is configured to emit pulses of light, with respective wavelengths of the pulses of light varying over time. The optical system includes at least one optical element, and is configured to direct light emitted by the laser to points along a scan line one point at a time. The gated camera is configured to record a fluorescent response of the surface from light having each wavelength of a plurality of wavelengths at each point along the scan line. The control system is configured to control the gated camera such that an aperture of the gated camera is open during fluorescence of the surface but closed during exposure of the surface to light emitted by the laser.