A system for processing samples includes sample supplies to supply samples, a channel connected to the sample supplies, a device connected to the channel to collect first information about the samples, and a controller. The controller is to perform a cycling operation: controlling a first sample supply of the sample supplies to supply a first sample in the first sample supply to the channel, controlling the device to collect the first information about the first sample in the channel, storing data associated with the first sample, including the first information about the first sample, evaluating the data against preprogramed thresholds and implementing the addition of water, chemical, product or recycled product, and controlling the first sample supply to discharge the first sample in the channel into the first sample supply. The controller is to repeat the cycling operation for a second sample.

A method of reading machine-readable labels on sample receptacles. In the method, a sample rack is moved between a first position and a second position within a housing, where the sample rack supports a plurality of sample receptacles, and each sample receptacle has a machine-readable label. An absolute position of the sample rack is measured as the sample rack moves between the first and second positions. An image of the machine-readable label associated with each sample receptacle is acquired as the sample rack moves between the first and second positions. Finally, the acquired image of each machine-readable label is decoded.

A chromatography lab system comprising a cooling compartment arranged to hold both fraction collector devices and sample containers, whereby the cooling compartment comprises an identifying device which is arranged to identify the fraction collector devices such that fractions from the chromatography are collected only in the fraction collector devices.

A sample vessel assembly, comprising a base member including a base flange having first and second opposing surfaces, first and second sides intersecting with one another; and a first sidewall extending from the first surface at a distance from the first and second sides; and a lid member, including: a lid flange having third and fourth opposing surfaces, third and fourth sides intersecting with one another; and a second sidewall extending from the third surface at a distance from the third and fourth sides, the second sidewall engageable with the first sidewall such that the first surface of the base flange and the third surface of the lid flange are in an opposing spaced-apart relationship with one another and such that the first and second sidewalls cooperate with one another to define a sample chamber. Further disclosed is a method for automated analysis of samples in a sample vessel assembly.

The present invention provides devices and systems for use at the point of care. The methods devices of the invention are directed toward automatic detection of analytes in a bodily fluid. The components of the device are modular to allow for flexibility and robustness of use with the disclosed methods for a variety of medical applications.

The present invention provides devices and systems for use at the point of care. The methods devices of the invention are directed toward automatic detection of analytes in a bodily fluid. The components of the device are modular to allow for flexibility and robustness of use with the disclosed methods for a variety of medical applications.

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.

A method for setting at least one parameter of a handheld power tool includes recording at least one first characteristic variable using at least one internal sensor unit or an external sensor unit and transmitting the first characteristic variable to at least one of (i) an internal data processing unit and (ii) an external data processing unit. The method further includes processing the first characteristic variable into at least one of (i) at least one first parameter output and (ii) an output of a combination of parameters and transmitting using a communication unit to at least one of (i) an internal open-loop and (ii) a closed-loop control unit. The method further includes calculating from the first parameter output at least one operating parameter of the handheld power tool and setting it on the handheld power tool.

A method for handling a sample tube containing a biological sample is presented. A tube label can be attached to the sample tube. The tube label can carry tube data. The tube data can comprise at least geometric tube data descriptive of at least one geometric property of the sample tube. At least the geometric tube data can be read from the tube label by a reader device. At least the geometric tube data from the reader device can be transmitted to a processing device. The processing device for handling the sample tube can be controlled in accordance with the at least one geometric property described by the read geometric data.

A method for automated microscopic analysis wherein the test protocol is obtained from interrogatable data affixed to each microscope slide. The method further comprises the algorithms that implement the test protocol.