The system includes an adjustable light source constructed to direct a beam of electromagnetic radiation at a specimen chamber that allows a portion of the beam to scatter when illuminating particles within the chamber. The scattered portion of the beam is directed to a sensor, the sensor having a frame rate and a time period between frames. The system may have a processor connected to the sensor and light source, the processor may perform the following steps: activate the light source and obtain images from sensor; if the images from the sensor show that particles are blinking then reduce the frame rate, set the exposure time to at least 60% of the time between frames and reduce the illumination. Then the processor obtains additional images and processes those images to mitigate blurring. The processor determines the Brownian motion of the particles from the processed images and determines the sizes of the particles based on the motion.

An image flow cytometer for observing a microparticulate sample includes a flow chamber having a flow channel that permits the microparticulate sample to travel in a flow direction. An irradiation system scans an irradiation spot across a sensing area of the flow channel in a scan direction different from the flow direction. A detection system detects resultant light from the sensing area and provides a detection signal. An alignment system alters a location of the sensing area with respect to the flow chamber. A control unit causes the irradiation system to scan the irradiation spot during a first measurement interval and operates the alignment system to translate the location of the sensing area along the flow direction. The flow chamber can be mounted to a movable stage in some examples, and the alignment system can move the flow chamber substantially opposite the flow direction using the stage.

The disclosure provides a system, compositions, and methods for detecting ovarian cancer cells by photoacoustic flow cytometry.

A liquid droplet forming device includes a liquid droplet discharger that discharges, as a liquid droplet, a particle suspension liquid in which one or more fluorescent particles are suspended; a light source for irradiating light onto the flying liquid droplet discharged from the liquid droplet discharger; a photodetector that receives fluorescence that is emitted by the one or more fluorescent particles included in the liquid droplet in response to the light as excitation light; and a particle number detector that detects a number of the one or more fluorescent particles included in the liquid droplet based on information from the photodetector.

A system for orienting particles in a microfluidic system includes one or more radiation pressure sources arranged to expose particles to radiation pressure to cause the particles to adopt a particular orientation in the fluid. A system for sorting particles in a microfluidic system includes a detection stage arranged to detect at least one difference or discriminate between particles in the fluid flow past the detection stage, and one or more radiation pressure sources past which the particles move sequentially and a controller arranged to switch radiation energy to cause a change in direction of movement of selected particles in the fluid flow to sort the particles. The particles may be biological particles such as spermatazoa. The radiation pressure may be optical pressure and may be from one or more waveguides which may extend across a channel of the microfluidic system.

The present technology provides a technology for stabilizing break-off timings. Therefore, according to the present technology, there is provided a microparticle analysis device or the like including at least: a flow path in which a fluid including a sample flow containing microparticles and a sheath flow flowing to contain the sample flow; a droplet formation unit configured to form a droplet in the fluid by imparting vibration to the fluid using a vibration element; an electric charge application unit configured to apply electric charge to a droplet containing the microparticles; an imaging unit configured to obtain a photo of a phase of a certain time; and a control unit configured to control a timing at which the droplet breaks off on a basis of the photo.

Aspects of the present disclosure include methods and systems for detecting light from a sample in a flow stream by multi-photon counting. Methods according to certain embodiments include irradiating a sample in a flow stream with a light source and detecting light from the sample in the flow stream and counting photons of the detected light by integrating photo-electron charge over a time interval. Methods also include irradiating a sample in a flow stream with a light source, detecting light from the sample in the flow stream and outputting a digital output signal and an analog output signal produced by the detected light. Systems for detecting light from a sample in a flow stream with a detector and counting photons by integrating photo-electron charge over a time interval are also described. Kits having a detector, a photon counter and a flow cell configured to propagate a sample in flow stream are also provided.

In the present technology, the timing at which suction is performed is optimized in order to enhance the microparticle separation performance in a technology for separating target microparticles in a microchip. For this purpose, the present technology provides a method of optimizing a microparticle suction condition, and the like, using a microchip having a main flow channel through which a liquid containing a microparticle flows, a microparticle suction flow channel arranged coaxially with the main flow channel, and a branch flow channel branching from the main flow channel. The method includes: a branch point specifying process of specifying a branch point at which the branch flow channel branches from the main flow channel; and a time assignment process of assigning a time T.sub.1 to be applied to suction of the microparticle, on the basis of a distance between a position of the microparticle and the branch point at a time point when a predetermined time T.sub.X has elapsed from a time when the microparticle passed through a predetermined position on the main flow channel.

A measurement system includes a system for causing relative motion between a sample and an irradiation spot. The sample includes fluorescent markers having respective wavelengths. A gating system provides a gating signal based at least in part on resultant light substantially at an irradiation wavelength. A detection system detects fluorescent light from the irradiated markers and provides detection signals representing the fluorescent light detected concurrently with a gate-open signal. In some examples, the detection system detects fluorescent light at multiple wavelengths and provides respective detection signals. A spectral discriminator arranged optically between the sample and the detection system receives the fluorescent light from the sample and provides respective fluorescent light at the wavelengths to the detection system. A flow cytometer can spectrally disperse resultant fluorescent light and measure the wavelengths separately. Light from a sample disposed over a reflective phase grating can be dispersed, measured, and gated.

Aspects of the present disclosure include methods for generating a bitmap from a data plot of light detected from particles in a flow stream. Methods according to certain embodiments include detecting light from particles in a flow stream, generating a data plot of measurements of the detected light, where the data plot includes one or more regions each having a population of particles, calculating a set of vertices that form a boundary for each region in the data plot, identifying a type of algorithmic transformation associated with each vertex in the set of vertices, generating a bitmap of each region of particles such that the bitmap of each region includes a set of vertices that correspond to the vertices of each region in the data plot and identifying an algorithmic transformation for applying to each vertex in the bitmap of each region. Systems and integrated circuit devices (e.g., field programmable gate arrays) having programming for generating a bitmap according to the subject methods are also provided.