A cartridge has a strip that is provided with the test region and a case in which the strip is accommodated and in which an observation window for observing the test region from an outside is formed in a surface. A emission end portion, through which illumination light for illuminating a test region, is disposed at a position separated from the observation window on a rear surface of the case. A detection unit, that optically detects the color development state of the test region irradiated with the illumination light, is disposed at a position facing the observation window on a surface side of the case. The illumination light is transmitted from the rear surface of the case to an inside of the case, reaches the test region while being diffuse-reflected by an inner surface of the case, and illuminates the test region from the surface side.

Described herein are various embodiments directed to rotor devices, systems, and kits. Embodiments of rotors disclosed herein may be used to characterize one or more analytes of a fluid. An apparatus may include a first layer being substantially transparent. A second layer may be coupled to the first layer. The second layer may be substantially absorbent to infrared radiation. The second layer and the first layer may collectively define a set of wells. The first layer may define a base for each well of the set of wells. The second layer may define an opening for each well of the set of wells. At least one of the first layer and the second layer may define a sidewall for each well of the set of wells.

Embodiments include a reaction vessel having a reaction chamber defined by opposing first and second interior-facing surfaces of the housing; a first light absorbing layer conforming to the first interior-facing surface of the housing component; and a second light absorbing layer conforming to the second interior-facing surface of the housing component; a first energy source configured to direct light through the housing at the first light absorbing layer; and a second energy source configured to direct light through the housing at the second light absorbing layer.

A testing assembly for lateral flow assay comprising a liquid sample receiving unit arranged on a support structure defining a plane and configured to receive a liquid sample via the liquid sample receiving interface, at least one testing strip having, in a planar state, a testing strip center line length (L) in a longitudinal direction, a testing strip width in a width direction and a testing strip thickness, and comprising a capillary wick that includes a test portion that comprises a reacting material configured to react in a predetermined manner to a pre-specified analyte, wherein the width direction of the testing strip extends at an angle smaller than 90° with respect to a normal of the plane, and wherein the testing strip is curved, resulting in an effective extension being shorter than the testing strip center line length in the planar state.

A method for detecting biomarkers with shortened test time and enhanced precision is provided. A sample from the body fluid is made to flow over a sensor surface coated with a capture antibody to allow binding of a biomarker in the sample to the capture body. An optical method detects and counts the individual binding events along the sensor surface with single molecule resolution, and difference in the binding events along the sensor surface is detected in real-time and analyzed to determine the biomarker concentration.

This disclosure pertains to a consumable product (microplate) suitable for use in assays utilizing single-molecule recognition through equilibrium Poisson sampling (SiMREPS) and in other assays employing total internal reflection fluorescence (TIRF) or HiLo microscopy. The disclosed microplate is also suitable for use in other high throughput assay systems, such as single-molecule FRET, ligand-receptor binding studies, membrane biology assays, cell-based TIRF and near-TIRF assays. The disclosure further pertains to the use of the microfluidic microplate for the detection of analytes, including nucleic acids, polypeptides, carbohydrates, lipids, post-translational modifications, amino acids, metabolites, and small molecules.

The present disclosure relates to a flow cell receiver. The flow cell receiver can include at least one platen, having a plurality of ports. The flow cell receiver can include magnets. The flow cell receiver can be configured to automatically align, secure, and retain a flow cell carrier containing a flow cell.

A system for single-use immunochemical tests, comprising a support equipped, along a main direction, with a plurality of housings, including —at least one first housing for the sample to be analyzed, —at least one second housing for substances to be combined with the sample during the test, —at least one third housing for a well carrying a substance to be combined with the sample during the test, characterized in that the surface of said at least one third housing of said support is opaque to light and said well is made of a material at least partially transparent to light, and in that said at least one third housing is —equipped with a through-hole on the bottom, so that a beam of light can pass through said bottom of the third housing and through said well, in order to conduct a colorimetric absorbance test, or —equipped with a closed bottom in order to conduct a luminescence test in the well, —so that said system uses a single type of well at least partly transparent to light to conduct colorimetric absorbance and luminescence tests.

Described herein are various inventions and embodiments thereof, directed to systems, devices, and methods for analysis of a biofluid, as well as controlling a biofluid analysis system using a microfluidic device. Embodiments of biofluid analysis systems disclosed herein may provide analysis of a biofluid to identify and characterize one or more analytes. An apparatus may include a first layer defining a first opening and a second opening. The first layer may be substantially transparent. A second layer may be coupled to the first layer and define a microfluidic channel that establishes a fluid communication path between the first opening and the second opening. At least a portion of the second layer may be substantially opaque.

In an embodiment, the present disclosure pertains to a method of performing circulating tumor cell (CTC) analysis. In general, the method includes flowing a sample through a CTC microfluidic platform, deforming a CTC within the sample, measuring CTC deformation through an imprint of the deformed CTC, processing data related to the measuring, and at least one of identifying or characterizing parameters related to the data that enables at least one of detection of CTCs, enumeration of CTCs in the sample, characterization of biophysical properties, CTC cell size, CTC cell membrane deformability, stresses on CTC cell membranes, adhesion stress on CTC cells, normal stress of CTC cells, or combinations thereof. In some embodiments, the flowing includes passing the sample through at least one channel of the CTC microfluidic platform having a constricted section.