Provided is a chiller and system that may be utilized in a supercritical fluid chromatography method, wherein a non-polar solvent may replace a portion or all of a polar solvent for the purpose of separating or extracting desired sample molecules from a combined sample/solvent stream. The system may reduce the amount of polar solvent necessary for chromatographic separation and/or extraction of desired samples. The system may incorporate a supercritical fluid chiller, a supercritical fluid pressure-equalizing vessel and a supercritical fluid cyclonic separator. The supercritical fluid chiller allows for efficient and consistent pumping of liquid-phase gases employing off-the-shelf HPLC pumps. The pressure equalizing vessel allows the use of off-the-shelf HPLC column cartridges. The system may further incorporate the use of one or more disposable cartridges containing silica gel or other suitable medium. The system may also utilize an open loop cooling circuit using fluids with a positive Joule-Thomson coefficient.

A device for detecting analytes in a sample includes a main body. The main body includes a plurality of testing units. Each testing unit is configured to detect one or more analytes in the sample. Each testing unit is separable from the main body, or/and the testing units are connected together through the main body. When testing needs to be performed, the testing units are separable from each other, or the testing units are separable from the main body. The testing units are inseparable from the main body after completing the testing and entering the main body again.

Electronic chemical sensors can output raw electrical signal data in response to sensing a chemical compound, but the raw electrical signal data can be difficult to interpret. Processing the electrical signal data with a machine-learned model to generate an embedding output in an embedding space can provide a better understanding of the electrical signal data. Moreover, leveraging preexisting chemical property prediction models to generate other embeddings in the embedding space can allow for more accurate and efficient classification tasks of the electrical signal data.

The present invention is directed to biochemical assay methods, which uses a biotin-immobilized solid support surface for quantitating an analyte or measuring kinetic binding in different samples, from about 3 to 20 times, while maintaining acceptable assay performance. The methods use a streptavidin capture solution comprising streptavidin or preferably streptavidin polymers. The biotin-immobilized solid support surface is regenerated after each cycle of reactions by contacting the surface in an acidic solution having pH about 1-4, followed by DMSO. The regeneration step removes the bound immunocomplex and leaves the biotin on the surface.