The present invention provides a production-line-type high-throughput screening system, which relates to the field of biotechnology and testing equipment. The system comprises of four manipulators, three parallel conveyor belts with fixed slots, 2-DOF slipway and fixed fixtures, 96-channel pipetting system, coloring device, oscillating mixing device, microplate reader, well plates loading platform and well plates recycling platform. Manual operation takes five minutes to detect one 96-well plate, while this system can handle 20 96-well plates per minute. It expands the number of screening targets, making the screening process more clearly and concisely and liberating manual labor. The system makes effective contributions to the development of microbial breeding technology.

Described herein is a modular robotic system for processing a biological sample, and methods of using a modular robotic system for processing a biological sample. The modular robotic system includes a bidirectional plate transportation track to transport plates within the modular robotic system, as well as robotic arms that can transport the plate from a node on the bidirectional plate transportation tack to a sample processing module. Through this system, the sample and/or consumable plates can be transported throughout the processing system. Additionally, the modular robotic system is configured to be expandable, so that the system can be easily adapted to scale up biological sample processing laboratories.

An analyzer for use with in vitro diagnostics includes an automation system to move a plurality of sample carriers within the system. At least some carriers include a plurality of slots. Each slot is configured to hold one of a plurality of fluid containers. The system also includes a place and pick device configured to place the plurality of fluid containers into the plurality of slots and remove the plurality of fluid containers from the plurality of slots. The system further includes a controller configured to place mother sample tubes along with empty sample tubes into the same carrier and move the carrier to an existing pipettor within the analyzer to aliquot a sample portion of the mother sample into the empty daughter tubes to create aliquots for certain samples without requiring a standalone aliquoting station or substantially disrupting the normal flow of sample tubes within the automation system.

Incubation system and method for automated cell culture and/or testing. An exemplary incubation system may comprise a housing forming a chamber. A rack may define storage positions to support an array of sample holders inside the chamber. A detection robot may be configured to capture one or more images of cells contained by one or more wells of each sample holder while the sample holder remains at one of the storage positions of the rack. A fluid handling station may be configured to add fluid to, and/or remove fluid from, one or more wells of each of the sample holders inside the housing. At least one plate robot may be configured to move sample holders between the rack and the fluid handling station. A computer may control operation of the detection robot, the fluid handling station, and the at least one plate robot.

A secondary solid waste container for solid waste of an analyzer is disclosed. The secondary solid waste container comprises side walls and an impact absorbing member. The side walls comprise an upper end and a lower end. The impact absorbing member is connected to the side walls such that the impact absorbing member extends between the side walls and is spaced apart from the lower end with respect to a direction from the lower end to the upper end. The impact absorbing member is configured to absorb an impact from solid waste of the analyzer. An analyzer and a method for removing solid waste of an analyzer are also disclosed.

An assay performance system may include modules configured to store aqueous sample plates, conduct droplet generation or emulsification of aqueous samples, and to perform thermocycling and droplet reading functions. One or more samples may be emulsified and stored in an emulsified state for extended times prior to thermocycling. Accordingly, the assay performance system may include material handling systems and methods to accommodate the storage function.

A device and method for testing foodstuffs for the presence of microorganisms including an infeed unit for a package containing a foodstuff, a sample analysis device configured to take a sample of the foodstuff and test for the presence of microorganisms, a discharge unit for discharging the package, and a display for displaying the results of testing by the sample analysis device.

A laboratory sample distribution system is presented. The system comprises a number of sample container carriers, a transport plane, a number of electro-magnetic actuators, a number of position sensors and a position determination unit. The position sensors and the position determination unit enable improved sample container carrier position detection on the transport plane. A laboratory automation system comprising such a laboratory sample distribution system is also presented.

A transportation system for paraffin embedded tissues includes a placing assembly, a bearing unit and a storage device. The placing assembly includes a horizontal moving assembly, a vertical moving assembly, a rotation assembly and a placing unit. The horizontal and vertical moving assemblies move the placing unit in horizontal and vertical directions, respectively, and the rotation assembly allows the placing unit to rotate around a vertical axis. The bearing unit receives the paraffin embedded tissues. The storage device has a rotation plate including a plurality of receiving slots each for storing the bearing unit. The placing unit is configured to remove the bearing unit from the storage device, move the bearing unit to a processing apparatus located at another side of the placing assembly, remove the bearing unit from the processing apparatus, and transport the bearing unit to the receiving slot of the storage device.

A luminometer apparatus includes, inside a light-shielded room, a container rack loaded with holding containers, a dispensation mechanism that dispenses a liquid, a rotary plate that turns, while holding a plurality of reaction containers which accommodate a mixture liquid of a sample and a luminescent reagent on a concentric annular plate, and is provided with a gap allowing the container rack to pass therethrough between at least a pair of adjacent ones of the reaction containers, and a photodetection unit that performs luminescence measurements. The light-shielded room has an insertion opening having a width allowing for insertion of the container rack and provided to be openable and closable. The rotary plate is provided with a region in which the container rack can be installed inside a region of passage of the reaction containers, when turning, and is provided to be turnable where the light-shielded room is in a closed state.