A process for preparing paramagnetic compounds is described. A paramagnetic compound made by the process is described, including its use in density-based analysis by MagLev.

This technology relates in part to optical methods for analyzing particles, including nanoparticles, thereby determining their presence, identity, origin, size and/or number in a sample of interest.

Portable real-time airborne fungi acquiring and detecting equipment and method are provided, the equipment includes a light source device, a manual constant-flow air pump, an impactor, an airborne fungi enrichment and dyeing device, and a fluorescence data collecting and processing device sequentially connected. The fluorescence detection technology is combined with the microparticle separation technology to develop the portable airborne fungi real-time acquiring and detecting equipment. This equipment improves the complex and extensive collection methods in conventional airborne fungi detection and the demand limitation of independent detection equipment, and realizes the real-time collection and quantification of airborne fungi concentration. Moreover, the equipment has the advantages of small volume, low costs, easy operation and is easy to be prompted.

In accordance with a method for characterization of particles in a fluid-filled hollow structure, an ultrasound signal with a frequency spectrum, which exhibits a local maximum at a variable measurement frequency, is emitted in the direction of a part area of the hollow structure and reflected components are detected. The measurement frequency is tuned in a predetermined measurement interval, and depending on the detected reflected components, a spectral response curve is acquired as a function of the measurement frequency. Depending on the response curve, at least one characteristic property for a part of the particles located in the part area of the hollow structure is determined. The characteristic property includes a measure for an adhesion of the particles of the part of the particles located in the part area of the hollow structure.

Provided are a method and device for dynamically monitoring suspended matter based on an annular interleaving array. An annular multi-band interleaving array used thereby can be combined with the Doppler effect to on-line measure the concentration and linearity distribution of the suspended matter and a three-dimensional flow velocity of suspended water, thus realizing real-time monitoring of water quality. A frequency range needing to be measured is divided into different frequency bands, and different transceiving transducer arrays are used to transmit and receive measurement signals, so that the concentration and linearity distribution of various suspended matter with an extremely large linearity range can be obtained through one measurement.

Devices and methods for using changes in the orientation of micrometer sized dispersed liquid crystal domains to detect or quantify analytes in a test sample, including amphiphilic analytes, are disclosed. The dispersed liquid crystal domains are defined by an interface, and one or more nanoparticles or nanoparticle-containing complexes are adsorbed to the interface. As a result of the adsorption of the nanoparticles or nanoparticle-containing complexes at the interface, the microdomains are stabilized, and resist coalescing for extended periods of time, unlike previously known devices using liquid crystal emulsions for analyte detection.

When the dispersed liquid crystal microdomains are exposed to the test sample, any changes in the orientation of the liquid crystal microdomains (such as from the bipolar to radial) are detected. Such changes in orientation signal the presence of analyte in the test sample, and the proportion of liquid crystal microdomains exhibiting the change in orientation is correlated with the quantity of analyte in the test sample. The nanoparticle used, the amphiphile used in the nanoparticle-containing complex, or both may be selected to optimize the sensitivity and/or selectivity of the device for a given analyte.

A binding capacity evaluation apparatus includes a first solution tank into which a first solution is input, the first solution including a hydrophobic substance and a hydrophilic substance; a second solution tank into which a second solution is input, the second solution including water as a major component; a light irradiation device irradiating light on a third solution including a mixture of the first and second solutions; a light-receiving device receiving light passing through the third solution; and a light transmittance measuring device measuring light transmittance by using an intensity of the light received by the light-receiving device. The apparatus uses the light transmittance to detect when the hydrophobic substance becomes supersaturated in the second solution.

A bio-substance analysis method using a sensing substrate having a fluid channel is disclosed. The method includes mixing retroreflective particles with a detection solution containing a target bio-substance, wherein a first bio-recognition substance selectively reacting with the target bio-substance is modified on the retroreflective particles; placing the sensing substrate so that a bottom is located under a cover in a direction of gravity; injecting the detection solution containing therein the retroreflective particles into a fluid channel and maintaining the solution in the channel for a first time duration; turning the sensing substrate upside down so that the bottom is located above the cover in the direction of gravity and maintaining the sensing substrate in the turned state for a second time duration; irradiating light into the fluid channel through the bottom; and generating and analyzing an image based on light retroreflected from the retroreflective particles.

The present disclosure relates to a method and apparatus for cleaning a 3D printed article, in particular a 3D printed heat exchanger. After 3D printing, an article may have internal passages formed from bonded powder and said passages may contain unbonded powder that needs to be removed before further use of/processing of the article. To remove this unbonded powder, the article is filled with a cleaning fluid and vibrated. The cleaning fluid is then pumped out of the article and past a sensor that generates a magnetic field. The sensor detects the presence of powder particles in the fluid by detecting a perturbation of the magnetic field caused by said particles. The fluid is then filtered and returned to a reservoir for use. The sensor may indicate the article is sufficiently clean when a detected concentration of particles in the fluid drops below a threshold.

Provided is an observation device including: a stereo image-acquisition optical system that acquires images of cells floating in a culture fluid inside a culture vessel; and an analyzer that calculates a cell density of the cells on the basis of the images acquired by the stereo image-acquisition optical system, wherein the analyzer identifies a three-dimensional position of each of the cells included in the images and calculates the cell density on the basis of the number of cells present within a predetermined three-dimensional region.