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.

A detection chip is disclosed. The detection chip includes a sample injection structure, a filter structure, and a reaction structure which are sequentially connected. The filter structure includes a first main body, and a first inlet portion and a first outlet portion respectively on two sides of the first main body. A width of the first inlet portion gradually decreases in a direction away from the first main body, and a width of the first outlet portion gradually decreases in a direction away from the first main body.

Provided herein are systems, devices and methods for performing multianalyte detection in a biological sample, such as a human blood sample. Multiwell plates useful for performing multianalyte detection are also provided. The systems, devices and methods provided herein relate to the field of direct-to-consumer diagnostics (DTC diagnostics) and are useful, e.g., for facilitating consumer access to consumer healthcare and consumer wellness information. Other uses of the systems, devices and methods provided herein relate to the fields of medical research and drug discovery.

A system configured to determine the load in a liquid sample of predetermined antigens is provided. The system comprises a measurement chamber configured for receipt therein of the liquid sample, a sensor circuit, and an analysis unit. The sensor circuit comprises a plurality of working electrodes, each comprising antibodies on its surface associated with one of the predetermined antigens, at least one reference electrode, and at least one counter electrode. Proximal ends of the electrodes are disposed on a reading zone of the sensor circuit, the reading zone being disposed within the measurement chamber. The analysis unit is configured to facilitate the determination of the load of each of the antigens by measuring electrical properties of the electrodes.

A filter insert, a sample vial incorporating a filter insert, a method of using a sample vial containing a filter insert for chemical analysis, and a sample vial kit including a filter insert. The filter insert includes a cylindrical body having a proximal end, a protrusion extending radially from the proximal end of the cylindrical body and configured to set on the open end of a sample vial, a distal end, a cavity extending longitudinally through the cylindrical body from the proximal end to the distal end, and a filter assembly coupled with the distal end of the cylindrical body.

A mesoscale fluidic system comprises a substrate having a sample chamber and an analysis chamber. The sample chamber comprises a cell permeable filter defining a sample application compartment and a conditioning medium compartment. The sample chamber has a sample inlet port in the sample application compartment. The analysis chamber has an entry port and an exit port. The conditioning medium compartment is in fluid communication with the entry port of the analysis chamber via a channel. The sample application compartment is below the cell permeable filter and the conditioning medium compartment is above the cell permeable filter. The mesoscale fluidic system is suited for analysing cellular motility in a sample. Also disclosed is a method of estimating the quantity of motile cells in a sample and a method of extracting motile cells from non-motile cells.

A point of use analyzer includes pump, valve, port, and storage channel. The storage channel may hold multiple assay packets composed of reagent aliquots separated by bounding slugs. The storage channel may define an elongated lumen having two ends with each of the ends coupled to the valve. A sampling device for use with the analyzer engages the port and may include a recurrent coaxial tube having a separation medium. A method of using the analyzer with the sampling device includes steps of pumping a fluid to displace a sample into the separation medium and out through the opposed connection.

A column-based device and method for retrieving cells of interest were enclosed. The said device comprises a column comprising (i) an inner wall defining an inner chamber with inlet and outlet openings, (ii) a perforated plug disposed adjacent to the outlet opening, (iii) a sleeve insert with a channel and disposed within the chamber and adjacent to the perforated plug, and (iv) a filtering means housed within sleeve insert sandwiched between two sealing means. In particular, Tumor-derived endothelial cell clusters (TECCs) as characterized multiple nuclei, expression of endothelial markers (PECAM1, VWF and CDH5), and non-expression of leukocyte, megakaryocyte and platelets markers, may be retrieved using the disclosed device. Also encompassed are methods, reagents and kits for the diagnosis and prognosis of cancers by detecting for the presence of TECCs isolated from blood samples using the claimed device.

The present invention provides point-of-need diagnostic devices and kits for detecting a target nucleic acid sequence in a sample. Methods of using the point-of-need diagnostic devices or the kits disclosed are also provided.

A pipette tip according to certain embodiments includes a proximal end, a distal end, and a reagent chamber. The proximal end is dimensioned to fit on an end of a pipettor, and includes a proximal end opening. The distal end includes a distal end opening. The reagent chamber has a reagent composition disposed therein. The reagent chamber is defined at least in part by a proximal barrier and a distal barrier. The reagent composition is operable to pass through the distal end opening upon rupturing of the distal barrier.