A reagent analyzer and method is described. In the method, a reagent card having a reagent pad is passed through an optical signal path between an optical signal source and an optical signal detector. A transition between a first electrical signal and a second electrical signal is detected to determine a substantially exact position of a leading end or a trailing end of the reagent pad. The first electrical signal is indicative of the substrate interfering with the optical signal. The second electrical signal is indicative of the substrate and reagent pad of the reagent card interfering with the optical signal. The reagent pad is moved to a known second location upon determining the substantially exact position of at least one of the leading end and the trailing end of the reagent pad. At the second location a sample is dispensed onto the reagent pad by a sample dispenser.

An automatic analyzer capable of positioning in a short time is provided. The automatic analyzer includes: a rotation mechanism configured to rotate, in a circumferential direction in a horizontal plane, a nozzle configured to perform at least one of aspiration of a fluid in a container accommodated in an accommodation portion disposed on a trajectory during rotation and discharge of the fluid to the container; a height positioning mechanism configured to position a position adjustment tool accommodated in the accommodation portion in a height direction by driving the nozzle; and a circumferential positioning mechanism configured to position the accommodation portion accommodating the position adjustment tool in a circumferential direction by bringing the nozzle into contact with the position adjustment tool from a side thereof after a height position of the position adjustment tool is determined.

Provided are methods and apparatuses for controlling a position of a target point on a processing result relative to a focus point of a focusing sensor system for determining properties of the processing result. The method includes the steps of determining an initial focus point of the focusing sensor system, controlling rotation of the cartridge and disc, checking whether the initial focus point of the focusing sensor system corresponds to the target point on the processing result, comparing (x, y) target positions in captured images with the initial focus point of the focusing sensor system, adjusting rotation of the cartridge and disc such that the focus point of the focusing sensor system corresponds to the target point on the processing result, and detecting and examining signals received from the focusing sensor system for determining properties of the processing result.

Systems and methods are provided for sample processing. A device may be provided, capable of receiving the sample, and performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing multiple assays. The device may comprise one or more modules that may be capable of performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing the steps using a small volume of sample.

A method for performing a laser microdissection for cutting a dissectate from a specimen using a laser includes the step of providing the specimen in a light path of an illumination system. The specimen is illuminated by the illumination system. A detector detects light emanating from the specimen. The light detected by the detector is analyzed. It is determined, based on the analysis of the light detected by the detector, whether a receptacle for collecting the dissectate is disposed in a predetermined collection position, at which the dissectate is to be collected in the receptacle after it is cut from the specimen. Laser cutting of the dissectate from the specimen is initiated based on it having been determined that the receptacle is in the predetermined collection position.

Described is an apparatus for controlling a position of a sample in a liquid chromatography system. The apparatus includes a rotary drive mechanism, a stepper motor and a rotational coupling system such as a drive belt and pulley system. The rotational coupling system transfers the rotational motion of a motor shaft to a shaft of the rotary drive mechanism. Advantageously, the stepper motor is remote to the sample compartment for improved safety in the event that volatile gas accumulates within the sample compartment. The rotary drive mechanism can be configured in a small form factor and can provide highly stable rotation of an attached sample tray to accommodate the requirements of compact liquid chromatography systems. In addition, leakage from inside the sample compartment to the ambient environment is substantially reduced or eliminated, resulting in better thermal control of the sample compartment.

When an automatic analysis apparatus has a mechanism that performs an operation of an arcuate trajectory to access a plurality of positions arranged on a straight line, an arc and a straight line cannot coincide with each other. Thus position adjustment is required to minimize the deviation between the arc and the straight line. An automatic analysis apparatus according to the invention includes a reagent disk which accommodates a plurality of reagent bottles in each of which a plurality of suction ports are arranged along a center line, and which rotates around a central axis to transport a reagent bottle to a desired position; and a reagent dispensing mechanism which rotates around a rotation axis to suck a reagent from the reagent bottle at a predetermined suction position on the reagent disk, in which the reagent disk is provided with, at least one mounting position of the reagent bottle on the reagent disk, first and second marks sandwiching the mounting position of the reagent bottle.

A system for biological analysis includes a housing, a block assembly within the housing having a sample block and a baseplate, a heated cover and a cover carrier. The sample block receives a sample holder comprising an RFID tag. A first drive mechanism generates relative movement between the sample block and the baseplate along a first axis. A second drive mechanism generates relative movement between the heated cover and the cover carrier along a second axis that is different from the first axis. Based on a first command the first drive mechanism releasably engages the sample block and operates the second drive mechanism to releasably engage the heated cover with the cover carrier. The system also includes first and second RFID antennas that receive RFID data from the sample holder RFID tag that is read by at least one RFID reader.

Provided is a connection module with a high degree of freedom for an automatic analyzer which does not depend on a device as a discharge destination. For this purpose, a module to be connected to an automatic analyzer with a rack rotor mechanism includes: a rack discharge mechanism for moving a rack from the rack rotor mechanism to a rotation holder; a rack rotating mechanism for rotating the rack moved to the rotation holder; a conveyor mechanism for transporting the rack from the rack rotating mechanism to a discharge port; and a feeder mechanism for pushing the rack out of the rotation holder to the conveyor mechanism, in which the rack rotating mechanism rotates the rotation holder from a direction parallel to the rack discharge mechanism to a direction parallel to the feeder mechanism and the conveyor mechanism in the selected rotation direction.

Systems and methods for use in an in vitro diagnostics setting may include an automation track, a plurality of carriers configured to carry a plurality of sample vessels along the automation track, and a characterization station including a plurality of optical devices. A processor, in communication with the characterization station, can be configured to analyze images to automatically characterize physical attributes related to each carrier and/or sample vessel. A method may include receiving a plurality of images from a plurality of optical devices of a characterization station, wherein the plurality of images comprise images from a plurality of perspectives of a sample vessel being transported by a carrier, automatically analyzing the plurality of images, using a processor, to determine certain characteristics of the sample vessel, and automatically associating the characteristics of the sample vessel with the carrier in a database.