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.

Various embodiments are described herein for an apparatus and method for indicating at least one property related to an object. Detection data and optionally input data are received for the at least one property related to the object and at least one light property that corresponds to the at least one property related the object based on the detection signal is determined using a processing unit. A light is then generated and projected to illuminate and/or surround at least a portion of the object, the light being based on the at least one light property to indicate the at least one property related to the object.

Disclosed is a blood sample analyzer, including: a sample conveying device for conveying a sample rack loaded with a sample container; a first agitating device having a sample stirring component for stirring a blood sample in the sample container and being capable of driving the sample stirring component to uniformly agitate the blood sample in the sample container; a second agitating device capable of picking up the sample rack or a second sample container on the sample rack, and driving the second sample container containing a common-volume blood sample on a second agitating position to uniformly agitate the blood sample; and a controller configured to communicate with the sample conveying device, the first agitating device and the second agitating device, and control the sample conveying device, the first agitating device and the second agitating device. In addition, the present application further discloses a blood sample agitating device, a blood sample analysis method, and a computer storage medium.

Certain configurations described herein are directed to autosamplers. In some instances, the autosampler may include a support comprising a body configured to receive two or more articles at separate sites of the body. The autosampler may also include a first motor coupled to the support and configured to rotate the support in an x-y plane, and a second motor configured to move the support in a z-direction to load one of the at least two articles at the separate sites in the body of the support. An encoder may also be used with the autosampler if desired.

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.

The present invention is related to a liquid handling apparatus having a working platform provided with a plurality of housings for accommodation of consumable products and defining a first portion of a working surface of the apparatus and a feeding platform of the consumable products which defines a second portion of the working surface and comprises at least one modular framework provided with at least one containment frame of the consumable products; wherein the modular framework is movable with respect to the working platform to allow coupling and uncoupling of the containment frame from the modular framework, and wherein the containment frame is provided with a containment compartment, configured to allow stacking of the consumable products below the working surface, and with an opening at the working surface, configured to arrange the consumable products at the working surface.

An apparatus for cup loading and unloading and a thromboelastography machine are provided. The apparatus for cup loading and unloading includes a base, a shaft, a movable cover, and a cup holder. The shaft is rotatably connected to the base about an axis of the shaft and has an end configured to engage with an inner cup. The movable cover is disposed around the shaft and slidably connected to the base along the axis of the shaft. The movable cover is provided with an elastic member therein. The cup holder is slidably connected to the base along the axis of the shaft and disposed below the base and the shaft. The cup holder has a cavity configured to engage with an outer cup, and the cavity has an open directed upward.

A method for determining a position of a rack on a rack placement unit of a laboratory handling system is presented. The rack is configured to carry a number of laboratory sample containers. The method comprises measuring a height profile of the rack, determining at least one corner region of the rack based on the measured height profile of the rack, and determining the position of the rack based on the determined at least one corner region of the rack.

A sample measurement apparatus according to one or more embodiments includes a processing unit that aspirates a sample inside a sample container and measures the sample; a transfer unit that includes a holder to hold the sample container, and that picks up the sample container from a rack capable of storing the sample containers at storage positions on a row and transfers the sample container to the processing unit; and a detection unit that is attached to the holder and is movable integrally with the holder, and that detects whether or not there is the sample container at each of the storage positions.

The purpose of the present invention is to enhance the throughput of an analysis device by efficiently delivering sample containers between an accommodation unit and measurement unit. This analysis device comprises a first holding part for holding a sample container to be delivered to a measurement unit and a second holding part for holding a sample container received from the measurement unit. The first holding part and second holding part are moved in an integrated manner (see FIG. 1B).