A sample management device which comprises a source flow path in which a fluidic sample can flow, a volume flow adjustment unit configured for adjusting a volume flow of the fluidic sample to be branched off from the source flow path at a fluidic coupling point, and a fluidic valve fluidically coupled with the source flow path and with the volume flow adjustment unit, wherein the fluidic valve is switchable into a branch off state in which the fluidic coupling point is established within the source flow path to branch off an adjustable volume of the fluidic sample from the source flow path via the fluidic coupling point while a flow of the fluidic sample in the source flow path continues.

The present disclosure relates to methodologies, systems, and apparatus for controlling fluid flow within a chromatography system. The chromatography system includes a mobile phase pump configured to pump a liquid mobile phase through a column and a restrictor positioned downstream of the column and upstream of a detector. The system also includes a valve configured to operate in at least two positions. In a first position, the valve is configured to direct the output of the column to bypass the valve and reach the detector, while in the second position the valve directs the output of the column to waste.

The disclosure relates to a system for liquid sample introduction into a chromatography system. The system includes a metering device for drawing up the liquid sample, a first multi-port valve in fluid communication with a first end of the metering device and the liquid sample, a second multi-port valve in fluid communication with a second end of the metering device and a chromatography column, and a pump in fluid communication with the second multi-port valve and a mobile phase. When the valves are in a first position the metering device draws up the liquid sample filling a portion of the metering device. When the valves are in a second position, a remaining portion of the metering device is filled with the mobile phase thereby mixing with and pressurizing the liquid sample. When the valves are in a third position, the mixed and pressurized sample flows to the chromatography column.

A valve switching cassette for selectively interconnecting components of a bioprocess installation, wherein the valve switching cassette comprises at least one fluid flow system of ports and fluid lines, which fluid flow system includes primary ports, communicating with primary fluid lines, and secondary ports, communicating with secondary fluid lines, wherein the valve switching cassette comprises an array of switchable valve units for selectively interconnecting the primary fluid lines with the secondary fluid lines via transfer fluid lines. It is prosed, that the valve switching cassette comprises a transfer plate with apertures and an elastically deformable membrane structure on each flat side of the transfer plate, that at least part of the primary fluid lines and secondary fluid lines are extending between the transfer plate and one of the membrane structures and that the transfer fluid lines are at least partly provided by the apertures.

A high-duty-cycle liquid chromatography system that includes two or more columns that are configured to alternatingly be in a productive phase or a regeneration phase, wherein simultaneously one of the columns is in a productive phase and the other columns are in the regeneration phase. Additionally, the system includes a mobile phase gradient delivery pump, an isocratic pump, two or more gradient storage chambers, and two or more valves that are each independently coupled to a column and a gradient storage chamber. The column in the productive phase has a solution containing a sample which is pushed through the column, collected at a detector, and analyzed. The column in the regeneration phase is being prepared for the next productive phase.

A variable fluidic restrictor of a liquid chromatography system including a stator body, the stator body include a plurality of fluidic channels located within the stator body, wherein each fluidic channel of the plurality of fluidic channels includes a restrictor element, wherein a flow of a fluid through the variable fluidic restrictor is selectively restricted based on a position of an external element coupled to the stator body is provided. Furthermore, an associated method is also provided.

A liquid chromatograph (1) includes a liquid-sending unit (20) for sending a mobile phase from a reservoir (11) to a column (14) through a tube (12) at a predetermined pressure. The unit (20) includes a pump (21) having a suction port (211) connected to the reservoir and an ejection port (212) connected to the tube directly or via another pump. A check valve (232) is provided for the ejection port. For the precompression process for opening this valve, a pressure application controller (27) controls the pressure applied to the mobile phase within the pump, based on the compressibility of the mobile phase and the amount of compression of the inner wall of the pump resulting from the pressure application, so as to reach the pressure at which the check valve opens before the mobile phase suctioned from the suction port is to be ejected from the ejection port.

A liquid chromatograph includes: a liquid meter that measures a liquid amount of a mobile phase stored in one or more mobile phase containers; and a notification unit that notifies an operator of the liquid amount of the mobile phase in each of the one or more mobile phase containers measured by the liquid meter. According to such a liquid chromatograph, when the operator replenishes the mobile phase to the mobile phase container, it is not necessary to visually measure the liquid amount of the mobile phase or manually input the value to the control device, so that it is possible to reduce the workload of the operator regarding the liquid amount management of the mobile phase.

Certain embodiments described herein are directed to chromatography systems that include a microfluidic device. The microfluidic device can be fluidically coupled to a switching valve to provide for selective control of fluid flow in the chromatography system. In some examples, the microfluidic device may include a charging chamber, a bypass restrictor or other features that can provide for added control of the fluid flow in the system. Methods of using the devices and methods of calculating lengths and diameters to provide a desired flow rate are also described.

A configurable injector for injecting a fluidic sample in a separation path of a sample separation apparatus includes a sample accommodation volume for accommodating the fluidic sample to be injected into the separation path, a valve arrangement fluidically couplable with the separation path, fluidically coupled with the sample accommodation volume, and being controllable for injecting the fluidic sample into the separation path, an input interface configured for receiving input data indicative of an injection profile of an injector to be emulated by the configurable injector, and a control unit configured for controlling the configurable injector, in particular the valve arrangement, so that the configurable injector is operated in accordance with the injection profile to thereby emulate the injector to be emulated.