A system for detecting analytes in a test sample, and a method for processing the same, is provided. The system includes a cartridge reader unit that has a control unit and a pneumatic system, and a cartridge assembly that prepares the samples with mixing material(s) through communication channels. The assembly has a memory chip with parameters for preparing the sample and at least one sensor (GMR sensor) for detecting analytes in the sample. The assembly is pneumatically and electronically mated with the reader unit via a pneumatic interface and an electronic interface such that the parameters may be implemented via the control unit. The pneumatic system is contained within the unit and has pump(s) and valve(s) for selectively applying fluid pressure to the pneumatic interface of the assembly, and thus through the communication channels, to move the sample and mixing material(s) through and to sensor. The control unit activates the pneumatic system to prepare the sample and provide it to the sensor for detecting analytes, and also processes measurements from the sensor to generate test results.

The present invention relates to a sensor assembly (1) for body fluids. The sensor assembly (1) comprises: a measurement chamber (2) extending in an axial direction from an inlet end (3) to an outlet end (4), the measurement chamber having a transverse cross-section with side walls (5, 6) defining a chamber width in a horizontal direction, and with top and bottom walls (8, 7) defining a chamber height in a vertical direction, each of the side walls (5, 6), top wall (8) and bottom wall (7) having a respective wall wettability for aqueous solutions; a first sensor (10a-h) adapted to measure a first parameter of body fluids, the first sensor (10 a-h) having a first sensor surface (11a-h) exposed to the inside of the measurement chamber at a first axial position, the first sensor surface (11a-h) having a first wettability for aqueous solutions; and a second sensor (20) adapted to measure a second parameter of body fluids, the second sensor (20) having a second sensor surface (21) exposed to the inside of the measurement chamber (2) at a second axial position upstream or downstream from the first axial position, the second sensor surface (21) having a second wettability for aqueous solutions higher than the first wettability. At the second axial position, the chamber width exceeds the width of the second sensor surface (21), and the measurement chamber has a widening (22) in a horizontal direction as compared to the first axial position.

The invention is to provide a method of profiling a sample comprising a plurality of cells, the method comprising: flowing cells from the sample through a first array of pillars to obtain one or more distribution profiles of cells sorted by the first array; flowing cells from the sample through a second array of pillars that is different from the first array of pillars to obtain on one or more distribution profiles of cells sorted by the second array; and deriving a biophysical signature of the sample based on at least the one or more distribution profiles of the cells sorted by the first array and/or the one or more distribution profiles of the cells sorted by the second array. The method further comprises determining a health status of a subject based on the biophysical signature of the sample. The invention is also to provide a sample profiling system. In various embodiments, the distribution profile of cells in the output regions is indicative of one or more biophysical properties of the cells, which may include the size and deformability of the cells. The pillars in the first array and the second array may have a shape selected from the group consisting of a substantially L shape and a substantially inverse L shape, mirror reflections thereof or combinations thereof.

A sensor performs measurement of a culture medium and is used in a state of being immersed in a medium placed in a well, the sensor comprising a main body having a first surface and a second surface that is on the opposite side from the first surface; an electrode unit that is provided on the first surface in the main body and to which a specific voltage is applied in the course of performing measurement in a state of being immersed in the medium; and a liquid holding portion that is provided around the electrode unit on the first surface, and that is disposed near the inner wall surface of the well and holds the medium up to above the electrode unit, in between the inner wall surfaces.

The present disclosure refers to a sensor assembly for an IVD analyzer, the sensor comprising two opposite substrates with at least one fluidic conduit for receiving a sample. The electrodes of different types of electrochemical sensors are arranged on the two opposite substrates facing the at least one fluidic conduit for coming in contact with the sample and determining sample parameters, wherein the counter electrodes and the reference electrodes are formed on one substrate and the working electrodes are formed on the opposite substrate. This achieves optimal sensor-working conditions in terms of a homogeneous and symmetrical electric field density and enables a sensor assembly with simpler geometry and smaller size.

The invention relates to an optical method for detecting at least one target molecule (TM) contained in a sample at a determined concentration, which comprises: (a) bringing a sample containing the TM into contact, in a liquid medium, with a solution containing nanoparticles (NPs), the surface of the NPs having been coated or functionalised with at least one type of specific bioreceptor (BR) of the target molecule to be detected (NP-BR), such that the BRs specifically recognise the TM, thus forming conjugates of the NP-BRs with the TMs (NP-BR-TMs); (b) separating the nanoparticles conjugates (NP-BR-TMs and/or NP-BRs) formed in the previous step; (c) bringing the nanoparticles conjugates (NP-BR-TMs and/or NP-BRs) into contact with a sensor surface of an optical transducer that operates by means of reflection and/or transmission, the response of which is based on optical interference, the sensor surface being functionalised by immobilising thereon: (i) the target molecule (TM) or (ii) at least one specific bioreceptor of the target molecule, which may be of the same type (BR) or of another type (BR1); and (d) determining the optical reading on the sensor surface by means of change in the interference response of the optical transducer, caused by change in the real part of the refractive index as a result of the NP conjugates recognised on the sensor surface, and/or by means of change in intensity in the interference response, caused by variation in intensity as a result of dispersion or as a result of variation in the complex part of the refractive index of the NP conjugates, or by means of a combination of both effects amplification in the interference response by refractive index and scattering.

The presence of analytes can be detected in the bodily fluid using Electrochemical Impedance Spectroscopy (EIS) or Electrochemical Capacitance Spectroscopy (ECS) in devices, such as handheld point-of-care devices. The devices, as well as systems and methods, utilize using Electrochemical Impedance Spectroscopy (EIS) or Electrochemical Capacitance Spectroscopy (EIS) in combination with an antibody or other target-capturing molecule on a working electrode. Imaginary impedance or phase shift, as well as background subtraction, also may be utilized.

Cartridges and related systems and methods are disclosed. In accordance with an implementation, a method includes securing a sample container in a sample container receptacle of a cartridge using a sample container lock and coupling the cartridge to a cartridge receptacle of a system. The method also includes depositing a sample from the sample container within a sample well of the cartridge and determining a presence of a target molecule within the sample using the system. In response to the target molecule being present within the sample, the method includes releasing the sample container lock of the cartridge to allow the sample container to be removed from the sample container receptacle and for the cartridge to remain coupled to the system.

A method of assessing a bodily fluid sample on a test strip may involve applying a periodic signal with a first electrode located at a first location in a microfluidic channel of the test strip, monitoring the applied periodic signal with a second electrode located at a second location in the microfluidic channel, and using a third electrode located at a third location in the microfluidic channel as a reference electrode. The method may also include: collecting the bodily fluid sample in the microfluidic channel; continuing to apply the periodic signal, monitor the periodic signal and use the third electrode as a reference electrode while collecting the bodily fluid sample; and determining that the bodily fluid sample is sufficient for analyzing, based at least in part on the applied and monitored periodic signal.

Examples herein provide a device. The device includes a sample delivery component, which includes: a reagent chamber to contain at least one reagent; a sample chamber to contain a fluid sample; and a delivery channel extending from the reagent chamber and in fluid communication with the sample chamber and an output port, wherein the delivery channel is conducive mixing the at least one reagent and the fluid sample to form a mixture before the mixture reaches the output port and be discharged therefrom. The device includes a testing cassette detachable from the delivery component, which includes: an input port in fluid communication with a microfluidic reservoir, the input port to receive the discharged fluid sample from the output port; and a micro-fabricated integrated sensor in a microfluidic channel extending from the microfluidic reservoir.