A method for collecting a sample for sample analysis includes drawing a first portion of the sample into a sample storage portion of a chromatography system while the chromatography system is in a first configuration. The method further comprising switching the chromatography system to a second configuration; sealing an end of a sample pick-up needle and draining a portion of a liquid from the second tubing; switching the chromatography system to a third configuration; drawing a second portion of the sample into the sample storage portion of the chromatography system; switching the chromatography system to an injection configuration; and fluidly connecting the sample storage portion to the chromatography column and supplying the first portion of the sample and the second portion of the sample from the sample storage portion to the chromatography column.

A sample injector is provided for a chromatography system that includes a mobile phase drive and a separation unit. The mobile phase drive is configured for driving a mobile phase through the separation unit, and the separation unit is configured for chromatographically separating compounds of a sample fluid in the mobile phase. The sample injector is configured for injecting the sample fluid into the mobile phase and comprises a needle and a handling unit configured for positioning the needle. Operating the sample injector includes providing a receptacle that includes a filtration unit configured for filtering a sample fluid comprised within the receptacle, moving the filtration unit within the receptacle in order to filter at least a portion of the sample fluid contained in the receptacle, operating the handling unit to position the needle into the receptacle, and aspirating a volume of the filtered sample fluid.

Methods of assessing purity of cytisine using gradient chromatography at multiple wavelengths is provided herein.

Methods of assessing purity of cytisine using gradient chromatography at multiple wavelengths is provided herein.

A sample delivery system for liquid chromatography is provided. The sample delivery system includes: a sample receptacle; a sample aspiration cannula for aspirating a sample located in the sample receptacle, the sample aspiration cannula being directed using a drive in a direction towards the sample receptacle so that a tip at a distal end of the sample aspiration cannula is immersed in the sample; and a guide element for the sample aspiration cannula provided above the sample receptacle, the guide element being designed as a washing device. The sample aspiration cannula can be retracted using the drive at least so far from the sample receptacle such that the distal end of the sample aspiration cannula may be cleaned in the washing device.

The present invention relates to a needle (1), wherein the needle (1) comprises a channel (12) extending through the needle (1), wherein the needle (1) comprises a needle tip (11), wherein the channel (12) comprises an opening at the needle tip (11), wherein the needle (1) defines an axial direction (x), wherein the axial direction (x) defines a distal direction and a proximal direction, wherein the needle tip (11) is a distal portion of the needle (1), and wherein the needle tip (11) comprises a first surface section (112) and a second surface section (111), wherein the first surface section (112) is arranged at a first angle (α) with respect to the axial direction (x) and the second surface section (111) is arranged at a second angle (β) with respect to the axial direction (x), wherein the first angle is different from the second angle. The present invention also relates to a corresponding apparatus, system and use.

The present invention relates to a needle (1), wherein the needle (1) comprises a channel (12) extending through the needle (1), wherein the needle (1) comprises a needle tip (11), wherein the channel (12) comprises an opening at the needle tip (11), wherein the needle (1) defines an axial direction (x), wherein the axial direction (x) defines a distal direction and a proximal direction, wherein the needle tip (11) is a distal portion of the needle (1), and wherein the needle tip (11) comprises a first surface section (112) and a second surface section (111), wherein the first surface section (112) is arranged at a first angle (α) with respect to the axial direction (x) and the second surface section (111) is arranged at a second angle (β) with respect to the axial direction (x), wherein the first angle is different from the second angle. The present invention also relates to a corresponding apparatus, system and use.

A controller (50) of a liquid chromatograph (1) is configured to execute, as an analysis operation in an analysis unit (3), a sample injection step of bringing a high-pressure valve (10) into a loading state, sucking a sample from a tip of a needle (12) to hold a sample in a sampling channel (2), then connecting the sampling channel (2) to an injection port (16) and bringing the high-pressure valve (10) into an injecting state, and supplying a mobile phase from a liquid supplier (6), thereby injecting a sample held in the sampling channel (12) into an analysis channel (4), and an analysis step of separating components of a sample injected into the analysis channel (4) in a separation column (14) by bringing the high-pressure valve (10) in the loading state and supplying the mobile phase from the liquid supplier (6) after the sample injection step is ended. In a case where at least a predetermined condition is satisfied, after the analysis step is ended, the controller is configured to execute, as the analysis operation, a system cleaning step of cleaning a liquid flowing route from the sampling channel (2) to the analysis channel (4) by connecting the sampling channel (2) to the injection port (16) and bringing the high-pressure valve (10) into the injecting state, and supplying the mobile phase and/or a cleaning liquid from the liquid supplier (6).

A sample dispatcher for a fluid separation apparatus includes a sampling path including a sampling volume, a sampling unit, and a retaining unit. The sampling unit receives a fluidic sample, and the sampling volume temporarily stores an amount of the received sample. The retaining unit receives and retains from the sampling volume at least a portion of the stored sample, and has different retention characteristics for different components of the sample. A switching unit is coupled to the sampling path, a sampling fluid drive, a mobile phase drive, and a separating device. In a feed injection configuration of the switching unit, the mobile phase drive, the separating device, and the sampling path are coupled together in a coupling point for combining a flow from the sampling fluid drive containing the fluidic sample retained by the retaining unit with a flow of the mobile phase from the mobile phase drive.

Methods and systems for sensing headspace vial presence are described herein. In one embodiment, a system can include a sample probe, a fluid source in fluid communication with the sample probe, one or more of a pressure sensor and a flow sensor in fluid communication with the sample probe, and a processor configured to: (a) receive a first set of signals from the one or more of the pressure and flow sensors, execute an ejection procedure to remove a sample vial from the sample probe, receive a second set of signals from the one or more of the pressure sensor and the flow sensor during step (b), (d) detect whether the ejection procedure is successful from the first set of signals and the second set of signals, and (e) in response to the detecting, initiate one or more actions selected from the group consisting of: a remediation and an alert.