A method of evaluating an asphaltene inhibitor includes providing a centrifugal microfluidic system including: a disc mounted to rotate about an axis; a microfluidic device mounted on the disc, the device having sample, solvent, inhibitor, and precipitant reservoirs and an analysis chamber in fluid communication with the sample, solvent, inhibitor, and precipitant reservoirs; and an optical detection system coupled to the analysis chamber and configured to measure the optical transmission of fluid in the analysis chamber. The method includes filling the sample, solvent, inhibitor, and precipitant reservoirs, respectively, with a sample, solvent, inhibitor, and precipitant; rotating the disc to generate centrifugal force to cause the sample, solvent, inhibitor, and precipitant to travel radially outward to the analysis chamber; and measuring the optical transmission of a mixture of the sample, solvent, inhibitor, and precipitant in the analysis chamber as a function of radial distance of the analysis chamber.

An apparatus for performing a thermocyclic process, such as amplifying DNA, includes a microfluidic chip with a channel formed therein and one or more thermal distribution elements disposed over portions of the chip. Each thermal distribution element is configured to distribute thermal energy from an external thermal energy source substantially uniformly over the portion of the chip covered by the thermal distribution element. The portion of the chip covered by the thermal distribution element thereby comprises a discrete temperature zone. Other temperature zones can be defined by other thermal distribution elements or by portions of the chip not covered by a thermal distribution element. The channel is configured so that a fluid flowing through the channel would enter and exit the different temperature zones a plurality of times, thereby alternately exposing the fluid to the temperature of each zone for a period of time required for the fluid to traverse the zone.

A gene analyzer has a structure in which a metal block, a heater installed on an outer surface of the metal block, and a heat insulator applied onto an outer surface of the heater are integrally formed, thereby miniaturizing the gene analyzer. Further, parts for light measurement, such as a light source element, a light-receiving element, a light source filter, a fluorescent filter, a light source lens, a fluorescent lens, and the like, are installed in a heat insulator light source path and a heat insulator fluorescent path formed in the heat insulator, and the paths formed in the heat insulator are aligned with a block light source path and a block fluorescent path of the metal block.

A fluid analyzer includes an optical source and detector defining a beam path of an optical beam, and a fluid flow cell on the beam path defining an interrogation region in a fluid channel in which the optical beam interacts with fluids. One or more flow-control devices conduct a particle in a fluid through the fluid channel. A motion system moves the interrogation region relative to the fluid channel in response to a motion signal, and a controller (1) generates the motion signal having a time-varying characteristic, (2) samples an output signal from the optical detector at respective intervals of the motion signal during which the interrogation region contains and does not contain the particle, and (3) determines from output signal samples a measurement value indicative of an optically measured characteristic of the particle.

Disclosed herein is an apparatus comprising: a probe carrier, an optical system and a sensor; wherein the probe carrier comprises a substrate, a first layer and a second layer; wherein the substrate comprises a first surface, a second surface, one or more locations on the first surface configured to be deposit sites for one or more probes; wherein the second surface is at an opposite side of the substrate from the first surface; wherein the first layer is on the first surface of the substrate or is embedded in the substrate under the first surface; wherein the second layer is on the second surface of the substrate or is embedded in the substrate under the second surface; the first and second layers are configured to reduce crosstalk between probes at different locations.

A device for monitoring the spatial and temporal dynamics of thrombin that includes a temperature-controlled sealed chamber with a transparent window and a light trap, the chamber being filled with a fluid medium and designed to accommodate a cuvette containing a test sample of blood plasma, and a coagulation activating insert placed into the cuvette, at least one illumination source and at least one first irradiation source and at least one second irradiation source capable of exciting a fluorescence signal of a special marker that forms in the sample during cleavage of a fluorogenic substrate, a camera, a pressure adjustment element capable of maintaining a pressure inside the chamber, the at least one first irradiation source provides irradiation of the sample in a direction perpendicular to the cuvette, and the at least one second irradiation source provides irradiation of the sample at an angle to the cuvette.

Provided are methods, devices and systems that utilize free-surface fluidics and SERS for analyte detection with high sensitivity and specificity. The molecules can be airborne agents, including but not limited to explosives, narcotics, hazardous chemicals, or other chemical species. The free-surface fluidic architecture is created using an open microchannel, and exhibits a large surface to volume ratio. The free-surface fluidic interface can filter interferent molecules, while concentrating airborne analyte molecules. The microchannel flow enables controlled aggregation of SERS-active probe particles in the flow, thereby enhancing the detector's sensitivity.

The present invention discloses a multi-channel aerosol scattering absorption measuring instrument, comprising a light path device, a detection device and a gas path device. The light path device supplies three different wavelengths of laser entering the detection device in sequence; the detection device is provided with photoelectric detectors at multiple angles for measurement, so as to reduce the measurement error of aerosol scattering coefficient; the gas path device comprises a sample loading unit, a calibration unit and a sample discharging unit; and a light source from the light path device and a gas flow from the gas path device enter the photoacoustic cavity of the detection device respectively and are detected by a control unit. The aerosol scattering absorption measuring instrument of the present invention is characterized by multi-channel, multi-angular, full-scale and direct measurement of scattering phase function and absorption coefficient of aerosol particles, combines the function of synchronously acquiring the optical parameters of an aerosol (such as scattering coefficient, extinction coefficient, visibility, transmittance, single scattering albedo, etc.), and achieves the integrated on-line detection of different optical parameters of an aerosol with high automation degree and good stability.

To effectively concentrate particles in a detection area serving as the measurement center of a sensor. A particle sensor is provided with an enclosure; a detection area inside the enclosure, and a guide path in the enclosure, configured to guide a gas to a detection area. The cross-sectional perimeter in a direction perpendicular to the extending direction of the guide path gradually becomes smaller from an inlet to the guide path toward the detection area.

A method and an arrangement are disclosed in connection with a measurement arrangement of optical parameters of a separate sample taken from a process liquid, in which method a sample is taken from the process liquid. The sample can be arranged into a sample vessel provided with at least one measurement window, and optical parameters of the sample in the sample vessel are measured through the measurement window. In the sample in the sample vessel, a flow is produced which can be used to mitigate (e.g., prevent) the measurement window surface in contact with the sample from getting dirty. A back-and-forth flow can be produced in the sample residing in the sample vessel by means of pressure variation focused on the sample, and the back-and-forth flow can be focused on the surface of the optical measurement window.