A method of testing an antibiotic susceptibility includes dispensing and cultivating sample solution into culture wells including one or more comparative wells and a plurality of antibiotic wells receiving two or more kinds of antibiotics, respectively, receiving the sample solution into a plurality of preprocessing wells each including magnetic particles and fluorescent particles that bond to one or more kinds of bacteria such that the bacteria and the magnetic particles and fluorescent particles bond to each other, receiving the sample solution into a plurality of image wells having magnetic members thereunder such that the magnetic particles bonding to the bacteria are arranged on the bottoms of the image wells, removing the sample solution from the image wells that have undergone the planarizing step, taking fluorescent images of the image wells washed in the washing step, and determining an antibiotic tolerance/susceptibility of the sample solution by analyzing the fluorescent images.

The present invention provides devices and systems for use at the point of care. The methods devices of the invention are directed toward automatic detection of analytes in a bodily fluid. The components of the device are modular to allow for flexibility and robustness of use with the disclosed methods for a variety of medical applications.

The sample plate has a principal plane in which a plurality of wells is arranged. The sample plate has a plurality of through-holes each allowing a sampling needle to pass through in a region of the principal plane where the wells are not provided, and positions of the wells and positions of the through-holes are designed such that when two pieces of the sample plates are arranged up and down with a predetermined positional relationship in a state in which respective principal planes are arranged in parallel each other, the through-holes of the sample plate arranged on an upper side is arranged at positions directly above respective wells of the sample plate arranged on a lower side.

A vacuum manifold for filtration microscopy includes a manifold top having multiple openings, and a capture membrane positioned above and spaced apart from the manifold top, where the capture membrane is configured to deflect into contact with a surface of the manifold top when a negative pressure is applied to the multiple openings. A method for filtration microscopy includes the steps of providing a vacuum manifold including a manifold top having a plurality of openings, and a capture membrane positioned above and spaced apart from the manifold top; applying sample drops to sample spots on the membrane, the sample spots positioned above the plurality of openings; applying a negative pressure to the openings such that the capture membrane contacts a surface of the manifold top; and optically imaging particulates on the capture membrane.

In a sample pretreatment device, a container storage section (2) holds multiple containers, including a first well plate having wells in an N×M matrix form and a second well plate having N elongated wells whose length corresponds to M wells in one row of the first well plate or M elongated wells whose length corresponds to N wells in one column of the first well plate. A dispensing section (3) includes: a platform (30) on winch containers can be placed; a pipette unit (311, 312) including an M-channel tip corresponding to M wells in one row of the first well plate or an N-channel tip corresponding to N wells in one column of the first well plate; and a pump unit (313) for suctioning/ejecting a liquid from/into a container on the platform through the pipette unit. A transfer section (4) transfers containers between the container storage section and the platform. A controller (5) controls operations of the dispensing section and the transfer section.

Automated analyzer (2000) comprising a housing (2010, 3010), a robotic arm comprising an end effector (2360), the end effector (2360) comprising a body (2320) rotatably connected to an articulating arm and first (2363a) and second fingers (2363b) coupled to the body (2362) and being moveable relative to each other in a first direction, each of the fingers (2363a, b) having an engagement feature (2361) projecting inwardly from each of the first and second fingers (2363a, b) and toward the other of the first and second fingers (2363a, b). The automated analyzer (2000) further comprises a shuttle platform (2030) for receiving a shuttle (2030) carrying sample containers (03), the containers carrying sample (03) to be evaluated by the analyzer (2000) and the shuttle platform (2030) comprising a jaw assembly that engages the bottom portion of the sample containers when the jaw assembly is in the closed position.

Carriers are provided for microbiological laboratory use, as are methods for their use. The carriers may be used to transport patient samples between laboratory stations and can be loaded into automated AST systems. In an aspect, a method of performing AST may include loading a tube comprising a patient sample onto a carrier. An AST panel may be loaded onto the carrier. The carrier may be conveyed to an automated inoculation assembly. The patient sample may be inoculated from the tube into the AST panel. The AST panel may be loaded into an automated AST system.

The present invention relates to an immunoassay method and an immunoassay device.

According to an aspect of the present invention, provided is an immunoassay device including: a stage capable of accommodating a plurality of cartridges having a plurality of wells; a solution transfer unit including a plurality of tips, which are movable relative to the stage and disposed to correspond to a position of the cartridge so as to suction a solution stored in each of the wells or discharge the suctioned solution from the well; and a control unit controlling the stage and the solution transfer unit to be relatively movable and controlling suction or discharge of a content into/from the plurality of tips.

The present invention relates to an immunoassay device and an immunoassay method.

According to an aspect of the present invention, an immunoassay device includes a measurement unit provided with a detection unit disposed at one side of a stage accommodating cartridges having a plurality of wells to move in a direction, in which the plurality of cartridges are arranged, and capable of measuring a state within the well disposed at the outermost side, and including a shielding plate that moves to cover an opened upper portion of the well disposed at the outermost side to block introduction of light into the well.

Articles, systems, and methods for transferring liquids that may employ a robot.