The present disclosure provides apparatuses, systems, and methods involving a spotter for depositing a substance on a submerged surface. The spotter comprises an outlet cavity defined at least in part by a spotting orifice, a first opening, and a second opening. The spotter also comprises a first conduit fluidly coupled to the first opening and a second conduit fluidly coupled to the second opening. The spotter is adapted so that fluid flowing through the first conduit and the second conduit is communicated among the first opening, the second opening, and a submerged deposition surface when the sealing orifice is sealed against the submerged deposition surface to form a deposition spot on the submerged deposition surface. The submerged deposition surface is within a liquid such that the liquid covers the deposition spot upon removal of the orifice from the deposition surface.

According to one embodiment of the present invention, a tube opening and closing device capable of opening and closing a lid of a tube and comprising a container, a lid coupled to the container so as to enable the container to be blocked, and a joint part for connecting the container and a first side of the lid comprises: a tube supporting rack having a plurality of openings formed on one surface thereof, wherein the containers of the tubes can be inserted into each of the plurality of openings; an opening and closing part positioned at an upper part of the tube supporting rack, rotating around a first rotary shaft and having a coupling groove in which a second side of the lid, which faces the first side of the tube, can be accommodated; and a driving part for rotating the opening and closing part, wherein the lid can be opened and closed with respect to the container through the rotation of the opening and closing part.

A container for taking up and dispensing a substance includes a glass tubule, a glass punch that slides adjustably in the glass tubule, forming a seal, and a glass sleeve closed on one side, in which the glass tubule is accommodated. The glass sleeve is shorter than the glass tubule, so that the glass tubule projects out of the glass sleeve. The glass punch is longer than the glass tubule and projects out of the glass tubule at the end situated outside of the glass sleeve. The glass punch does not fill the glass tubule completely, so that a substance chamber remains in the region of the end of the glass tubule situated within the glass sleeve.

An on-demand vapour generator includes a vapour chamber configured to produce a vapour and a vapour absorption assembly configured to receive flows of vapour from the vapour chamber. The vapour absorption assembly includes a first vapour-permeable passage having a passage outlet and at least one second vapour-permeable passage that is closed. When vapour absorption assembly receives a flow of vapour from the vapour chamber, the flow of vapour passes through the first vapour-permeable passage to the passage outlet at least substantially without absorption of vapour from the flow of vapour. However, when a flow of vapour is not received from the vapour chamber, vapour entering the vapour absorption assembly from the vapour chamber passes into the first vapour-permeable passage and the at least one second vapour-permeable passage and is at least substantially absorbed.

The present invention relates to an apparatus for sample taking from a fluid-conducting system, wherein the apparatus has at least one adapter which comprises at least one septum and at least one cannula displaceable relative to the septum, wherein the cannula is displaceable such that it penetrates the septum in a sample taking position and does not penetrate the septum in a flushing position; and wherein the adapter has at least one flushing region for a flushing medium which is arranged such that it is in fluid communication with the inner space of the cannula in the flushing position of the cannula; and wherein the apparatus has at least one receiving region having locking means for the fluid-conducting system by which the fluid-conducting system is fixable in a defined position relative to the adapter. The present invention furthermore relates to a blood treatment device and to a method for taking a sample from a fluid-conducting system.

Disclosed is a solid-liquid separation method including: sucking a suspension containing particles, through an opening formed at a leading end of a suction nozzle, into the suction nozzle; allowing at least a part of the particles contained in the sucked suspension, to sediment to be clogged in the suction nozzle; and ejecting a liquid inside the suction nozzle, through the opening of the suction nozzle clogged with the particles.

A support that comprises a plate having a first side and a second side opposed to the first side. The plate has a sample section including bottle-receiving members defined in the first side and configured for holding the bottles in a fixed position relative to the plate, and first conduit-receiving openings extending from the first side to the second side for receiving conduits extending from the bottles. The plate has a manifold section including second conduit-receiving openings extending from the first side to the second side for receiving the conduits. The plate has a channel section including channels defined in the second side and extending between the first conduit-receiving openings and the second conduit-receiving openings for receiving the conduits therein. The support may be used for example on a shaker. A method for retaining bottles and conduits connected to the bottles is also discussed.

An on-demand vapor generator includes a vapor chamber configured to produce a vapor and a vapor absorption assembly configured to receive flows of vapor from the vapor chamber. The vapor absorption assembly includes a first vapor-permeable passage having a passage outlet and at least one second vapor-permeable passage that is closed. When vapor absorption assembly receives a flow of vapor from the vapor chamber, the flow of vapor passes through the first vapor-permeable passage to the passage outlet at least substantially without absorption of vapor from the flow of vapor. However, when a flow of vapor is not received from the vapor chamber, vapor entering the vapor absorption assembly from the vapor chamber passes into the first vapor-permeable passage and the at least one second vapor-permeable passage and is at least substantially absorbed.

An electronic dosing drive comprising a support structure, a threaded spindle with an external thread for driving a plunger, at least one first guide element is firmly connected, and is guided parallel to the threaded spindle on a second guide element, a spindle nut having an internal thread is engaged with the external thread of the threaded spindle, an electric drive motor having a motor shaft is coupled with the spindle nut and is attached to the support structure, an electric control apparatus is connected to the electric drive motor, where the external thread of the threaded spindle has multiple threaded areas that are separated from each other by first flattenings on their circumference extending in the longitudinal direction, and the first flattenings have guide areas that abut the core diameter of the internal thread of the spindle nut.

A reaction processor includes: a reaction processing vessel placing portion for placing a reaction processing vessel provided with a channel into which a sample is introduced; a temperature control system, which controls the temperature of the channel in order to heat the sample inside the channel; and a liquid feeding system, which controls the pressure inside the channel of the reaction processing vessel in order to move the sample inside the channel. The liquid feeding system maintains the pressure inside the channel to be higher than the atmospheric pressure in the surrounding of the reaction processing vessel, more preferably 1 atm or higher, during a reaction process of the sample.