A cell chip includes first, second and third elements, a dye dialysis layer, a micro-channel structure and washing solution inlet and outlet. The first element has a first hole and second holes at opposite sides of the first hole. The second element has a third hole corresponding to the first hole and fourth holes corresponding to the second holes. The dye dialysis layer is inserted between the first element and the second element and has a cell-assembly region corresponding to the first and third holes. The micro-channel structure is disposed below the cell-assembly region and between the second and the third elements. The washing solution inlet and outlet are communicatively connected to the micro-channel structure. The washing solution inlet includes the second hole and a corresponding fourth hole. A washing solution flows in the micro-channel structure through the washing solution inlet and outlet.

An apparatus and method for producing a coated analytic substrate using a compact and portable automated instrument located in the laboratory setting at the point of use which can consistently produce one or a plurality of coated analytic substrates “on demand” for using the analytic substrate immediately after coating, preferably without a step of rinsing the coated analytic substrate before use. The apparatus preferably uses applicator cartridges having a reservoir containing the coating compositions used to form the coatings. Preferably the cartridges are removable and interchangeable to facilitate the production of individual analytic substrates having different coatings or different coating patterns. These coated analytic substrates have superior specimen adhesion characteristics due to the improved quality of the coatings applied by the coating apparatus and due to the quickness with which the coated analytic substrates can be used in the lab after production.

A biological chip, a manufacturing method thereof, an operation method thereof, and a biological detection system are provided. The biological chip includes a base substrate and a plurality of working units. The plurality of the working units are arranged on the base substrate; each of the working units includes a working element configured to be in contact with a target substance; and the working element includes a metal electrode and an electric-field-controllable surface modification layer on a surface of the metal electrode.

A fully integrated miniaturized optical biosensor and methods of making the same are disclosed. The biosensor may include a fluid transport system and an optical system.

The present disclosure provides a sensor substrate capable of detecting a trace amount of an analyte. This sensor substrate according to the present disclosure is a sensor substrate comprising a metal microstructure that generates surface plasmon when irradiated with excitation light. The metal microstructure is composed of a plurality of protrusions disposed in a planar shape. The plurality of the protrusions are disposed in such a manner that imaginary lines V each passing through a center between adjacent protrusions draw a honeycomb shape in a plan view. Each of the plurality of the protrusions has a substantially hexagonal shape in the plan view. A depth in a thickness direction of the sensor substrate of a gap present between the adjacent protrusions is larger than a radius of an imaginary circle inscribed in a hexagon forming the honeycomb shape.

Provided is a microchip that can achieve a favorable bonding state in the bonding portion between first and second substrates even if the microchip is large in size. A microchip includes a first substrate made of a resin and a second substrate made of a resin, the first substrate and the second substrates being bonded to each other, and a channel surrounded by a bonding portion between the first substrate and the second substrate is formed by a channel forming step formed at least in the first substrate. Further, a noncontact portion is formed to surround the bonding portion, and an angle θ.sub.1 formed between a side wall surface of the channel forming step and a bonding surface continuous therewith satisfies θ.sub.1>90°.

Disclosed are a detection chip and a manufacturing method therefor, and a reaction system. The detection chip includes: a first substrate (11); a microcavity defining layer (12), which is located on the first substrate (11) and defines a plurality of micro-reaction chambers (120); and a shading structure layer (13), which is located on the first substrate (11) and provided among the plurality of micro-reaction chambers (120). In practical application, the number of target molecules in a reaction system solution in each micro-reaction chamber (120) can be determined by collecting a fluorescence image; and the detection chip is provided with the shading structure layer (13), and the shading structure layer (13) is located on the first substrate (11) and provided among the plurality of micro-reaction chambers (120).

A container for the heating of samples and a system comprising such a container and provides a container for processing samples, wherein the container is made of a material comprising electrically conductive particles.

A structure is manufactured by forming a mask that has an opening pattern on a surface of a substrate, etching the surface of the substrate with the mask to form a recessed portion corresponding to the opening pattern of the mask, forming a thin film including aluminum on a bottom surface of the recessed portion in a state where the mask remains, treating the thin film including aluminum with hot water to change the thin film into a fine recessed and projected layer including alumina hydrate smaller than the recessed portion, etching the bottom surface of the recessed portion, on which the fine recessed and projected layer is formed, in a state where the mask remains to form a fine recessed and projected structure on the bottom surface of the recessed portion, and thereafter removing the mask and the fine recessed and projected structure, which remains after the etching step.

A structure is manufactured by forming a mask that has an opening pattern on a fine recessed and projected structure of a substrate having the fine recessed and projected structure with an average period of 1 μm or less on a surface thereof, etching the surface of the substrate from a side of the mask to form a recessed portion which has an opening greater than the average period of the fine recessed and projected structure according to the opening pattern of the mask, the recessed portion having a depth equal to or greater than double a difference in height between recesses and projections of the fine recessed and projected structure, and then removing the mask.