Abstract: The chemical sensing device comprises a substrate of semiconductor material, integrated circuit components and a photodetector formed in the substrate, a dielectric on the substrate, a wiring in the dielectric, and a source of electromagnetic radiation, a waveguide and a fluorescent sensor layer arranged in or above the dielectric. A portion of the waveguide is arranged to allow the electromagnetic radiation emitted by the source of electromagnetic radiation to be coupled into the waveguide. A further portion of the waveguide is arranged between the photodetector and the fluorescent sensor layer.

Abstract: Embodiments of the present disclosure provide for methods of detecting, sensors (e.g., chromogenic sensor), kits, compositions, and the like that related to or use tunable macroporous polymer. In an aspect, tunable macroporous materials as described herein can be used to determine the presence of a certain type(s) and quantity of liquid in a liquid mixture.

Abstract: A method for detecting glutaraldehyde in a water sample in which Au-BSA nanoclusters have been introduced is provided. In the method, the water sample is mixed with the Au-BSA nanoclusters to form a mixture. The mixture is incubated for 2 to 10 minutes, and the glutaraldehyde present in the mixture reacts with the Au-BSA nanoclusters and causes fluorescence quenching of the Au-BSA nanoclusters. Then a fluorescence intensity of the quenched Au-BSA nanoclusters in the mixture is measured at an emission wavelength of 675 nm. A presence and concentration of glutaraldehyde in the water sample is then determined by comparing the measured fluorescence intensity of the quenched Au-BSA nanoclusters at the emission wavelength of 675 nm with fluorescence intensity values of calibration samples comprising Au-BSA nanoclusters and known glutaraldehyde concentrations.

Abstract: The molecule detecting apparatus of an embodiment includes a light source 31, a fluorescent layer 42 emitting different fluorescence depending on the kind of a target molecule 60 captured when being irradiated with light from the light source 31, a photodetector 32 configured to detect fluorescence, and the photodetector 32 is an array of avalanche photodiodes operating in Geiger mode.

Abstract: The invention relates to a method for detecting an analyte present in a liquid specimen, including: injecting the liquid specimen into a detection chamber, the detection chamber having a non-zero volume enclosing polymeric beads covered with a reagent suitable for the analyte to be detected; capturing at least one image of at least one region of the detection chamber using a sensor; processing the image acquired by the sensor, which includes determining a texture level of the acquired image; and determining a concentration of the analyte depending on the texture level determined for the image.

Abstract: A sensor element is used to collect environment information on a surface of the earth or a surface layer of the earth by being scattered in a target region where the environment information is collected. At least one of reflection properties, transmission properties, absorption properties, or luminescence properties with respective to an electromagnetic wave with a specific wavelength, or light emitting properties changes in accordance with an environment.

Abstract: The present invention provides a fluorescent polymer comprising a fluorophore perylene bisimide (PBI) and oligo (p-phenylene vinylene) (OPV) functionalized with carboxy and amine functionality groups and a polystyrene (PS) backbone for the detection of volatile organic compound, a process for the detection and a kit thereof.

Abstract: A gasket sandwiched between a flow cell and a joint member has, in a main flat surface, an inlet communication hole for communicating between an inlet hole of the flow cell and an inlet flow path of the joint member and an outlet communication hole for communicating between an outlet hole of the flow cell and an outlet flow path of the joint member. Furthermore, a deformation absorbing structure for absorbing deformation of the gasket is provided between the inlet communication hole and the outlet communication hole in the main flat surface of the gasket.

Abstract: A microfluidic assay system including a microfluidic cartridge and an associated microfluidic operator system. The microfluidic cartridge comprises a base part, having a first face with a recess and a foil fixed to the base part for covering the recess and providing a microfluidic cartridge foil face. The base part with the recess and the foil forms a flow channel and a sink in fluid communication with each other. The microfluidic cartridge comprises an inlet opening into the flow channel upstream to the reaction section.

Abstract: Provided are methods for imaging a biospecimen, which involves the use of electrochemical pH modulation in combination with pH-sensitive labels to achieve localized imaging with a high vertical axial resolution.

Abstract: A sensor system includes a sensor and an optical source. The sensor has a receptor configured to bind to a chemical species. A spacer is bound to the receptor, and a fluorophore is bound to the spacer. The optical source is configured to irradiate the sensor to dissociate the chemical species from the receptor. The optical source can be infrared light, microwave or radio wave. The sensor system optionally includes a photodetector configured to determine an amount of the chemical species by measuring fluorescence when the optical source irradiates the sensor.

