A sensor structure is disclosed comprising at least four planar layers subsuming at least one cavity housed but not contained by overlapping apertures through at least two of the planar layers, wherein the at least one cavity comprises a plurality of chambers, and wherein at least one chamber of the plurality of chambers is configured to be in fluid coupling with at least one other chamber. The plurality of chambers may be defined by overlapping apertures through a plurality of the planar layers. The plurality of chambers may include a Gas Chromatograph (GC) column. The planar layers may be flexible flat glass. The planar layers may be fused together. The layers may be made with apertures through the layers disposed in a desired pattern to define complex structures by the apertures overlapping between abutting layers when the layers are stacked. The planar layers may be configured to admit ultraviolet light.

A method for reducing the variability, as measured by relative standard deviation (RSD), of an analytical testing technique is provided. This improvement in RSD improves the confidence in the values obtained during field testing. The method includes incorporating a focusing agent into the sampling media, which permits providing sampling media such as thermal desorption tubes preloaded with the focusing agent.

A hand-held microfluidic testing device is provided that includes a housing having a cartridge receiving port, a cartridge for input to the cartridge receiving port having a sample input and a channel, where the channel includes a mixture of Raman-scattering nanoparticles and a calibration solution, where the calibration solution includes chemical compounds capable of interacting with a sample under test input to the cartridge and the Raman-scattering nanoparticles, and an optical detection system in the housing, where the optical detection system is capable of providing an illuminated electric field, where the illuminating electric field is capable of being used for Raman spectroscopy with the Raman-scattering nanoparticles and the calibration solution to analyze the sample under test input to the cartridge.

Apparatuses and associated methods are described for the efficient evaluation of C1-containing substrates, and especially for such evaluation conducted locally, or on-site, at a prospective facility for implementation of a biological conversion process for desired end product using a C1 carbon source. The exact composition of a given, industrial C1-containing substrate, as well as the range in composition fluctuations, are generally difficult to reproduce at a remote facility (e.g., a laboratory or a pilot-scale or demonstration-scale process), as required for the accurate prediction/modeling of commercial performance to justify large capital expenditures for commercial scale-up.

The devices, systems, and methods described herein generally relate to chemical profiling of an occupant in a vehicle. The devices, systems and methods described herein can detect enclosure-related chemicals, the enclosure-related chemicals including biochemicals expelled by one or more occupants. The enclosure-related chemicals can then be associated to an associated occupant of the one or more occupants. A biological profile can then be created for the associated occupant, the biological profile comprising medical information and historical information related to the enclosure-related chemicals.

A method for reducing the variability, as measured by relative standard deviation (RSD), of an analytical testing technique is provided. This improvement in RSD improves the confidence in the values obtained during field testing. The method includes incorporating a focusing agent into the sampling media, which permits providing sampling media such as thermal desorption tubes preloaded with the focusing agent.

Systems, methods and computer program products for cannabis analysis, such as a system that has a cannabis analysis data server and a plurality of mobile cannabis analysis devices that are communicatively coupled to a network. The mobile devices perform physical analyses of a physical sample and communicate resulting data to the cannabis analysis data server with a unique identifier. The mobile cannabis analysis devices may also monitor device and external environmental conditions that affect the performance and communicate these to the cannabis analysis data server. The cannabis analysis data server performs analyses on the received data from the mobile devices. Based on the sample analyses, the cannabis analysis data server generates sample analysis reports and communicates them to a user. The cannabis analysis data server may also generate data to control the operation of the mobile cannabis analysis devices based on the operation and environmental data received from the devices.

A sensor structure is disclosed comprising at least four planar layers subsuming at least one cavity housed but not contained by overlapping apertures through at least two of the planar layers, wherein the at least one cavity comprises a plurality of chambers, and wherein at least one chamber of the plurality of chambers is configured to be in fluid coupling with at least one other chamber. The plurality of chambers may be defined by overlapping apertures through a plurality of the planar layers. The plurality of chambers may include a Gas Chromatograph (GC) column. The planar layers may be flexible flat glass. The planar layers may be fused together. The layers may be made with apertures through the layers disposed in a desired pattern to define complex structures by the apertures overlapping between abutting layers when the layers are stacked. The planar layers may be configured to admit ultraviolet light.

A gas analysis device suited for e.g. medical analysis of exhaled breath from a subject. A gas inlet receives a gas sample to a flow path for guiding the gas sample to two or more gas separators, e.g. gas chromatography columns, with respective molecule selectivity properties which are different. One or more detectors, each with a sensor, are arranged to generate respective responses to outputs from the two or more gas separators. A communication module generate output data in response to the respective responses from the one or more detectors, e.g. data indicative of selected molecules in the gas sample, e.g. data indicative of one or more diseases identified as a result of identified biomarkers in the gas sample. The device is suitable as a compact device, e.g. a handheld breath analysis device, since the use of a plurality of gas separators allows use of very molecule specific gas separators which can be implemented with a small size. E.g. a flow path with several parallel paths each comprising one or more gas separator may be used.

A method of monitoring catalytic performance of a catalyst used in a reforming process, comprising a) collecting gaseous component data from the reforming process; b) calculating a gaseous component ratio from the gaseous component data; and c) utilizing the gaseous component ratio to estimate an amount of catalytic activity remaining in the catalyst used in the reforming process, a number of days on stream remaining for the catalyst used in the reforming process, or both.