A method of reading machine-readable labels on sample receptacles held by a sample rack. In the method, an absolute position of the sample rack is measured as the sample rack moves between first and second positions in a housing. During movement between the first and second positions, an image is acquired of a machine-readable label associated with each sample receptacle held by the sample rack. The image of each machine-readable label is thereafter decoded.

A laboratory system for a laboratory automation system is presented. The laboratory system comprises a sample container carrier. The sample container carrier is configured to carry a laboratory sample container and comprises a removal detector. The removal detector is configured to interact with the laboratory sample container to detect a removal of the carried laboratory sample container from the sample container carrier. Furthermore, the laboratory system is configured to determine based on the detected removal that a before valid logic assignment of the sample container carrier to the carried laboratory sample container is invalid.

A processing system includes a processing unit configured to process a cartridge, in particular a microfluidic cartridge, and is further configured to process a biological sample received in the cartridge. The processing unit includes a computing unit configured to compare input or read in sample data with input or read in first cartridge data in order to determine a compatibility of the sample with the cartridge. The computing unit is further configured to output a first error message in response to a determination of incompatibility between the sample and the cartridge. A method includes using the processing system to determine a compatibility between a sample and a cartridge.

A method is provided for associating an RFID tag to an RFID reader antenna in a laboratory device with a number N RFID reader antennae, the method including the steps of reading a unique identifier corresponding to each of a number M of RFID tag(s); registering received signal strength indications by each of the N RFID reader antennae of corresponding response signals from each RFID tag(s) and associating each RFID tag with the reader antenna having received the strongest received signal strength indication corresponding to the RFID tag. A laboratory device is also provided which is configured to perform the disclosed method.

Method for attaching a sample vessel rack (1, 1) in an apparatus (2, 2, 23), which apparatus comprises a slot (4, 24) into which the sample vessel rack is inserted, wherein magnetic attraction force is utilized in the attachment and correct positioning of the sample vessel rack (1, 1) into the slot (4, 24), where in the slot (4, 24) comprises a movable member (9, 9, 28, 35), which movable member is moved to a locking position with a magnetic attraction force when the sample vessel rack (1, 1) is in a correct position in the slot, and which movable member comprises at least one protrusion (11, 33) which protrusion sets itself in a notch (37) formed in the sample vessel rack in the locking position of the movable member. The invention also relates to such a sample vessel rack and an apparatus, and to a use of such a sample vessel rack.

Embodiments are directed to a combination of an automation system that continuously tracks the identity and positions of all of its pucks with a single sample identification station and covers/interlocks in order to provide sample chain of custody without the need to re-identify the sample at points of interaction (aspiration, de-capping, etc.). This eliminates the need to have sample identification stations at each interaction point. This reduction of hardware allows the system to be cheaper, smaller, and more reliable. It also allows not only the automation system, but also existing pre-analytical/analytical equipment connected to the automation system, to run more efficiently.

Embodiments of the present disclosure generally pertain to systems and methods for performing amplicon rescue multiplex polymerase chain reaction (arm-PCR). In one embodiment, the system comprises a processor and a reader coupled to a control element. The control element is configured to control the operation of the processor and the reader based on a variety of settings. The processor is configured to receive a self-contained cassette for performing PCR amplification of DNA and/or RNA obtained from an organic specimen. The processor engages with the cassette and manipulates reagents within the cassette in order to amplify and detect the DNA from the specimen. The processor also causes the cassette to deposit the DNA on a microarray within the cassette. The reader is configured to receive the cassette after it has been processed by the processor and to capture an image of the microarray for transmission to the control element as test data. The control element is further configured to analyze the test data received from the reader and to produce an output indicative of a comparison of the test data to predefined data.

A sample analyzing apparatus for performing an optical-based measurement on a sample includes a housing, a first light source, excitation optics, a first light detector, emission optics, and a monitoring system, all of which are disposed in the housing. The monitoring system is configured for monitoring a movable component disposed in the housing. The monitoring system includes one or more light sources for illuminating the movable component, and one or more light detectors for detecting light reflected from the movable component in response to being illuminated.

A sample measuring method of optically measuring a sample housed in a container in a sample measurement device, the method including: loading the container such that the container is shielded from light; starting to read information regarding a measurement to be performed on the sample in response to the loading the container; and measuring the sample based on the read information.

A rack for holding samples and various reagents, wherein the rack may be used for loading the samples and reagents prior to using the reagents. The rack accepts complementary reagent holders, each of which contain a set of reagents for carrying out a predetermined processing operation, such as preparing biological samples for amplifying and detecting polynucleotides extracted from the samples.