Abstract: An instrument turntable is presented which allows an instrument to be installed into an automated system, yet that will still allow an operator to use the instrument manually, even while the automated system is running, without ever removing the instrument from the automated system.

Abstract: An instrument turntable is presented which allows an instrument to be installed into an automated system, yet that will still allow an operator to use the instrument manually, even while the automated system is running, without ever removing the instrument from the automated system.

Abstract: Various embodiments include a sample storage system having: a transport module; a storage module coupled with the transport module on at least one side of the transport module, the storage module for storing a plurality of specimen tubes or microtiter plates; a tube selector module coupled to an end of the transport module for selecting at least one of the plurality of specimen tubes or microtiter plates; and an input/output (I/O) module coupled with the transport module on a side of the transport module, wherein the transport module is configured to modularly couple with at least one additional storage module for storing a plurality of specimen tubes or microtiter plates.

Abstract: A housing for an automated centrifuge with side and top access is disclosed. The housing includes an inner housing for enclosing at least one labware nest of the automated centrifuge, the inner housing having a top and a side body substantially surrounding the at least one labware nest, wherein the inner housing includes an opening through both a portion of the top and a portion of the body, and a door movably connected to the inner housing, and movable relative to the open between an open position, in which the door exposes the opening, and a closed position in which the door blocks the opening.

Abstract: A housing for an automated centrifuge with side and top access is disclosed. The housing includes an inner housing (104) for enclosing at least one labware nest (108) of the automated centrifuge, the inner housing having a top and a substantially cylindrical body, wherein the inner housing includes an opening through both a portion of the top and a portion of the body; and a door (114) configured to move between an open position in which the door exposes the opening and a closed position in which the door blocks the opening.

Abstract: Various embodiments include a sample storage system having: a transport module; a storage module coupled with the transport module on at least one side of the transport module, the storage module for storing a plurality of specimen tubes or microtitre plates; a tube selector module coupled to an end of the transport module for selecting at least one of the plurality of specimen tubes or microtitre plates; and an input/output (I/O) module coupled with the transport module on a side of the transport module, wherein the transport module is configured to modularly couple with at least one additional storage module for storing a plurality of specimen tubes or microtitre plates.

Abstract: An automated testing system includes one or more laboratory devices that operate together to perform an assay. The testing system is designed such that a laboratory device may be seamlessly integrated with the remaining devices in a quick and effortless manner. Specifically, the laboratory device is securely mounted on a slidable cart with fluid and electrical connections established therebetween. The slidable cart is in turn adapted to releasably engage with a docking station that is fixedly mounted on the workspace floor, the docking station being provided with at least one fluid input connection, an input power connection and at least one communication signal connection that are relatively permanent in nature. In order to couple the cart to the docking station, the cart is rolled generally into position above the docking station using complementary alignment posts and tracks.

Abstract: A method and system for self-sterilizing an automated incubator is disclosed. The internal temperature of the automated incubator is elevated by forcing hot air to flow into the internal incubation chamber, wherein all mechanics and electronics associated with the automated plate mover are outside the internal incubation chamber. During sterilization, the heating system of the automated incubator will force hot air to flow over the internal surfaces of the incubator, thereby reducing contaminating microorganism resistance by inducing dehydration.

Abstract: Automated testing system arrangements using a docking station. One system includes a unit including: a) a polygonal base having a plurality of sides, a number of the plurality of sides including a docking station for mating with a mobile equipment carrying cart; and b) a robotic arm having a stationary base positioned on or in the polygonal base and configured to interact with the equipment on each mobile equipment carrying cart.

Abstract: A housing for an automated centrifuge with side and top access is disclosed. The housing includes an inner housing (104) for enclosing at least one labware nest (108) of the automated centrifuge, the inner housing having a top and a substantially cylindrical body, wherein the inner housing includes an opening through both a portion of the top and a portion of the body; and a door (114) configured to move between an open position in which the door exposes the opening and a closed position in which the door blocks the opening.

