This application relates to a movable apparatus for collecting and analyzing specimens. In one aspect, the movable apparatus includes a transport means configured to be moved independently and to maintain negative pressure therein by a negative pressure module, and a specimen collecting device arranged in the transport means and configured to collect a specimen under remote control by inserting a specimen collecting member into the nasal cavity of a testee who enters the transport means. The apparatus may also include a specimen transport device arranged in the transport means and configured to transport the specimen collecting member under remote control that has collected the specimen in one direction, and a specimen analysis device arranged in the transport means and configured to extract the specimen from the specimen collecting member that has been transported by the specimen transport device under remote control and to analyze the specimen.

The invention provides a laboratory apparatus for the storage and delivery of samples or labware wherein the apparatus can have a plurality of beams for holding one or more containers of samples or labware consumables in a first set position; a conveyor for motional translation of the one or more supports from a first set position to a second set position where the conveyor has a first pulley in a first set of pulleys translationally connected by a first timing belt to a second pulley in the first set of pulleys, and a first pulley in a second set of pulleys translationally connected by a second timing belt to a second pulley in the second set of pulleys.

An automatic analyzer includes a transporter, a first dispensing probe, a second dispensing probe, a reagent dispenser, a first reaction container transporter, a fluid dispenser, and a second reaction container transporter. The reagent dispenser is configured to dispense the reagent into the first reaction container at a first dispensing position by the first dispensing probe. The first reaction container transporter is configured to move the first reaction container, from the first dispensing position to a sucking position by the transporter. The fluid dispenser is configured to dispense the fluid including the reagent from the first reaction container at the sucking position into the second reaction container at a second dispensing position by the second dispensing probe. The second reaction container transporter is configured to transport the second reaction container containing the fluid from the second dispensing position to the first dispensing position by the transporter.

A system for capturing an image of a plated culture dish. The system includes an imaging device having a camera with a telecentric lens adapted to capture an image of the plated culture dish, a minor adapted to ensure that a label on the side of the plated culture dish is captured in an image of the plated culture dish that is captured by the imaging device. The system further includes at least one light system for illuminating the plated culture dish for image capture. The mirror is placed adjacent to the side of the plated culture dish on which the label is placed and at least a portion of the minor extends beneath a bottom portion of the plated culture dish at the side of the plated culture dish.

A management unit 101 for integrally managing a sample conveyance system 100 generates conveyance path information for conveying a holder 30 on the basis of conditions of conveyance tiles 401 detected by control drivers 301, 302, 303, 304 that perform detection of conditions and driving of the conveyance tiles 401, and control units 201, 202, 203 that manage operations of the plurality of conveyance tiles 401 and that can move the holder 30 in a planar two-dimensional direction, generate a conveyance path of the holder 30 on the basis of the conveyance path information, generate command signals for the conveyance tiles 401, and output the signals to the control drivers 301, 302, 303, 304.

The present invention is one that intends to achieve improvements in both analysis efficiency and analysis accuracy without difficulty, and a biological substance analysis device that analyzes light derived from a biological substance in a sample, and the biological substance analysis device includes: a holder that holds multiple containers containing the sample; a photodetector that is fixed at a predetermined position; a holder driving mechanism that moves the holder to position each of the containers held in the holder at a detection position by the photodetector in sequence; and a light shielding mechanism that, while guiding light emitted from the sample in a container at the detection position to the photodetector, prevents light emitted from the sample in the other containers from being guided to the photodetector.

A liquid distribution method comprises: providing at least two ferrying units, each ferrying unit made to reciprocate between an initial workstation and a first workstation; transferring from the initial workstation onto each ferry unit a reactor containing a sample; at the first workstation, adding a reagent into the reactor; recording, as a first cycle, a shortest time window during which a sequence of actions performed by each ferry unit can be cyclically reproduced, and recording, as a second cycle, a quotient obtained by dividing the first cycle by the number of ferry unit, and successively transferring the reactors to other ferry units staggeredly at intervals of the second cycle; and sequentially removing from the ferry units the reactors for which the mixing has been completed, staggeredly at intervals of the second cycle, and placing another reactor containing the sample onto the ferry unit from which the reactor was removed.

A sample container transport system for moving sample containers in an in-vitro diagnostic (“IVD”) laboratory system is proposed, the sample container transport system comprising a gripping apparatus for gripping sample containers, and a robotic movement apparatus for moving the gripping apparatus in multiple directions, characterized in that the sample container transport system comprises a multidimensional-force sensor that is designed for detecting a multidimensional-force signal indicative of forces in multiple directions acting on a sample container gripped by the gripping apparatus. Further, a method for using the sample container transport system is proposed.

The present invention relates to an ELISA-based, liquid-phase immunoassay apparatus optimized for detecting particular ingredients contained in a biological sample, etc., and a method therefor.

A sample tube rack (10) for receiving at least one sample tube is provided, comprising: a bottom surface (12) comprising at least one opening (14) for receiving the sample tube, and at least two guiding elements (16, 16′, 16a-d) arranged on the bottom surface (12) adjacent to the opening (14), wherein each guiding element (16, 16′, 16a-d) extends substantially parallel to a vertical axis (18) of the opening (14) from the bottom surface (12) towards a top side (20) of the sample tube rack (10). The guiding elements (16. 16′, 16a-d) are arranged at different positions (17a-d) around the opening (14), such that a tube compartment (24) for receiving the sample tube is formed by the guiding elements (16, 16′, 16a-d) and the opening (14), wherein the guiding elements (16, 16′, 16a-d) are spaced apart from each other along a perimeter (21) of the opening (14), thereby forming at least two clearances (22) between the guiding elements (16, 16′, 16a-d) along the perimeter (21) of the opening (14).