An analysis apparatus including a stage, an analysis device placed on the stage and including receiving sections which accommodate a sample and a reagent for biochemical reaction, and are communicated with one another through a flow path having an inlet and an outlet, a liquid introduction section which is connected to the inlet and supplies into the flow path the sample, the reagent, and an sealing liquid for sealing each of the receiving sections, and a waste liquid storage section which is connected to the outlet and stores as waste liquid an excess of the sample and the reagent and a part of the sealing liquid supplied to the flow path, an optical system which includes an objective lens, emits excitation light to the receiving sections and allows observation of fluorescence generated in the receiving sections by the excitation light, and a control unit that controls such that the sealing liquid and the excess of the sample and the reagent form an interface in the waste liquid storage section, and that the interface is formed at a distance not less than a fluorescence-obtainable distance from a bottom of the receiving sections.

A receiving unit for receiving a fluid has a receiving element with a receiving face and at least one micro-cavity that is arranged and formed in the receiving element on the receiving face in order to receive the fluid. The receiving face further has a hydrophilic surface characteristic in at least one subregion adjoining the at least one micro-cavity.

Provided are a gene detection kit and a gene detection device. The gene detection kit includes a kit body, a piston cylinder, and a piston. The kit body has an accommodating cavity and a plurality of reagent cavities. The piston cylinder is provided in the accommodating cavity, and the piston cylinder has a piston cavity. The piston is movably provided in the piston cavity along an axial direction of the piston cylinder. A first channel in communication with the piston cavity is provided on an outer circumferential surface of the piston cylinder, a plurality of second channels are provided on an inner wall of the accommodating cavity, each of the second channels is in corresponding communication with one of the reagent cavities, and the piston cylinder can move relative to the kit body, so that the plurality of second channels are alternately in communication with the first channel.

Provided herein is a fluid delivery method for permeabilizing a biological sample. The method includes delivering the fluid to a first substrate and/or a second substrate. At least one of the first substrate and the second substrate includes a spacer. The method further includes assembling, subsequent to the delivering, a chamber comprising the first substrate, the second substrate, the biological sample, and the spacer. The spacer may be disposed between the first substrate and second substrate. The spacer may be configured to maintain the fluid within the chamber and maintain a separation distance between the first substrate and the second substrate. The spacer may be positioned to at least partially surround an area on the first substrate on which the biological sample is disposed and/or at least partially surround the array disposed on the second substrate.

Among other things, the present invention is related to devices and methods of performing biological and chemical assays, particularly an easy sample manipulation and/or a rapid change or a rapid thermal cycling of a sample temperature is needed (e.g. Polymerase Chain Reaction (PCR) for amplifying nucleic acids).

Methods and apparatuses for mechanically controlling microfluidic movement using a force applicator and an elastically deformable sheet are described herein. These apparatuses may include a mechanical microfluidics actuator devices and a cartridge. A microfluidic droplet may be moved or displaced within an air gap of the cartridge by applying a compressive force locally and selectively reduce the gap width of the air gap near the microfluidic droplet causing the microfluidic droplet to move toward the reduced gap. Compressive forces may also be used to divide, join, mix or perform other operations on the microfluidic droplets.

A system is disclosed for measuring head framing and tip straightness in a liquid handler. The present system uses a test plate, having an upper surface formed of clay or other impressionable material. The test plate may be placed at a liquid handling station. Pipette tips may then be loaded onto the head, and the head positioned at the station including the test plate. The head may be actuated in the z-direction so that the tips leave an imprint in the upper surface of the test plate. The imprint of the tips on the test plate may then be analyzed using any of a variety of measurement techniques to determine head framing alignment or misalignment.

Techniques regarding one or more structures that can facilitate automated, multi-stage processing of one or more nanofluidic chips are provided. For example, one or more embodiments described herein can comprise a system, which can comprise a roller positioned adjacent to a microfluidic card comprising a plurality of fluid reservoirs in fluid communication with a plurality of nanofluidic chips. An arrangement of the plurality of nanofluidic chips on the microfluidic card can defines a processing sequence driven by a translocation of the roller across the microfluidic card.

An analysis unit for quantitating detection target substances bound to antibodies includes wells and inclination parts. The wells each have a hole-like shape defined by an opening, an inner circumferential surface, and a bottom. The inclination parts each have an inclined surface connected to the inner circumferential surface and inclined downward such that whose height with respect to the bottom decreases as a distance from an outer circumferential side of the well increases.

An apparatus for washing an array plate includes one or more dispensers and one or more aspirators that are distinct from the one or more dispensers. A respective dispenser of the one or more dispensers is configured to dispense a first liquid on the array plate, and a respective aspirator of the one or more aspirators is configured to aspirate liquid on the array plate. A method for washing particles is also disclosed.