The present invention provides self-contained systems for performing an assay for determining a chemical state, the system including a stationary cartridge for performing the assay therein, at least one reagent adapted to react with a sample; and at least one reporter functionality adapted to report a reaction of the at least one reagent with said sample to report a result of the assay, wherein the at least one reagent, the sample and the at least one reporter functionality are contained within the cartridge.

An integrated semiconductor device for manipulating and processing bio-entity samples and methods are described. The device includes a lower substrate, at least one optical signal conduit disposed on the lower substrate, at least one cap bonding pad disposed on the lower substrate, a cap configured to form a capped area, and disposed on the at least one cap bonding pad, a fluidic channel, wherein a first side of the fluidic channel is formed on the lower substrate and a second side of the fluidic channel is formed on the cap, a photosensor array coupled to sensor control circuitry, and logic circuitry coupled to the fluidic control circuitry, and the sensor control circuitry.

A coating composition includes: (i) a film-forming resin; (ii) an infrared reflective pigment; and (iii) an infrared fluorescent pigment or dye different from the infrared reflective pigment. A multi-layer coating including the coating composition, and a substrate at least partially coated with the coating composition is also disclosed. A method of detecting an article at least partially coated with the coating composition is also disclosed.

A method for sample analysis that employs a signal-amplifying nanosensor is provided. An implementation of the present method may include a) obtaining a sample, b) applying the sample to a signal-amplifying nanosensor containing a capture agent that binds to an analyte of interest, under conditions suitable for binding of the analyte in a sample to the capture agent, c) washing the signal-amplifying nanosensor, and d) reading the signal-amplifying nanosensor, thereby obtaining a measurement of the amount of the analyte in the sample. In some embodiments, the analyte may be a biomarker, an environmental marker, or a foodstuff marker. Also provided herein are kits that find use in performing the present method.

Multiplexed fluorescent imaging which is essential for finding out how various biomolecules are spatially distributed in cells or tissues is disclosed. The present disclosure may obtain 10 or more different biomolecule images with one labeling and imaging by newly designing selection of fluorophores, detection spectral ranges, and signal unmixing algorithm. The present disclosure is a blind unmixing technology for unmixing an image without an emission spectrum of fluorophore, and in this technology, 4 pairs of fluorophores are used, and each pair consists of two fluorophores in which emission spectra are overlapped. Each pair of fluorophores is strongly excited by only one excitation laser. Two images with different detection spectral ranges are obtained for each pair, and two images are unmixed via mutual information minimization without fluorophore emission spectrum information. Two images also may be unmixed via Gram-Schmidt orthogonalization and fluorescence measurement based unmixing. This signal unmixing is repeated for each pair of fluorophores. Furthermore, a total of 10 or more fluorophores may be simultaneously used by adding two large stoke's shift fluorophores emitting light in wavelength ranges that does not overlap with the emission spectra of the above 8 fluorophores.

The present invention is to provide methods and devices that monitoring health and diagnosing a disease by directly measuring the biomarkers inside a cell (intra-cellular detection) rapidly and easily.

A cartridge for use with an instrument to perform measurement of a fluid, including a digital microfluidics substrate comprising a plurality of electrowetting electrodes operative to perform droplet operations on a liquid droplet in a droplet operations gap; a top plate separated from the digital microfluidics substrate to form a droplet operations gap and comprising openings for injecting liquids into the droplet operations gap; a fiber assembly comprising a fiber optic probe projecting into the droplet operations gap and having a sensing end situated in proximity with one or more of the electrowetting electrodes.

The invention relates to methods for detecting and/or characterising a nanovesicle in a sample or a method of detecting a target that is bound or associated with said nanovesicle, wherein the sample is brought into contact with nanoparticles that are capable of binding on the surface of nanovesicle and form, in situ, a nanoshell that surround said nanovesicle. In a preferred embodiment, the nanovesicle is exosome labelled with fluorescent probes and the nanoparticles are gold nanoparticles (AuNP). The invention also relates to a kit or microfluidic chip for performing such methods, as well as a method of determining the prognosis of a cancer in a subject by performing such methods.

The invention relates to methods, compositions, kits, and assay systems for assay signal amplification. Also provided herein is a signal amplification reagent, wherein the signal amplification reagent is an antibody or antigen-binding fragment thereof.

In some aspects, the present disclosure relates to methods for reducing the crowding of signals, for example optical crowding, that can occur when nucleic acids are detected in a sample in multiplex, which can make it difficult to resolve individual signals and can lead to a reduced dynamic range. In some aspects, the present disclosure relates to methods for reducing signal crowding in the detection of multiple target nucleic acid sequences in a sample, e.g., using hybridization probes, wherein signal crowding from said hybridization probes is reduced. The methods herein have particular applicability in the detection of barcode sequences by sequencing-by-hybridization (SBH) methods, including those relying on combinatorial labelling schemes and decoding of the barcodes by sequential cycles of decoding using hybridization probes. Also provided are kits comprising probes for use in such methods.