Apparatus and methods for detecting, characterizing, and compensating motion-related error of moving micro-entities are described. Motion-related error may occur in streams of moving micro-entities, and may represent a deviation in and expected arrival time or an uncertainty in position of a micro-entity within the stream. Motion-related error of micro-entities is observed in a flow cytometer, e.g., as pulse jitter, and is found to have a functional dependence on a parameter of the system. The pulse jitter can be compensated, according to one embodiment, by adjusting data acquisition observation windows. For the flow cytometer, a reduction of pulse jitter can improve measurement accuracy, resolution of doublets, system throughput, and enable an increase in an interrogation region for probing the micro-entities.

The present invention provides system and method for three-dimensionally tracking micro particle motion wherein a dark-field condenser is configured to receive light field emitted from a light source and project the light field on a fluid sample having at least one particle thereby generating a scattered light field associated with the at least one particle, an objective lens is configured to receive the scattered light field, an image capturing unit coupled to the objective lens receives the scattered light field thereby generating at least one image of the fluid sample, and a controller is configured to couple to the image capturing unit for analyzing interference ring pattern corresponding to a specific particle in the at least one image and determining a tracking information associated with the specific particle along three-dimensional direction according to the size and center of the interference ring pattern.

A system and a method of measuring a particle's size in a select aerosol using the optical diameter of the particle to perform a mobility and/or aerodynamic diameter conversion without any knowledge about the particle's shape and its optical properties in the aerosol being characterized. In one example embodiment of the invention, the method includes generating a set of calibration data and finding the optimal refractive index and shape that best fits the calibration data. In addition, the method includes creating a new calibration curve that provides a mobility-equivalent or aerodynamic-equivalent diameter.

The apparati, methods, and computer program products disclosed herein can be used to nondestructively detect undissolved particles, such as glass flakes and/or protein aggregates, in a fluid in a vessel, such as, but not limited to, a fluid that contains a drug.

The invention relates to a method for optically characterizing dielectric particles such as virus or biological particles of submicrometre size, by e.g. holographic microscopy. In particular, the invention is directed to mixing dielectric particles with non-dielectric particles which when mixed will bind to the dielectric particle.

Systems and methods for automated detection and classification of objects in a fluid of a receptacle such as, for example, a soft-sided receptacle such as a flexible container. The automated detection may include initiating movement of the receptacle to move objects in the fluid contained by the receptacle. Sequential frames of image data may be recorded and processed to identify moving objects in the image data. In turn, at least one motion parameter of the objects may be determined and utilized to classify the object into at least one of a predetermined plurality of object classes. For example, the object classes may at least include a predetermined class corresponding to bubbles and a predetermined class corresponding to particles.

An optical proximity sensor includes a first vertical cavity surface-emitting laser configured for self-mixing interferometry to determine distance to and/or velocity of an object. The optical proximity sensor also includes a second vertical cavity surface-emitting laser configured for self-mixing interferometry to determine whether any variation in a fixed distance has occurred. The optical proximity sensor leverages output from the second vertical cavity surface-emitting laser to calibrate output from the second vertical cavity surface-emitting laser to eliminate and/or mitigate environmental effects, such as temperature changes.

A system includes a device configured to facilitate an interaction between a first fluid flow and a second fluid flow within a flow path of the device; an optical sensor configured to obtain one or more images representing the flow path; an image analysis module configured to: process the images to identify at least one droplet generated in a flow path of the device by the interaction between the first fluid flow and the second fluid flow, and estimate a size of the at least one droplet; and a control system configured to: determine that the size of the at least one droplet satisfies a threshold condition, and responsive to determining that the size of the at least one droplet satisfies the threshold condition, generate a signal that causes an adjustment to a flow rate of at least one of the first fluid flow or the second fluid flow.

There is provided a system, method, and lighting module for fast-moving particle characterization. The lighting module can include a light source directed at the particles to generate a light beam of incoherent or semi-coherent light; and a pulse generator connected to the light source to direct the light source to generate the light beam when in receipt of a trigger signal, the pulse including a time period on a nanosecond scale. In some cases, the light beam can be conditioned with optical elements into a homogeneous flat-top profile. In some cases, the trigger signal is generated by a camera module, which is passed through a synchronization board to compensate for any noise.

The present invention concerns a system for phenotypical profiling of at least one object and deterministic nanoliter-droplet encapsulation, comprising sample supplying means, buffer supplying means; a microfluidic chip comprising an encapsulation area or structure in which the object is encapsulated with a quantity of the reaction buffer by the droplet; detection means configured to detect the passage of the object through the first imaging chamber; at least one valve configured to stop the flow of the sample buffer when the detection means detect passage of the object through the first imaging chamber; phenotypical assessing means configured to assess the phenotype of the object when the flow of the sample buffer is stopped by the valve and the object is at an object stopping site; a droplet deposition means configured to deposit the droplet in a well or in a well of a multi-well plate and comprising an outlet capillary.