A microplate processing device having at least one carriage with a first receptacle for microplates where the at least one carriage is movable in a first horizontal direction, and having at least one lift that is movable in a vertical direction, where the microplates can be removed from and supplied to the carriage, the carriage has a through-opening, the periphery, in the vertical projection, can at least in part be situated horizontally within the periphery of a microplate held in the carriage, and the lift has a second receptacle for microplates, the periphery, in the vertical projection, is situated within the periphery of the through-opening, where the second receptacle can be moved unhindered through the through-opening in the vertical direction.

In one example, a dispenser platform can include an enclosure that includes a first actuator to move a support in a first plane, wherein a portion of the support extends outside the enclosure, and a second actuator coupled to the portion of the support that extends outside the enclosure to move a stage coupled to the support in a second plane.

Material transfer/interrogation devices (e.g. liquid handling workstations) have been designed in the past for transferring material from a source to a destination location or for interrogating a material at a location, where the locations remain fixed. The invention provides methods and apparatuses for transferring or interrogating materials by one or more carrier devices to one or more receiving devices, where the carrier and receiving devices move independently and simultaneously on multiple axes. In some embodiments, one or more of the carrier and receiving devices can move along an X, Z, Y, and Theta axis, which allows the source and destination locations to rotate and translate relative to each other. Due to this rotation and translation, containers can be positioned to minimize the distance traveled between a pick location from the source and a place location on the destination, greatly increasing the speed at which material transfer can occur.

A microplate reader having a receiving apparatus for receiving a microplate having predefined dimensions and a multiplicity of wells, and an optical detector for detecting an optical radiation at respective individual ones of the wells of a microplate that in the receiving apparatus. The receiving apparatus is arranged to be movable in at least one spatial direction by a positioning mechanism to position the received microplate relative to the optical detector for successive measurements at different wells. The movable receiving apparatus has an interface device configured to provide an energy and/or data connection and/or a media supply connection and/or media disposal from the microplate reader to an accessory apparatus for additional functions. The interface device enables additional hardware provided as an accessory apparatus, which can be inserted into the receiving apparatus jointly with or instead of a microplate or some other sample container, to be supplied with energy and communication.

A biologic sample preparation system that prepares samples for processing includes a frame defining a horizontal plane, a pipette assembly, a sample module and an extraction module. The pipette assembly includes a first pipette. The pipette assembly is movably mounted to the frame in a direction substantially perpendicular to the horizontal plane during operation. The sample module includes a sample plate and is movably mounted to the frame. The sample module is movable substantially parallel to the horizontal plane at least from a sample area spaced from the pipette assembly and a working area proximate the pipette assembly. The extraction module includes an extraction plate and is movably mounted to the frame. The extraction module is movable substantially parallel to the horizontal plane at least from an extraction staging area spaced from the pipette, assembly and the working area proximate the pipette assembly.

The present invention describes an automated platform for inoculating a variety of receptacles with biological samples for testing and analysis. The lab automation system includes a plurality of modules used to automate the inoculation of media for subsequent analysis. In this regard, the lab automation system has one module to enter specimen/order information and store an inventory of petri dishes. Another module is used to label the sample receptacles with a unique identifier that associates the receptacles with the sample. Yet another module includes a robot for retrieving sample and inoculating the receptacles. The sample inoculation module also includes an apparatus that will receive slides, inoculate those slides, and further process the slides for analysis. Finally, the lab automation system includes a module that streaks the culture media with the sample. Thus, the automated lab system described herein provides consistent samples with minimal input from a lab operator.

An automated sample inspection system is provided with a conveyance line for conveying sample carriers; an empty sample carrier line for conveying empty sample carriers; and a buffer line for temporarily holding empty sample carriers supplied from the empty sample carrier line to the conveyance line. According to the depletion status of the buffer line of each processing system, and the depletion status of other processing systems adjacent to each processing system, the number of empty sample carriers to be conveyed from the empty sample carrier line to the buffer line of each processing system, and the number of empty sample carriers to be conveyed from the empty sample carrier line of each processing system to the empty sample carrier line of another adjacent processing system are determined. Consequently, delays in the processes in the system can be suppressed due to the suppression of the depletion of sample carriers.

In one example, a dispenser platform can include an enclosure that includes a first actuator to move a support in a first plane, wherein a portion of the support extends outside the enclosure, and a second actuator coupled to the portion of the support that extends outside the enclosure to move a stage coupled to the support in a second plane.

The present invention describes an automated platform for inoculating a variety of receptacles with biological samples for testing and analysis. The lab automation system includes a plurality of modules used to automate the inoculation of media for subsequent analysis. In this regard, the lab automation system has one module to enter specimen/order information and store an inventory of petri dishes. Another module is used to label the sample receptacles with a unique identifier that associates the receptacles with the sample. Yet another module includes a robot for retrieving sample and inoculating the receptacles. The sample inoculation module also includes an apparatus that will receive slides, inoculate those slides, and further process the slides for analysis. Finally, the lab automation system includes a module that streaks the culture media with the sample. Thus, the automated lab system described herein provides consistent samples with minimal input from a lab operator.

A microplate processing device having at least one carriage with a first receptacle for microplates where the at least one carriage is movable in a first horizontal direction, and having at least one lift that is movable in a vertical direction, where the microplates can be removed from and supplied to the carriage, the carriage has a through-opening, the periphery, in the vertical projection, can at least in part be situated horizontally within the periphery of a microplate held in the carriage, and the lift has a second receptacle for microplates, the periphery, in the vertical projection, is situated within the periphery of the through-opening, where the second receptacle can be moved unhindered through the through-opening in the vertical direction.