A container (1) for biologic samples has a lower receptacle (2), an upper receptacle (3) for a toxic liquid (LF) or considered as such, having a radial ring (63), and a connecting sleeve (4) with a circumferential rim (54) and a transversal septum (40), provided with a central vent opening (55) and with a plurality of transfer openings (51) for the transfer of toxic liquid (LF). The toxic liquid (LF) is sealed between the upper receptacle (3) and the transversal septum (40) before unscrewing the upper receptacle until its radial ring (63) touches the circumferential rim (54). When unscrewing the upper receptacle (3), the toxic liquid (LF) reaches and passes through the plurality of transfer openings (51), and air contained in the lower receptacle (2) flows into the upper receptacle (3) through the central vent opening (55), without any exit of gases and liquids from the container (1).

A system for performing biological reactions is provided. The system includes a chip including a substrate and a plurality of reaction sites. The plurality of reaction sites are each configured to include a liquid sample of at most one nanoliter. Further, the system includes a control system configured to initiate biological reactions within the liquid samples. The system further includes a detection system configured to detect biological reactions on the chip. According to various embodiments, the chip includes at least 20000 reaction sites. In other embodiments, the chip includes at least 30000 reaction sites.

A closure and a container assembly are disclosed. The closure includes a first visual identifier and a second visual identifier, wherein the second visual identifier is different from the first visual identifier. The first visual identifier may be a first color, and the second visual identifier may be a second color. At least one of the first and/or second visual identifier may include a fluorescent compound having a characteristic fluorescent spectra. The first visual identifier and the second visual identifier may be provided on the annular skirt of the closure. The fluorescent compound may be provided on at least one of the closure and the container assembly and can be used to facilitate automated visualization of the fluorescent compound under fluorescence excitation light.

A fluid handling unit is configured for handling a fluid contained or to be contained in a receptacle bearing a marking. The unit includes a needle having an elongated shape with an open end and for aspirating the fluid from the receptacle and/or dispensing the fluid into the receptacle. The fluid handling unit further includes a needle drive for positioning the needle with respect to the receptacle, a detection unit for detecting the marking of the receptacle, and a control unit. The control unit is configured for analyzing the detected marking for determining at least one feature that is part of the marking or the marking itself, determining a target position based on the detected at least one feature, and operating the needle drive to position the open end of the needle relative to the determined target position.

The present invention relates to methods for determining biomarker signatures that are relevant for detecting a disease in a patient or identifying altered abundance of cells within the patient. Also disclosed are methods for detecting a disease or altered cell type abundance in a patient by measuring said biomarker signature for at least one cell type.

The invention relates to an apparatus for analyzing heterogeneously catalyzed reactions comprising at least one reactor (3) through which a particulate catalyst flows and at least one reactant feed, wherein arranged downstream of each reactor (3) is a separation apparatus (17) for separating the particulate catalyst from a reaction product comprising condensable gases and arranged downstream of the separation apparatus (17) is a liquid separator (31) for separating liquid constituents from the reaction product, wherein the liquid separator (31) comprises a metallic tube (103) and a deflection body (119), wherein the metallic tube (103) is closed at its ends and the deflection body (119) is accommodated in the metallic tube (103) and the metallic tube (103) comprises a side feed (135) at a first end (105) and a gas outlet (113) at a second end (107) and the gas outlet (113) is connected to at least one sample vessel (37). The invention further relates to a process for analyzing heterogeneously catalyzed reactions in the apparatus.

A biopsy container assembly having a container with a lower chamber suitable for containing a buffer liquid, and a cap coupled with the container. The cap being provided with a chamber that contains a biopsy liquid sealed by a membrane, and a crown with a toothing-suitable for tearing off the membrane of the cap. The crown is also suitable for being disposed in the container in an initial position, wherein the toothing is directed downwards in order not to interfere with the membrane of the cap when the cap is closed on the container, and in an operating position, wherein the toothing is directed upwards in order to tear off the membrane of the cap when the cap is closed on the container.

Methods and kits for assessing the propensity of developing urolithiasis, kidney disease, or bladder disease in pets; and compositions to treat such conditions are described herein.

Devices, systems, and methods for imaging samples. In some examples, a device includes at least two basins for holding a liquid medium, the at least two basins including a sample chamber and a reservoir. The device includes a wedge between the sample chamber and the reservoir, and the wedge protrudes into the sample chamber and defines a space between the wedge and a bottom of the sample chamber. The space is sized for holding one or more biological samples. The device is formed to define a flow channel between the sample chamber and the reservoir, and the flow channel is shaped to allow the passage of the liquid medium from the sample chamber and the reservoir and to block passage of the one or more biological samples between the sample chamber and the reservoir.

A system is disclosed for measuring head framing and tip straightness in a liquid handler. The present system uses a test plate, having an upper surface formed of clay or other impressionable material. The test plate may be placed at a liquid handling station. Pipette tips may then be loaded onto the head, and the head positioned at the station including the test plate. The head may be actuated in the z-direction so that the tips leave an imprint in the upper surface of the test plate. The imprint of the tips on the test plate may then be analyzed using any of a variety of measurement techniques to determine head framing alignment or misalignment.