A system and a method for sorting particles are provided. An example of a particle sorting system includes an array that includes a number of microfluidic ejectors. An optical sensor is focused on the array. A controller is used to identify a target particle proximate to a microfluidic ejector, and activate the microfluidic ejector to eject the target particle into a collection vessel.

A method is provided for detecting a composition of airborne particles. The method includes directing, with a pump, gas including particulate matter through a filter including an indicator dye. The method further includes causing a color change in the filter based on the particulate matter binding to the indicator dye. The method further includes transmitting, with an optical source, an optical signal at the filter. The method further includes detecting, with an imaging device, a reflected signal from the filter. The method further includes determining, with a processor, a value of a parameter of the particulate matter based on the color change, wherein the color change is based on the detected reflected signal.

Disclosed is an optical trap calibration apparatus and method based on variation of electric field by optical imaging of a nanoparticle. By means of a direct optical imaging method, a linear nanoparticle equilibrium position displacement under the action of a constant electric field is measured to realize calibration, thereby avoiding the introduction of error signals, and improving the reliability of differential calibration. The specific calibration method and apparatus of the present invention are not only suitable for calibration of electric field quantity, but also suitable for the calibration of other magnetic forces and the like. By means of the accurate calibration of mechanical quantity in the present invention, the development and application of the vacuum optical trap sensing technology can be promoted.

The invention relates to a method for determining the florescence of antibodies on exosomes using quality control of the measurement using two different control methods.

A method for detecting particles in a liquid includes following operations. A detection device is provided. A chemical liquid is provided to flow through the detection device. A capacitance of the detection device is measured during the flowing of the chemical liquid. A dielectric constant of the chemical liquid is calculated according to the capacitance of the detection device. When the dielectric constant of the chemical liquid is between an upper limit and a lower limit, the chemical liquid is determined to be normal.

Disclosed is a multi-dimensional optical tweezers calibration device based on electric field quantity calibration and a method thereof. The polarization-dependent characteristics of a tightly focused optical trap are utilized to realize triaxial electric field force calibration of particles through a one-dimensional electric field quantity calibration device. The method of the present application enables a particle electric field force calibration system to be compatible with particle delivery and particle detection systems; the device is simplified and calibration complexity is reduced.

A micro-nano particle detection device and method are disclosed. The device includes a sample chamber and at least two measurement chambers, where at least one through hole is formed between each measurement chamber and the sample chamber, each measurement chamber is communicated with the sample chamber only through the through hole, a common electrode is arranged in the sample chamber, a measurement electrode is arranged in each measurement chamber respectively, a first end of the sample chamber is provided with a first liquid driving device, and the common electrode is grounded.

An optical method of characterizing an object comprises providing an object to be characterized, the object having at least one nanoscale feature; illuminating the object with coherent plane wave optical radiation having a wavelength larger than the nanoscale feature; capturing a diffraction intensity pattern of the radiation which is scattered by the object; supplying the diffraction intensity pattern to a neural network trained with a training set of diffraction intensity patterns corresponding to other objects with a same nanoscale feature as the object to be characterized, the neural network configured to recover information about the object from the diffraction intensity pattern; and making a characterization of the object based on the recovered information.

A particle analysis device includes a liquid space adapted to store a liquid; a chip disposed above the liquid space, the chip having a connection pore extending vertically and communicating with the liquid space; an upper hole disposed above the chip, the upper hole extending vertically and communicating with the connection pore; a first electrode adapted to apply an electric potential to a liquid in the upper hole; and a second electrode adapted to apply an electric potential to the liquid in the liquid space. The upper hole having a diameter that is equal to or greater than the maximum width of the connection pore, and the entirety of the connection pore falling within the range of the upper hole.

A microfluidic chip for focussing a stream of particulate containing fluid comprises a sample microfluidic channel configured to receive the stream of particulate containing fluid, a guidance microfluidic channel having a polygonal cross-sectional area and configured to receive a stream of guidance fluid, and a common microfluidic channel having a polygonal cross sectional area formed by the merging of the sample microfluidic channel and the guidance 10 microfluidic channel at an oblique angle along only part of one or more sides of the guidance microfluidic channel, and a detection zone disposed in the common microfluidic channel having one or more sensors. The merging of the sample microfluidic channel and the guidance microfluidic channel is configured to provide a composite fluid stream containing a focussed beam of particulates that is disposed asymmetrically in the common microfluidic channel 15 adjacent a corner or side of the common microfluidic channel and wherein the one or more sensors are configured for sensing a characteristic of the focussed beam of particulates in the common channel.