A system for nucleic acid (NA) amplification includes a light source configured to emit a first excitation light based on a control signal, a reaction chamber configured to house a solution including a plurality of first nucleic acids (NAs), the plurality of first NAs being configured to amplify in response to the first excitation light, the solution being configured to emit a second light in response to heating by the first excitation light and to emit a third light in response to amplification of the plurality of first NAs, a detector configured to detect the second and third lights and to generate a temperature signal corresponding to the second light and a first fluorescence signal corresponding to the third light, and a lens module configured to focus the second and third lights onto the detector.

The present disclosure provides a method for detection of an analyte in a sample, where the sample is introduced into an analytic chamber along with droplets of an emulsion or gel beads. In another aspect, the present disclosure provides designs for formulations of emulsion drops or gel beads such that they are useful for detection of analytes in a massively parallel manner. Formulations that contain specific combinations of fluorescent particles allow optical determination of the identity of each fluorescent particle. The combinations are based on particle fluorescence emission wavelength, fluorescence excitation wavelength, and particle count.

The disclosed technology relates to the field of nucleic acid sequencing, and more particularly, to systems and methods for DNA sequencing utilizing a single optical excitation and at least three fluorescent labels. In some embodiments, the disclosed technology uses a first nucleotide coupled to a first fluorescent label which can emit light to be detectable by a first detector, a second nucleotide coupled to a second fluorescent label which can emit light to be detectable by a second detector, a third nucleotide coupled to a third fluorescent label which can emit light to be detectable by both the first and second detectors, and a fourth nucleotide coupled to no fluorescent label. The disclosed technology may identify a nucleotide in the nucleic acid sequence based on whether the emission is received by the first detector, the second detector, both the first and second detectors, or neither the first nor second detector.

Disclosed is a fluorescence image analyzer for measuring and analyzing a sample that includes a plurality of cells in which target portions are labeled with fluorescent dyes, and the fluorescence image analyzer includes a light source configured to apply light to the sample; an imaging unit configured to take a fluorescence image of each of the cells by which fluorescence is generated by applying the light; a processing unit configured to process the fluorescence image having been taken; and a display unit. The processing unit obtains a bright point pattern of fluorescence in the fluorescence image, causes the display unit to display a plurality of positive patterns that are previously associated with at least one of a measurement item or a labeling reagent, and causes the display unit to display information of at least one of the number of abnormal cells included in the sample, a proportion of the number of the abnormal cells, the number of normal cells included in the sample, and a proportion of the normal cells, based on the bright point pattern having been obtained and the plurality of positive patterns.

A ternary fluorescence correlation spectroscopy system for analyzing an interaction between three kinds of molecules, including at least three excitation light sources with different wavelengths. The excitation light sources are configured to illuminate and excite a sample to generate a fluorescence signal. The fluorescence signal is divided into multiple signals according to wavelength, which are then respectively detected by a single photon detector and transmitted to a signal acquisition and operation card to perform real-time operation of a triple-correlation function, so as to obtain a fluorescence triple-correlation spectroscopy curve.

The present invention provides a wide-area sample-based reader design which serves as a diagnostic detection device for bio-particles.

A system and method for high resolution multi-fluorescence imaging with synchronized image acquisition amongst sensors can be used to simultaneously capture fluorescence signals from multiple fluorophores over extremely large fields of view. The system can include an array of micro-cameras, along with a particular arrangement of fluorescent filters that can be fixed in one location or moved to new locations.

Hardware and control software for use in the field of digital imaging and spectroscopy. More particularly, a hardware and software system that simultaneously measures electromagnetic energy as quantities of photons in distinct wavelength regions across the ultraviolet, visible, and infrared spectrum. The system records the measurements as digital data and employs a processor (preferably a programmable processor) that executes processing steps to enhance the spatial and spectral fidelity of the recorded signals. More specifically, the electro-optical sensor hardware is engineered to maximize the light collection efficiency, especially for low light intensities, by using multiple detectors, each of which is optimized individually to maximize its sensitivity to specific wavelength regions of interest. The detector system also employs a variable amplification process that is dependent on the signal intensity so that low signals can be increased for better detection while high signals are amplified less to stay within the dynamic range of the optical sensor that is used to convert the analog signal to a digital value. Solutions to existing problems of low light detection are provided as are new capabilities for data collection and analysis in previously undetectable low signal regimes. The systems and methods are applicable to a broad array of imaging applications in diverse fields from biomedical imaging to astronomy and remote sensing.

A microfluidic analyser and a method of using the same is disclosed. The microfluidic analyser comprising a droplet generator, an analyte flow channel in fluid communication with said droplet generator at a first end, wherein said flow channel is configured to allow the droplets to flow in from the first end and exit from a second opposing end, said flow channel receiving at least one illumination channel positioned at a predetermined location between the first and the second end to excite contents of the droplets and said flow channel further comprising a plurality of receiving channels set at predetermined angles to an axis of the flow channel to interrogate at least one optical signal from the illuminated droplet traversing the flow channel and wherein said receiving channels terminate in a signal detector at the distal end away from the flow channel.

The disclosed embodiments relate to multimodal imaging system, comprising: a fiber-coupled fluorescence imaging system, which operates based on ultra-violet (UV) excitation light; and a fiber-coupled optical coherence tomography (OCT) imaging system. The multimodal imaging system also includes a fiber optic interface comprising a single optical fiber, which facilitates light delivery to a sample-of-interest and collection of returned optical signals for both the fluorescence imaging system and the OCT imaging system. During operation of the system, the single optical fiber carries both UV light and coherent infrared light through two concentric light-guiding regions, thereby facilitating generation of precisely co-registered optical data from the fluorescence imaging system and the OCT imaging system.