A particle detector that includes a housing defining a chamber, and an air stream injector, producing an airstream with entrained particles, in the chamber. A light source produces a light beam that intersects with and is wider than the air stream. A light detection assembly detects light generated by scattering of the light beam, by particles in the air stream. A digitizer produces a sequence of scattering digital values, each representing light detected per a first unit of time duration. Additionally, a summing assembly produces a sequence of summed scattering digital values, each equaling a sum of a sequential set of n of the digital values, and wherein successive summed digital values are offset by a the first unit of time duration and overlap by n1 of the first units of time duration with a nearest neighbor. Finally, a detection assembly processes the summed scattering digital values to detect particles.

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.

A method of sorting cells including magnetically coupling a nozzle assembly to a flow cytometer in a predetermined orientation to form a fluid stream having a sheath fluid and a sample fluid. Particles within the sample fluid are oriented and then interrogated at an inspection zone to produces signals representative of emitted or reflected electromagnetic radiation. The electromagnetic radiation is analyzed to classify the cells and the cells are sorted according to their classification.

Disclosed is a sheath delivery system that uses a continuous flow of sheath fluid into a pressurized internal reservoir that substantially matches the outflow of sheath fluid through the nozzle of a flow cytometer. A substantially constant level of the sheath fluid is maintained. If the sheath fluid level falls below a desired level, or goes above a desired level, a dampened control system is used to reach the desired level. In addition, air pressure in the pressurized internal container is controlled so that an external sheath container can be removed and refilled with additional sheath fluid without stopping the sheath delivery system 100. Differences in pressure are detected by a droplet camera, which measures the droplet breakoff point to determine the pressure of the sheath fluid in the nozzle.

A system capable of measuring particulates includes: a nozzle formed in the shape of a tube; a light measurement unit constituted by a light source supplied as energy and a photodetector and is provided adjacent to the nozzle; a probe having a hollow shape and into which one end of the nozzle is inserted; a particle measurement unit provided adjacent to the light measurement unit to measure the particulates introduced through the nozzle; an evaluation model unit linked to the particle measurement unit to evaluate the volume of the particulates on the basis of software; and an evaluation process unit linked to the evaluation model unit to evaluate each of a volume size distribution of the particulates, an integration with respect to the size of each of the particulates and a time, and the volume concentration of the particulates. Other components are also included in the system.

A microfluidic chip having a micro channel for processing a sample is provided. The micro channel may focus the sample by using focusing fluid and a core stream forming geometry. The core stream forming geometry may include a lateral fluid focusing component and one or more vertical fluid focusing components. A microfluidic chip may include a plurality micro channels operating in parallel on a microfluidic chip.

A microfabricated sheath flow structure for producing a sheath flow includes a primary sheath flow channel for conveying a sheath fluid, a sample inlet for injecting a sample into the sheath fluid in the primary sheath flow channel, a primary focusing region for focusing the sample within the sheath fluid and a secondary focusing region for providing additional focusing of the sample within the sheath fluid. The secondary focusing region may be formed by a flow channel intersecting the primary sheath flow channel to inject additional sheath fluid into the primary sheath flow channel from a selected direction. A sheath flow system may comprise a plurality of sheath flow structures operating in parallel on a microfluidic chip.

An external fluidic system and methods of operating the same are provided. The fluidic system can be hot-swap connected to a flow-cytometer-based system at runtime to expand sheath or waste fluid storage capability of the flow-cytometer-based system by making only minimal changes to the flow-cytometer-based system. The external fluidic system can include a pump and a controller configured to operate the external fluidic system such that the sheath fluid is supplied from the external fluidic system to the flow-cytometer-based system or the waste fluid is extracted from the flow-cytometer-teased system and provided to the external fluidic system.

The present invention provides microfabricated substrates and methods of conducting reactions within these substrates. The reactions occur in plugs transported in the flow of a carrier-fluid.

A sensor is provided for detecting and characterizing particles in a fluid. The sensor has a microfluidic channel for receiving the fluid sample, an acoustic transducer module configured to generate a standing wave for concentrating the particles in a region of the microfluidic channel; an optical detection module configured to detect optical signals scattered by the particles upon illuminating the region of the fluid sample with a light source; and a data processing module configured to characterize the particles of the fluid sample based on the optical signals using a classifier.