A gas concentration monitoring system (100) is provided. The system (100) includes a radiation source (104) having one or more emitting elements and a radiation sensor (106) having one or more sensing elements configured to detect radiation received at the radiation sensor (106). A reactive material (108) is located between the radiation source (104) and the radiation sensor (106) and is configured to react to the presence of a gas such as carbon dioxide, wherein the reaction of the reactive material (108) impacts an amount of radiation detected at the radiation sensor (106).

The invention relates to a testing system and related methods for detecting peritonitis or infection in peritoneal dialysate removed from a patient. The testing system can include a fluid sensor apparatus in a fluid line of a peritoneal dialysis cycler through which spent peritoneal dialysate can be pumped. The fluid sensor apparatus can detect one or more markers associated with peritonitis or infection.

A component or device is provided for the detection or the measurement in parallel of one or more specific types of biological or chemical target products. This component includes a group of nanotubes selected and/or functionalized to interact with the target product, around an optical waveguide. Thus, an optical coupling is produced between the optical waveguide and one or more optical characteristics of these nanotubes, the modifications of which are evaluated in the presence of the target product. In addition, a method is provided for manufacturing and preparing such a component or device, and a detection method using them, as well as a post-manufacture preparation method comprising a specific functionalization for different target products starting from the same type of pluripotent generic component. Also provided is a family of PFO-based functionalization polymers.

Recent progress related to energy harvesting solutions and printed electronics is opening the opportunity for a smart label to combine chemical/physical color change technology with an electronic based reader architecture, which can be achieved with printed electronics technologies and can be suitable for monitoring applications that are very cost sensitive. The smart label provides an innovative product architecture to achieve a very low cost solution to monitor packaged items during storage and shipment. Exemplary applications of the smart label include, but are not limited to, cold chain monitoring, food monitoring, and in-package control of sensitive devices, such as electronic components.

A method of tagged-base DNA sequencing readout on waveguide surfaces includes immobilizing, a surface of a waveguide, a nucleotide fragment, exposing the nucleotide fragment to a first plurality of capped nucleotides, wherein the first plurality of capped nucleotides include a first plurality of nucleotide types, each distinct nucleotide type has a distinct capping agent, and each distinct capping agent has a distinct optical signature, severing base pair connections between the at least a nucleotide fragment and the first plurality of capped nucleotides, wherein the nucleotide fragment remains attached and a first single nucleotide, of the first plurality of capped nucleotides, remains immobilized on a nucleotide binding locus adjacent to the first nucleotide sequence, and detecting a first distinct optical signature of a first distinct capping agent of the first single nucleotide using the waveguide.

A blood coagulation analyzer comprises: a light irradiation unit configured to apply light onto a container configured to store a measurement specimen containing a sample and a reagent, and comprising: light sources including a first light source configured to generate light of a first wavelength for blood coagulation time measurement, a second light source configured to generate light of a second wavelength for synthetic substrate measurement, and a third light source configured to generate light of a third wavelength for immunonephelometry measurement; and optical fiber parts facing the respective light sources; a light reception part configured to receive light transmitted through the container; and an analysis unit configured to analyze the sample using an electric signal outputted from the light reception part.

The present invention relates to a compound for detecting phosgene and DCP (diethyl chlorophosphate) and a composition for detecting phosgene and DCP (diethyl chlorophosphate) comprising the said compound. More precisely, the compound for detecting phosgene and DCP of the present invention can selectively detect phosgene and DCP either in the liquid phase of gas phase by detecting the changes of fluorescence and color development very quickly within a few seconds with nM sensitivity. Therefore, the compound can also be effectively used as an ingredient for the composition and kit for the detection of one or more materials selected from the group consisting of phosgene and DCP.

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.

The present document describes a method for the detection of off-flavor maple syrup made from buddy maple sap or maple sap contaminated with buddy maple sap, or off-flavor maple sap comprising measuring a spectrophotometric property of a nanoparticle reactive with a buddy maple sample having a size of from about 1 nm to about 250 nm contacting a maple sample. A change in the spectrophotometric property is associated with an off-flavor maple syrup or maple sap sample, and no change in the spectrophotometric property is associated with a good flavor maple syrup or maple sap sample.

Disclosed herein are systems and methods for measuring one or more target analyte concentrations, particularly peroxyacid compounds, in a process solution, for example, in industrial and commercial water. These systems and methods include automated methods to measure the target analyte concentration in the process solution. The methods have the advantage of providing a large dynamic range for measurement and can be used in a wider range of process solutions.