The system includes a tensioned metastable fluid detector apparatus, a mixing chamber, and a processor. The processor is communicatively coupled to the tensioned metastable fluid detector apparatus. The processor executes steps to form an isotope detection rate versus negative pressure response curve and to determine the isotopic ratio. The mixing chamber is selectively coupled to the tensioned metastable fluid detector apparatus. The mixing chamber is configured to prepare a sample for tensioned metastable fluid detector analysis.

The disclosure provides a method for preparing exosomes using: (i) a step for ultrafiltering a sample containing at least one exosome; and (ii) a step for subjecting the sample that can be obtained from step (i) to anion exchange column chromatography.

The present invention relates to vitro method for analysing a liquid sample as to the presence, identity and properties of microbes comprising: a) isolating microbes from the liquid sample; b) analysing said microbes spectroscopically by means of spontaneous Raman spectroscopy; and c) determining antibiotic susceptibility of said microbes spectroscopically by means of spontaneous Raman spectroscopy. The present invention also refers to device for analysing a liquid sample as to the presence, identity and properties of microbes, wherein the device comprises as a first unit (i) a chip comprising a filtering unit and an antibiotics exposure unit capable of determining the susceptibility of microbes to an antibiotic; as a second unit (ii) a Raman spectroscopy system; and as a third unit (iii) an evaluation module which is coupled to the Raman spectroscopy system.

In a pretreatment method, in first step, a sample is dissolved in 1,1,1,3,3,3-hexafluoro-2-propanol to prepare a first solution. In second step, an organic base is added to the first solution to prepare a second solution. In third step, the second solution is heated to obtain a substance in which an anhydrous oxide structure in the sample has been decomposed. In a fourth step, an organic solvent that has a higher boiling point than that of 1,1,1,3,3,3-hexafluoro-2-propanol and is compatible (miscible) with 1,1,1,3,3,3-hexafluoro-2-propanol is added to the second solution to prepare a third solution.

A nanostructure for isolating or concentrating extracellular vesicles or a pathogen, includes a transferrin family protein linked on magnetic nanoparticles. The nanostructure includes a transferrin family protein, and thus has selectivity for a pathogen or extracellular vesicles capable of binding to the transferrin family protein, and the synthesized nanostructure is positively (+) charged. The nanostructure includes magnetic nanoparticles, a target material is easily and simply isolated from other materials by magnetism when a magnetic field is applied.

A dielectrophoretic detection device including a chip, with a flow channel having at least one inlet and one outlet, and at least a detection area configured to detect analytes trapped on functionalised beads flowing within the flow channel, first and second electrode assemblies shaped as rows of parallel pillars extending a the height of the flow channel, and configured to generate under electric tension an electric field to form an electrical barrier, and preventing the beads to cross the barrier and drawing the beads to the detection area by dielectrophoretic forces where they are clustered and concentrated. The device may be provided with multiple rows of parallel pillars of electrode assemblies extending over the height of the flow channel, forming multiple concentration lines. The flow channel may be provided with further rows of parallel pillars of electrode assemblies crossing the flow channel in a transverse direction, forming further incubation lines.

A dielectrophoretic detection device including a chip, with a flow channel having at least one inlet and one outlet, and at least a detection area configured to detect analytes trapped on functionalised beads flowing within the flow channel, first and second electrode assemblies shaped as rows of parallel pillars extending a the height of the flow channel, and configured to generate under electric tension an electric field to form an electrical barrier, and preventing the beads to cross the barrier and drawing the beads to the detection area by dielectrophoretic forces where they are clustered and concentrated. The device may be provided with multiple rows of parallel pillars of electrode assemblies extending over the height of the flow channel, forming multiple concentration lines. The flow channel may be provided with further rows of parallel pillars of electrode assemblies crossing the flow channel in a transverse direction, forming further incubation lines.

A gas monitor configured to monitor at least one target gas in an environmental mixture, by separating and concentrating the target gas and then adjusting for the concentration factor. The adjustment may also take into account sensor sensitivities to other gases. Methods for adjustment of target gas results and increasing accuracy of monitoring are described.

There are provided a sample solution concentration method that makes it possible to obtain a sample solution concentrated solution having a desired concentration fold ratio and a sample solution examination method using the sample solution concentration method. The sample solution concentration method includes, in the following order, a sample solution injection step of injecting a sample solution, which is an aqueous solution containing a high-molecular-weight molecule, into a cylinder accommodating a particulate super absorbent polymer, a water absorption step in which water contained in the sample solution injected into the cylinder is absorbed by the super absorbent polymer accommodated in the cylinder to generate a sample solution concentrate which is a concentrate of the sample solution, in the cylinder, a liquid addition step of adding a liquid having an amount smaller than an amount of the sample solution injected into the cylinder in the sample solution injection step, to the sample solution concentrate, and a taking-out step of inserting, into the cylinder, a piston insertable into the cylinder, the piston including a tip part having holes smaller than a particle diameter of the super absorbent polymer after water absorption, to take out a sample solution concentrated solution, which is a concentrated solution of the sample solution, through the holes in the tip part of the piston.

There are provided a concentration device for concentrating a sample solution, which makes it possible to obtain a sample solution concentrated solution having a desired concentration fold ratio, a sample solution concentration method using the concentration device, a sample solution concentration method using the sample solution examination method, and an examination kit including the concentration device. The concentration device is a concentration device for concentrating a sample solution which is an aqueous solution containing a high-molecular-weight molecule, the concentration device including a cylinder that accommodates a particulate super absorbent polymer and a piston that is insertable into the cylinder, where the cylinder has, at a bottom part, a liquid holding part for holding a part of the sample solution injected into the cylinder, the super absorbent polymer is accommodated in the cylinder to be in contact with the liquid holding part on the liquid holding part, and the piston includes the tip part having holes smaller than the particle diameter of the super absorbent polymer after water absorption.