Provided is a container (10) including a base material (1) including a plurality of concave portions (2); a recognition unit (3) disposed on the base material and configured to recognize the base material; and a storage unit (4) disposed in a position other than a measurement region of the base material and configured to store information on biomaterials contained in the plurality of concave portions, wherein the recognition unit and the storage unit are allowed to correspond to each other.

A microfluidic device comprising: (a) a plate comprising a substrate, a plurality of electrodes, and a first layer of hydrophobic material applied over the plurality of electrodes; (b) a processing unit operably programmed to perform a method of pinning an aqueous droplet within the microfluidic device; and (c) a controller operably connected to a power source, the processing unit, and the plurality of electrodes. The method of pinning an aqueous droplet comprises: applying an electric field of a first polarity to an aqueous droplet located on the surface of the layer of hydrophobic material and having a first contact angle, to cause the droplet to maintain a second contact angle in the absence of the electric field, wherein the aqueous droplet contains a surfactant and the second contact angle is less than the first contact angle.

The present invention relates to encapsulated microfluidic packages and methods thereof. In particular embodiments, the package includes a device, a cradle configured to support the device, and a lid having a bonding surface configured to provide a fluidic seal between itself and the device and/or cradle. Other package configurations, as well as methods for making such fluidic seals, are described herein.

A tissue holder cap for covering a tissue holder includes a cover having a perimeter, the cover having an outer surface and an inner surface opposite from the outer surface. The cover includes a central portion having an opening configured for receiving a central post of the tissue holder, a first latch extending from the perimeter of the cover, and a second latch extending from the perimeter of the cover, circumferentially spaced apart from the first latch. The cover also includes a first protrusion configured to engage the post of the tissue holder. When the first protrusion engages with the post, each of the first latch and the second latch automatically aligns with one or more of a plurality of tabs on located on a circumferential sidewall of the tissue holder to thereby securely fasten the tissue holder cap onto the tissue holder.

The present disclosure relates to a method for optimizing a measurement rate of a field device in a measurement system. The measurement system includes at least one second field device in which a measurement variable of the field device is correlated with the measurement variable of the second field device. The method determines a respective specific correlation pattern between the first measurement variable and the second measurement variable based on a learning phase. This makes it possible to check the measured values from the second field device for the correlation pattern during normal measurement operation and to change the measurement rate of the field device during the corresponding time window. This makes it possible to increase the service life and/or availability in the process installation.

A sensing cell culture vessel having one or more sensors on or in the vessel is configured to collect readings of various parameters or characteristics of a cell culture located within the sensing cell culture vessel and transmit the readings. The sensing cell culture vessels may be accompanied by a sensing plate having means for reading the one or more sensors and transmitting the one or more sensors to a server hosting electronic lab notebook for analyzing and storage of the readings. Sensing plates may further be equipped with cameras for imaging cell cultures located in the sensing cell culture vessels and transmitting the images to the server hosting the electronic lab notebook for analyzing and storage of the images. Embodiments of the invention allow for the continuous and automatic monitoring of cell cultures.

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).

Methods and apparatuses relating to measuring sample parameters and cell parameters (e.g., cell size, cell shape) are provided herein. The present disclosure provides additional methods, systems and techniques for improving osmotic gradient generating systems for vise in technologies to accurately determine red blood cell volume and the osmolality at which cells achieve a maximum volume.

Chemical delivery systems, device and methods are provided. A chemical delivery system may include a vessel and a chip. The vessel may include a groove configured to hold a solution. The groove includes an open surface, the open surface having a first surface area. The solution includes a target material. The chip includes a first side, a second side opposing the first side, and a bottom side. The chip includes one or more chambers configured to hold one or more chemicals, the one or more chambers including a bottom surface having a second surface area. The second surface area is greater than the first surface area. When one of the one or more chambers is positioned over the groove, the respective chemical in the chamber moves into the solution in the groove. The system increases the ease, stability, and reliability of a chemical delivery process.

The present invention has: a step for heating a resin or a metal in a state in which the resin or metal is sandwiched by a mold provided with a projection that is constituted from an elastic body having a heat resistance temperature higher than the temperature at which the resin or the metal softens, and a support body which is larder than the mold and which is softened by heat at a higher temperature than the resin or the metal, while a force is applied to the mold in the direction toward the resin or the metal.