A microfluidic chip includes a flow passage plate, a flat plate, and an annular seal. In the flow passage plate, a recess forming a flow passage for liquid and a communication hole communicating with the recess are formed. The flat plate is stacked on or under the flow passage plate to close the recess for defining the flow passage. In the flat plate, a communication through-hole communicating with the recess is formed. The annular seal is located on, or formed on, an outer surface of at least one of the flow passage plate and the flat plate, the annular seal surrounding at least one of the communication hole and the communication through-hole. The annular seal is made of an elastomer.

This liquid handling apparatus has a single introduction part that opens on a first surface side of a substrate and is for introducing a liquid, a plurality of discharge parts that open on the first surface side of the substrate and are for discharging the liquid that has been introduced through the single introduction part, a flow path for connecting the single introduction part and the plurality of discharge parts within the substrate, and a plurality of outflow prevention parts that are disposed so as to surround the openings of the plurality of discharge parts and are for using the surface tension of the liquid to check the progress of the outflow of the liquid from the discharge parts. For each opening part, there are two or more outflow prevention parts disposed so as to surround the opening part.

A method for optical contact bonding components includes: placing a first surface (2a) of a first component (2) onto a second surface (3a) of a second component (3), to form an air film, and pressing the first surface against the second surface for optical contact bonding of the two components. Placing and pressing the first component is carried out by a robot (4). A laminar gas flow (10) is generated between the first and second surfaces with a ventilation device (9). A related apparatus (1) includes: the robot, configured to place the first surface onto the second surface thereby forming an air film. The robot presses the first surface against the second surface, to optically contact bond the first and second components. A holding device (8) holds the second component during the placing and pressing. A ventilation device generates the laminar gas flow between the first and second surfaces.

A parallelized chain-synthesizing technique includes capillary tubes, where each tube provides multiple locations or addresses where a specific arbitrary sequence for polymeric chains can be synthesized. An optical addressing system selectively delivers light to the locations to mediate or control reactions in the tubes.

To provide a plate with which, although the plate has a plurality of microchannels or a microchannel in which a plurality of branch channels are formed, when a sample flowing through a microchannel is observed by a microscope, it is possible to easily identify the position of the microchannel or the branch channel under observation without reducing the magnification of the microscope. A plate having a microchannel therein includes an identification mark for identifying a position of the microchannel in a plane direction of the plate. When the microchannel includes a plurality of mutually independent microchannels, the identification mark is preferably formed for each microchannel. When the microchannel includes a source channel communicating with an injection port through which a sample is injected and a plurality of branch channels communicating with the source channel, the identification mark is preferably formed for each of the source channel and the branch channels.

A sample loading cartridge (1) for a microfluidic device comprises a cartridge body (10) with a sample reservoir (20) configured to house a volume of a liquid sample (3) and a sample port (30) in connection with the sample reservoir (20). The cartridge (1) also comprises an output channel (40) extending from the sample reservoir (20) and a feedback channel (50) connected to the sample reservoir (20) and to the sample port (30). The cartridge body (10) comprises a detection portion (60) aligned with the feedback channel (50) to enable detection of any sample (3) in the feedback channel (50). The flow resistance of the feedback channel (50) is lower than the flow resistance of the output channel (40) to cause liquid sample (3) received in the sample port (30) to enter the feedback channel (50) with substantially no liquid sample (3) entering the output channel (40).

A method for producing a cavity in a substrate composed of hard brittle material is provided. A laser beam of an ultrashort pulse laser is directed a side surface of the substrate and is concentrated by a focusing optical unit to form an elongated focus in the substrate. Incident energy of the laser beam produces a filament-shaped flaw in a volume of the substrate. The filament-shaped flaw extends into the volume to a predetermined depth and does not pass through the substrate. To produce the filament-shaped flaw, the ultrashort pulse laser radiates in a pulse or a pulse packet having at least two successive laser pulses. After at least two filament-shaped flaws are introduced, the substrate is exposed to an etching medium which removes material of the substrate and widens the at least two filament-shaped flaws to form filaments. At least two filaments are connected to form a cavity.

Described herein are embodiments of a microfluidic device configured to facilitate conceptualization of scientific principles and uses thereof.

Disclosed herein are processes and devices for use in the electrochemical detection of a target in a sample. For example, silicon or glass surfaces are treated with silanes functionalized with various side chains to tune the surface wetting characteristics.

A technique related to sorting entities is provided. An inlet is configured to receive a fluid, and an outlet is configured to exit the fluid. A nanopillar array, connected to the inlet and the outlet, is configured to allow the fluid to flow from the inlet to the outlet. The nanopillar array includes nanopillars arranged to separate entities by size. The nanopillars are arranged to have a gap separating one nanopillar from another nanopillar. The gap is constructed to be in a nanoscale range.