Abstract: A microfluidic device system includes a channel having an entrance and an exit, a height at the entrance being greater than a height at the exit. The height of the channel may decrease continuously from the height at the entrance to the height at the exit. Cells or particles or beads traveling through the channel become trapped based on their size and/or deformability. A visual sensor captures images of the trapped cells or particles or beads, and image software analyzes the captured images to provide size and/or deformability and/or fluorescence information. A method of fabricating such a microfluidic device includes introducing a glass wafer to an etching solution at a specific rate such that a first end of the glass wafer is etched longer than other portions of the glass wafer.

Abstract: This disclosure relates to a sensor that detects bacteria cells comprising (a) a primary negatively charged, nanoparticulate sensing material; (b) a secondary positively charged, fluorescent sensing material; (c) a housing; and (d) at least one illuminator. This disclosure further relates to a method for detecting bacteria cells.

Abstract: Among others, the present invention provides apparatus for detecting a disease, comprising a system delivery biological subject and a probing and detecting device, wherein the probing and detecting device includes a first micro-device and a first substrate supporting the first micro-device, the first micro-device contacts a biologic material to be detected and is capable of measuring at the microscopic level an electric, magnetic, electromagnetic, thermal, optical, acoustical, biological, chemical, physical, or mechanical property of the biologic material.

Abstract: By irradiating a sensor chip including an analyte labeled with a fluorescent substance with excitation light from an excitation light irradiation unit for emitting the excitation light using a specimen detector including the excitation light irradiation unit and a fluorescence detection unit for detecting fluorescence, fluorescence emitted from the fluorescent substance is detected by the fluorescence detection unit. When the analyte is detected on the basis of a detection value depending on the intensity of the detected fluorescence, a corrected detection value is calculated by correcting the detection value using individual difference information acquired in advance on the basis of an individual difference between the specimen detectors and a correction coefficient for each sensor chip.

Abstract: Provided are a quality control method, a quality control system, a management apparatus, an analyzer, and a quality control abnormality determination method in which measurement results of both a quality control substance and a specimen are sufficiently utilized to improve the quality of quality control. The quality control method used in a management apparatus which is connected via a network to an analyzer installed in each of a plurality of facilities includes obtaining, from an analyzer in each facility via a network, first quality control information obtained by measuring an artificially generated quality control substance, and second quality control information obtained by measuring a plurality of specimens by the analyzer in each facility; and outputting information concerning quality control of an analyzer in at least one facility, based on the obtained first quality control information and second quality control information.

Abstract: A method for the detection of adulterated gasoline in a sample is disclosed. The method includes contacting a sample with an immobilized molecular probe, the immobilized molecular probe having a photoluminescence which is environmentally sensitive; collecting the photoluminescence from the immobilized molecular probe; and determining whether the photoluminescence is indicative of adulterated gasoline. A test strip for the detection of adulterated gasoline in a sample is also disclosed, including an immobilized molecular probe embedded in a substrate and/or immobilized to the substrate, the immobilized molecular probe having photoluminescence which is environmentally sensitive to adulterated gasoline. The method and test strips are designed to be robust, portable, and within the capabilities of untrained personnel.

Abstract: A microfluidic component package that is readily integratable within a microfluidic system.

Abstract: A system, method, and apparatus for sensing analytes comprises assembling a sensor of at least one polymer and at least one fluorophore by mixing the polymer with the fluorophore, exposing the sensor to an analyte, and identifying the presence of the analyte according to a change in fluorescence of the sensor. The sensor can comprise a non-covalent complex of the at least one fluorophore and the at least one polymer. The at least one polymer can comprise a polymer capable of binding a metal ion. The at least one polymer is capable of binding a metal ion comprising an imidazole-containing polymer such as an N-vinylimidazole homo polymer and/or an N-vinylimidazole co-polymer.

Abstract: According to one embodiment of the present application, a biosensor, the biosensor comprising: a reaction part including a magnetic nanoparticle complex, a first electrode, and a second electrode; and a sample introduction part forming a passage so that a sample can be introduced into the reaction part from an outside of the biosensor; wherein the magnetic nanoparticle complex includes a first capturing substance for capturing a first target substance, a magnetic nanoparticle, and a reaction substance that performs at least one of an oxidation reaction and a reduction reaction, wherein the magnetic nanoparticle complex has is magnetic in the reaction part, and has a property that mobility can be changed according to a change in a condition of the reaction part, wherein the first electrode, a second capturing substance for capturing a second target substance is fixed, wherein the second electrode is an electrode different from the first electrode, and characterized in that at least one of the first target subs