Abstract: A robot teach tool is provided that enables automatic teaching of pick and place positions for a robot. The automated robot teach tool obviates the need for manual operation of the robot during the teaching. The result is an automated process that is much faster, more accurate, more repeatable and less taxing on a robot operator.

Abstract: An automated lidder and/or delidder apparatus to engage and disengage a lid from a microplate is disclosed. The microplate includes a sample area with a plurality of individual wells and a hollow outer frame formed around the sample area, the frame being shaped to include a plurality of openings in its top surface. The lid includes a plate and a plurality of latches formed on the underside of the plate. In the lidding process, the apparatus presses down on the lid to insert each latch through a corresponding opening in the microplate until the latch snaps into engagement with the frame. In the delidding process, the apparatus inserts delidding posts into the openings to disengage the latches from the frame.

Abstract: An automated lidder and/or delidder apparatus to engage and disengage a lid from a microplate is disclosed. The microplate includes a sample area with a plurality of individual wells and a hollow outer frame formed around the sample area, the frame being shaped to include a plurality of openings in its top surface. The lid includes a plate and a plurality of latches formed on the underside of the plate. In the lidding process, the apparatus presses down on the lid to insert each latch through a corresponding opening in the microplate until the latch snaps into engagement with the frame. In the delidding process, the apparatus inserts delidding posts into the openings to disengage the latches from the frame.

Abstract: An instrument turntable is presented which allows an instrument to be installed into an automated system, yet that will still allow an operator to use the instrument manually, even while the automated system is running, without ever removing the instrument from the automated system.

Abstract: A method and system for self-sterilizing an automated incubator is disclosed. The internal temperature of the automated incubator is elevated by forcing hot air to flow into the internal incubation chamber, wherein all mechanics and electronics associated with the automated plate mover are outside the internal incubation chamber. During sterilization, the heating system of the automated incubator will force hot air to flow over the internal surfaces of the incubator, thereby reducing contaminating microorganism resistance by inducing dehydration.

Abstract: A reusable microplate kit for use in the life sciences industry includes a microplate and a removable lid. The microplate includes a sample area with a plurality of individual wells and a hollow outer frame formed around the sample area, the frame being shaped to include a plurality of openings in its top surface. The lid includes a plate, a plurality of latches formed on the underside of the plate and a compressible gasket affixed to the underside of the plate. In use, the lid is mounted on the microplate by inserting each latch through a corresponding opening until the latch snaps into engagement with the frame. In this manner, the plate and gasket together serve to seal off each well from the outside environment. The microplate kit additionally includes a tool for disengaging the lid from the microplate and thereby assist in their separation.

Abstract: System including enclosure having smart glass panels and related method.

Abstract: A robot teach tool is provided that enables automatic teaching of pick and place positions for a robot. The automated robot teach tool obviates the need for manual operation of the robot during the teaching. The result is an automated process that is much faster, more accurate, more repeatable and less taxing on a robot operator.

Abstract: An automated testing system includes one or more laboratory devices that operate together to perform an assay. The testing system is designed such that a laboratory device may be seamlessly integrated with the remaining devices in a quick and effortless manner. Specifically, the laboratory device is securely mounted on a slidable cart with fluid and electrical connections established therebetween. The slidable cart is in turn adapted to releasably engage with a docking station that is fixedly mounted on the workspace floor, the docking station being provided with at least one fluid input connection, an input power connection and at least one communication signal connection that are relatively permanent in nature. In order to couple the cart to the docking station, the cart is rolled generally into position above the docking station using complementary alignment posts and tracks.

Abstract: Automated testing system arrangements using a docking station. One system includes a unit including: a) a polygonal base having a plurality of sides, a number of the plurality of sides including a docking station for mating with a mobile equipment carrying cart; and b) a robotic arm having a stationary base positioned on or in the polygonal base and configured to interact with the equipment on each mobile equipment carrying cart.