A grease testing device for testing oil separation from a grease sample includes a container defining a grease compartment for holding the grease sample. A grease shearer is at least partially positioned in the grease compartment and moves in the grease compartment to shear the grease sample in the grease compartment. A motor is operatively connected to the grease shearer to move the grease shearer in the grease compartment to shear the grease sample. A drain is arranged with respect to the grease compartment to receive oil separated from the grease sample from the grease compartment.

Automated test instruments electronically determine and/or obtain cell availability of cells of a holding structure in an incubated test chamber and for each of a plurality of open and available cells and electronically identify neighboring cells, electronically determining whether each of the identified neighboring cells are occupied or empty and, if occupied, electronically evaluating at least one of a test status or a time from load of a specimen container held therein. The instruments then electronically rank each of the plurality of open and available cells based at least in part on whether the identified neighboring cells are occupied or empty and the at least one of test status or time from load of the occupied cells of the identified neighboring cells. The loading mechanism is then directed to load an incoming specimen container into a selected one of the open and available cells based on the ranking.

Provided herein is a biological detection system and method of use wherein the biological detection system comprises at least one mixer or liquid bridge for combining at least two liquid droplets and an error correction system for detecting whether or not proper mixing or combining of the two component droplets have occurred.

Droplet-based methods of analysis. In an exemplary method, a device having a port connected to a chamber may be selected. A sample-containing fluid may be placed into the port. A pressure differential may be created that drives the sample-containing fluid from the port to the chamber and separates the sample-containing fluid into droplets. A two-dimensional monolayer of the droplets may be formed in the chamber. At least a portion of the monolayer may be imaged.

Included are: a main body including an installation part in which a cartridge housing a liquid for treating a test substance contained in a specimen is installed and a detector configured to detect the test substance treated with the liquid within the cartridge installed in the installation part; a lid part arranged rotatably on the main body about a shaft so as to open and close the installation part; a biasing part biasing the lid part in an opening direction; and a plurality of regulators each generating resistance against a biasing force in the opening direction at different timing during an opening motion of the lid part.

In some aspects, automated rapid antimicrobial susceptibility testing systems for performing a multi-assay testing sequence can include an automated incubation assembly having a nest assembly adapted to house at least one test panel having a plurality of wells for receiving a sample comprising microorganisms originating from a clinical sample, the incubation assembly facilitating incubation of one or more test panels in order to undergo the multi-assay testing sequence; a robotic handling assembly configured to accept one or more incoming test panels and move them to and from the incubation assembly for incubation between each assay of the multi-assay testing sequence; an automated liquid handling assembly configured to exchange one or more fluids in the plurality of wells of the test panels; and an optical assembly for interrogation and readout of each assay of the multi-assay testing sequence being performed in the plurality of wells.

A fieldable processing and detection apparatus for automatically collecting, preparing, Identifying and quantifying environmental DNA in samples of a material of Interest. Environmental samples of materials of interest are combined with polymerase chain reaction (PGR) reagents that are selectively compatible with the material of Interest and mixed. Various processing methods may be employed at the discretion of the operator and include droplet concentration, thermoprofiling, particle separation and other techniques or methods that are compatible with and suitable for the specific material of interest and the testing environment The system will selectively lyse cells, breaking down the cell membrane via mechanical disruption, ultrasound, thermocycling, or other suitable techniques and thereafter quantify the preamplified concentration of target nucleic add sequences using digital quantification.

A laboratory system and a method for separating interfering substances contained in test samples is presented. The laboratory system comprises separation vessels comprising solid surfaces and capturing molecules which are immobilized on the solid surfaces. The capturing molecules of the separation vessels are configured to bind interfering substances of laboratory tests of different analytical methods.

The invention, in part, includes systems for conducting continuous directed evolution in a plurality of sample and methods of using the systems. The invention, in part also provides systems for evaluating the suitability of diverse engineered cells to accomplish directed evolution and methods of use of such systems.