Embodiments of the current disclosure are directed to systems, methods and apparatus for evaluating single cell secretion profiles. In some embodiments, the apparatus may be configured to analyze substances expressed by a biological cell and may include a first compressible substrate, and a second substrate configured for removable sealing attachment with the first substrate. In some embodiments, upon attachment of the second substrate with the first substrate, an assembly is formed such that the open side of the plurality of chambers are covered by the second substrate, and a portion of each of the plurality of capture areas are exposed in each of the chambers.

In a method for producing a compound of at least two polymer substrates, two polymer substrates each having a connecting surface are provided. At least one of the polymer substrates is coated with a self-assembling polypeptide, at least in the area of the connecting surface. The two polymer substrates are connected by pressing together the connecting surfaces under pressure and at a temperature corresponding to at least the glass transition temperature of the material of one of the polymer substrates at the connecting surface, wherein a diffusion of polymer chains takes place between the connecting surfaces by the self-assembling polypeptide and a solid connection is formed between the two connecting surfaces. A sealed microfluidic cartridge includes a polymer cartridge and a sealing film connected by such a method.

The present application provides a method and a system for integrating morphological characteristics and gene expression of individual cells. The method comprises the following steps: providing a microfluidic device, which comprises a microwell array and an interdigital electrode, and each microwell comprises a plurality of capture oligonucleotides; injecting cells into the microwells, capturing a single cell and recording morphological characteristics of the cell; lysing the cell so that the mRNA released by the cell is captured by the capture oligonucleotide; reverse transcribing the captured mRNA to obtain cDNA; performing a PCR amplification reaction on the cDNA to obtain a cDNA library and sequencing the cDNA library; reading the cell barcode sequence and the unique molecular identifier sequence according to sequencing results, and the morphological characteristics and gene expression of the cell in the microwell are integrated together.

An electronically-controlled digital ferrofluidic device is disclosed which employs a network of individually addressable coils in conjunction with one or more movable permanent magnets, where each moveable permanent magnet delivers the designated fluid manipulation-based tasks. The underlying mechanism facilitating fluidic operations is realized by addressable electromagnetic actuation of miniaturized mobile magnets that exert localized magnetic body forces on droplets filled with magnetic nanoparticles. The reconfigurable, contactless, and non-interfering magnetic-field operation properties of the underlying actuation mechanism allow for the integration of passive and active components to implement advanced and diverse operations with high efficiency (e.g., droplet sorting, dispensing, generation, merging, mixing, filtering, and analysis).

A solid reagent containment unit is formed by a support; a frame body fixed to the support and delimiting internally, together with the support, an analysis volume; a reagent-adhesion structure within the analysis volume; and at least one reagent cavity, which extends within the reagent-adhesion structure. The reagent-adhesion structure is of an adhesion material embossable at temperatures lower by 6-8° C. than its own melting point and has a melting point such as not to interfere with the analysis. The reagent cavity forms a retention wall, laterally surrounding the reagent cavity, and houses dried reagents. The adhesion material is chosen among wax, such as paraffin, a polymer, such as polycaprolactone, a solid fat, such as cocoa butter, and a gel, such as hydrogel or organogel.

The present invention relates to a biosensor technique in which multiple types of target substances (biomarkers) contained in saliva or the like are allowed to be simultaneously measured or N samples for one target substance (biomarker) are allowed to be simultaneously measured and reliability of sensed results and high sensitivity are secured. A fluidic channel-based planar biosensor chip, in which a plurality of fluidic channels capable of measuring target substances (biomarkers) are embedded in one flat plate sensor chip and the flat plate sensor chip is measured by a light-emitting element (optical source) and a light-receiving element, and a biomarker measuring apparatus using the same are provided.

A solid reagent containment unit is formed by a support; a frame body fixed to the support and delimiting internally, together with the support, an analysis volume; a reagent-adhesion structure within the analysis volume; and at least one reagent cavity, which extends within the reagent-adhesion structure. The reagent-adhesion structure is of an adhesion material embossable at temperatures lower by 6-8° C. than its own melting point and has a melting point such as not to interfere with the analysis. The reagent cavity forms a retention wall, laterally surrounding the reagent cavity, and houses dried reagents. The adhesion material is chosen among wax, such as paraffin, a polymer, such as polycaprolactone, a solid fat, such as cocoa butter, and a gel, such as hydrogel or organogel.

The present disclosure discloses a microfluidic structure, a microfluidic chip and a detection method. The microfluidic structure includes: a first base substrate and a second base substrate opposite to each other, an antibody area located between the first base substrate and the second base substrate and storing an enzyme-labeled first antibody, a cleaning area storing cleaning liquid, a signal substrate area storing a signal substrate solution and a detection area with a second antibody and an ion sensitive film fixed thereon, wherein all channel areas from the antibody area, the cleaning area and the signal substrate area to the detection area each have a driving electrode structure driving liquid drops to move; and the detection area has a thin film transistor connected with the ion sensitive film.

A bio-information detection substrate and a gene chip are provided. The substrate includes a first main surface, the first main surface includes a test region and a dummy region located around the test region, at least one accommodation region is disposed on the first main surface, and the accommodation region is located in the dummy region.

An analytical toilet comprising a bowl for receiving excreta from a user; a base supporting the bowl; a supply of flush water; and a plurality of receptacles, each providing mechanical attachment, a power supply, and a data connection to an analytical device, which analytical device is adapted to provide data useful to the user is disclosed.