The method enables a concentration of a species in a culture medium (12) to be estimated using an estimation system (10) comprising a light source (16), a transparent substrate (14) and a matrix photodetector (18), the substrate being located between the source and the photodetector, the medium comprising biological particles (32) and changing colour when said concentration varies. Said method comprises the following steps:—placing the medium on the substrate,—illuminating the medium via the light source,—acquisition of an image of the medium via the photodetector, each image being formed by a ray transmitted by the illuminated medium and comprising at least one diffraction pattern, each diffraction pattern corresponding to the waves diffracted by a biological particle when the medium is illuminated,—and calculating an estimate of said concentration as a function of a pixel intensity of the acquired image.

Microfluidic devices, systems and techniques in connection with particle sorting in liquid, including cytometry devices and techniques and applications in chemical or biological testing and diagnostic measurements.

Methods, systems, and devices are disclosed for imaging particles and/or cells using flow cytometry. In one aspect, a method includes transmitting a light beam at a fluidic channel carrying a fluid sample containing particles; optically encoding scattered or fluorescently-emitted light at a spatial optical filter, the spatial optical filter including a surface having a plurality of apertures arranged in a pattern along a transverse direction opposite to particle flow and a longitudinal direction parallel to particle flow, such that different portions of a particle flowing over the pattern of the apertures pass different apertures at different times and scatter the light beam or emit fluorescent light at locations associated with the apertures; and producing image data associated with the particle flowing through the fluidic channel based on the encoded optical signal, in which the produced image data includes information of a physical characteristic of the particle.

A fractionation system comprising means for forming a three dimensional optical lattice that is operable to separate particles that have different physical characteristics. Preferably, the wells of the optical lattice are interlinked. For example, the wells may be linked in such a manner as to provide deflection greater than or equal to 15 degrees.

An analysis device includes an analysis unit configured to receive scattered light, transmitted light, fluorescence, or electromagnetic waves from an observed object located in a light irradiation region light-irradiated from a light source and analyze the observed object on the basis of a signal extracted on the basis of a time axis of an electrical signal output from a light-receiving unit configured to convert the received light or electromagnetic waves into the electrical signal.

A method of detecting particles (1), e.g. proteins, after separation of particles based on their specific features, e.g. charge, size, shape, density, as series of single light scattering events created by the individual particles is described. The particles (1) are separated from each other along the separation path (11) and particles have specific arrival times at the target side depending on the particle features. The detecting step comprises an interferometric sensing of the light scattered at individual particles bound or transient in the detection volume (30). Parameters of the scattering light signals e.g. the interferometric contrast are analysed for obtaining specific particle features, e.g. size, mass, shape, charge, or affinity of the particles (1). Furthermore, a detection apparatus (100) being configured for detecting particles (1) is described.

The present invention provides a system and method of particle size and concentration measurement that comprises the steps of: providing a focused, synthesized, structured laser beam, causing the beam to interact with the particles, measuring the interaction signal and the number of interactions per unit time of the beam with the particles, and using algorithms to map the interaction signals to the particle size and the number of interactions per unit time to the concentration.

This disclosure pertains to analytical instruments and related methods incorporating beam shaping optics for differentiating very bright and closely related signals over a wide range of operating conditions with an improved and uniform performance.

The present invention discloses a three-dimensional diffraction tomography microscopy imaging method based on LED array coded illumination. Firstly, acquiring the raw intensity images, three sets of intensity image stacks are acquired at different out-of-focus positions by moving the stage or using electrically tunable lens. And then, after acquiring the intensity image stacks of the object to be measured at different out-of-focus positions, the three-dimensional phase transfer function of the microscopy imaging system with arbitrary shape illumination is derived. Further, the three-dimensional phase transfer function of the microscopic system under circular and annular illumination with different coherence coefficients is obtained as well, and the three-dimensional quantitative refractive index is reconstructed by inverse Fourier transform of the three-dimensional scattering potential function. The scattering potential function is converted into the refractive index distribution. Thus, the quantitative three-dimensional refractive index distribution of the test object is obtained. The invention realizes high-resolution and high signal-to-noise ratio 3D diffraction tomography microscopic imaging of cells, tiny biological tissues and other samples.

Disclosed are methods, devices, systems and applications for camera-less, high-throughput three-dimensional imaging of particles in motion. In some aspects, a system includes a particle motion device to allow particles to move along a travel path; an optical illumination system to produce an asymmetric illumination area of light in a region of the travel path of a particle that scans over a plurality of sections of the particle at multiple time points while the particle is moving; an optical detection system optically interfaced with the particle motion device to obtain optical signal data associated with different parts of the particle corresponding to the particle's volume during motion in the travel path; and a data processing unit to process the optical signal data obtained by the optical detection system and produce data including information indicative of 3D features of the particle.