The present invention relates to an in vitro method for analysing liquid samples as to the presence, identity and properties of a virus comprising: a) analyzing said liquid samples for a virus spectroscopically by means of spontaneous Raman spectroscopy; and b) comparing the spectroscopic data to a database and identifying said virus. The present invention further relates to an in vitro method for analyzing exosomes in a liquid sample of a subject comprising: a) isolating exosomes from the liquid sample; b) analyzing said exosomes spectroscopically by means of spontaneous Raman spectroscopy; and c) obtaining a Raman spectrum for said exosomes. The present invention also refers to a device for analysing a liquid sample as to the presence, identity and properties of viruses; and to a device for analyzing exosomes in a liquid sample. Also envisaged are a method for monitoring a viral infection in a cell or group of cells and a method of monitoring the antiviral treatment effect in a virus infected cell or group of cells, as well as a system comprising said device and a module comprising a database comprising reference values of Raman spectra.

An apparatus configured to receive particles in a liquid includes: a housing comprising a housing inlet and a housing outlet; and a mesh located in the housing between the housing inlet and the housing outlet, the mesh having spaces greater than a greatest transverse dimension of the particles. The apparatus operates to break up agglomerates of the particles, such as agglomerates of magnetic particles. Other systems and methods of receiving and transferring liquids containing particles having a propensity to agglomerate are disclosed, as are other aspects.

Filtration apparatuses, kits, and methods for rapid isolation of intact, viable mitochondria from tissues are described with mitochondria isolated by differential filtration through nylon mesh filters. Mitochondria can be isolated in less than 30 minutes using the filtration apparatuses, kits, and methods described.

The present invention generally relates to droplet libraries and to systems and methods for the formation of libraries of droplets. The present invention also relates to methods utilizing these droplet libraries in various biological, chemical, or diagnostic assays.

A flow channel structure for removing a foreign substance, including a first flow channel, where the first flow channel has a first region having a depth shallower than a depth of another region. A method for removing a foreign substance in a fluid, including flowing the fluid to the first flow channel of the flow channel structure for removing a foreign substance.

A method and/or system can include processing a blood sample of a patient by degrading red blood cells of the blood sample using a lysing solution, quenching the degradation of the red blood cells after a threshold lysing time, centrifuging and aspirating the quenched solution to remove degraded red blood cell debris and concentrate white blood cells of the blood sample, and suspending the concentrated white blood cells in a buffer solution; within a threshold transfer time, deforming white blood cells, of the suspended white blood cells, within a microfluidic chip; and determining a probability that the patient is in an immune activation state based on images of the white blood cells acquired while deforming the white blood cells.

This present disclosure provides devices, systems, and methods for performing point-of-care analysis of a target analyte in a biological fluid via a binding assay. The present disclosure includes a cartridge for collecting the target analyte contained in a fluid sample and performing an assay. The cartridge includes an assay stack having a first separation layer, a second separation layer, and a detection membrane. The cartridge also includes a plurality of first complexes comprising a capture molecule and a magnetic bead and a plurality of second complexes comprising a detection molecule and a detection label. Further, the detection membrane includes a substrate that interacts with the detection label to elicit a quantifiable response in the presence of the target analyte. The quantifiable response corresponds to an amount of detection antibody present in the detection membrane, and the amount of detection antibody present corresponds to an amount of the target analyte present.

A portable diagnostic device for performing the diagnosis of pathogens, such as viruses, bacteria, microorganisms, etc., by rapidly detecting their nucleic acids in a biological sample to be tested. Also, the use of the portable diagnostic device and the methods for detection of at least one nucleic acid sequence of interest implemented with the aid of the portable diagnostic device.

A device enables a user to detect biomarkers, and includes an element that defines a multiplicity of microfluidic channels that communicate between an inlet duct and an outlet duct, the inlet duct communicating with an inlet port into which a user can introduce a drop of body fluid; the outlet duct communicating with an outlet port. A resilient bladder is connected to the outlet port to provide suction. Each microfluidic channel defines a reaction chamber containing a biomarker-sensitive reagent which provides a color or a change of color in the presence of a biomarker, there being a multiplicity of different biomarker-sensitive reagents, one such biomarker-sensitive reagent being provided in each of the multiplicity of different microfluidic channels. At least part of the element is transparent so the color within the reaction chamber can be seen. The device includes a cover with magnifying lenses above the reaction chambers. The device may be used in conjunction with a smart phone.

A cell evaluation device includes: a porous membrane having a first main face and a second main face; a first passage having a first passage portion facing a first area on which cells are placed in the first main face of the porous membrane; a second passage having a second passage portion facing a second area in the second main face of the porous membrane, the second area being positioned backside of the first area; and a first electrode provided in the first passage portion and a second electrode provided in the second passage portion, the first electrode and the second electrode being positioned across the first area and the second area. In the cell evaluation device, tight junctions are formed among the cells by cell cultivation. With the cell evaluation device, any increase in the electric resistance occurring due to the formation of the tight junctions can be easily measured.