A vise for column, for attaching a plug to a column tube of a column for chromatography comprising the column tube and the plug to be attached to one end of the column tube, is provided. The vise comprises a column supporter configured to be able to support a part of the column for chromatography, a main body configured to be connected to the column supporter and extending from the column supporter by a predetermined distance, and a column presser configured to be supported at another end of the main body opposite to one end to which the column supporter is connected, and configured to be movable toward and away from the column supporter, and configured to be able to press the plug against the column tube.

A container system is disclosed, where the container system includes a housing. A chromatography cartridge is disposed in the housing. A structural support in the housing is configured to retain the chromatography cartridge within the housing. The housing is configured to withstand a certain amount of pressure generated inside the chromatography cartridge. The chromatography cartridge is disposed in the housing either in horizontal or in vertical position.

The present invention relates chromatography cartridge comprising a barrel to be sealed with a cap utilizing a seal member such as an O-ring. The barrel comprises barrel lip on the circular top surface of the barrel. The cap comprises a seal holder and a space to accommodate the seal member. Then the cap is mounted on the barrel an interior contact surface of the cap will contact the barrel lip and force the barrel lip to shear inwards. The barrel lip and the contact surface will form a first cartridge seal. The barrel lip will in turn contact the seal member which will contact a seal surface of the cap and the seal holder to form a second cartridge seal.

Methods and devices for the washing, extraction, and separation of a sample in a disposable chromatography cartridge (201) comprising a barrel (204) and a column (205), and especially including reinforcement to the column permitting high-pressure separation.

A parallel assembly of chromatography column modules, the assembly having one common assembly inlet and one common assembly outlet, each column module comprising a bed space filled with chromatography medium and each column module comprises integrated fluid conduits which when the column module is connected with other column modules are adapted to connect the bed space of the column module with the assembly inlet and the assembly outlet, wherein the total length and/or volume of the fluid conduit from the assembly inlet to one bed space together with the length and/or volume of the fluid conduit from the same bed space to the assembly outlet is substantially the same for all bed spaces and modules installed in the parallel assembly.

A method for reconstituting a lyophilized reagent contained within a reagent well comprises the steps of drawing a diluent into a pipette tip attached to an automated pipettor and dispensing the diluent into the reagent well containing the lyophilized reagent. The reagent well has an internal side wall, a bottom wall, and an open upper end and includes one or more retention features disposed about the periphery of the internal side wall and defining a central opening into the well that permits passage of the pipette tip into the reagent well. The one or more retention features are integrally formed with the internal side wall, and each of the one or more retention features extends over a portion of the lyophilized reagent, thereby retaining the lyophilized reagent within the reagent well.

A sorbent tube holder (100) for securing a sorbent tube (10) in position in a fluid-flow system, the sorbent tube holder (100) comprising: an mounting element (126) having first and second opposed ends (126a, 126b) which define a tube mounting axis (A-A); at least one fastener (128) in communication with the mounting element (126) for providing a releasable tube retaining force; at least one sorbent tube (10) engaged with the mounting element (126); and a holder frame (130) to which the mounting element (126) is attached to prevent or limit movement of the mounting element (126) perpendicular to the tube mounting axis. A method of preventing or limiting unintentional damage to a sorbent tube, and a portable tube holder are also provided.

The invention provides an apparatus and system for the separation and optional analysis of the components of a sample of material, the apparatus and system comprising a cartridge comprising: at least one sample inlet port, at least one resin inlet port and a multiplicity of reagent and purge fluid input ports which are fluidically connected via a multiplicity of control valves to a multiplicity of chromatographic columns which are fluidically connected together in series; and a multiplicity of outlet ports wherein each outlet port additionally comprises an outlet valve which is adapted to control the flow of fluid through said outlet ports; wherein each of said multiplicity of chromatographic columns is aligned with one of said multiplicity of outlet ports so as to allow for fluid flow from said column through said outlet port. The system optionally additionally facilitates the analysis of the components. The invention additionally provides a method for the separation of the components of a sample of material which comprises the use of the apparatus and system of the invention. The apparatus, system and method of the invention are advantageously applied to the separation and analysis of radioactive materials.

Disclosed is a method of supported liquid extraction (SLE), wherein adsorption of at least one analyte to a solid phase is performed in the presence of salt. The method may include contacting a sample with salt, adsorption phase such as diatomaceous earth and optionally a subsequent step of phospholipid depletion. Also disclosed is a cartridge including two compartments, for salt and adsorption phase, and optionally a third compartment including a phospholipid depletion phase.

A composition, method and device for the preparation of biological samples for subsequent LC-MS analysis using a combined and concurrent protein precipitation and solid phase extraction (SPE) process is described. Through an integrated combination of protein precipitation, filtration, and SPE using a novel zirconia-coated chromatographic media, interfering compounds, such as proteins and phosphate-containing compounds, are eliminated from the biological samples, affording a higher degree of analyte response during LC-MS analysis.