A chromatography column has a retaining plug permanently fixed to an upstream end of the column and blocks one end of the bore through the column. The plug has a fluid passage therethrough. An upstream end of the passage is preferably but optionally larger in diameter than a downstream end of the passage. An upstream porous member upstream of the retaining plug is held by an upstream end cap and urged toward the plug. Chromatographic media extends from the upstream porous member, through the passage in the retaining plug, to a downstream porous member held by a downstream end cap. The media between the retaining plug and the downstream porous member are under compression to form a bed of packed media.

No filter between retaining member and upstream end of the packed chromatographic bed

A method and a slurry tank system for transferring chromatography media slurry from a slurry tank (3) to a chromatography column (9), said method comprising monitoring the content of slurry in the slurry tank (3) during the transferring and controlling the transferring of the slurry to the column (9) in dependence of the content of slurry in the slurry tank (3).

A method of making and loading a chromatography column includes selecting a column tube having an appropriate elasticity, and inner diameter and length, selecting appropriately sized flow distributors, a second flow distributor having a diameter that is larger than the inner diameter of the tube, permanently securing a first flow distributor to a first end of the tube, loading packing medium into the tube, inserting the second flow distributor into a second end of the tube to drive the second flow distributor into the tube to form a sealed chamber within the tube, adjusting the longitudinal position of the second flow distributor within the tube by applying a force to the second flow distributor until it reaches a desired location within the tube, and/or forcing liquid into the chamber to move the second flow distributor and permanently securing the properly positioned second flow distributor within the tube.

The invention relates to a chromatography column frame comprising at least two legs, a support arrangement connected to said at least two legs, and a holder means connected to said support arrangement. Said holder means is arranged to releasably hold an adaptor rod of a chromatography column, so that the adaptor rod is prevented to move in a horizontal direction and so the adaptor rod is allowed to move in a vertical direction. The invention also relates to method of conducting maintenance on and packing of a chromatography column.

The present invention provides novel chromatographic materials, e.g., for chromatographic separations, processes for its preparation and separations devices containing the chromatographic material; separations devices, chromatographic columns and kits comprising the same; and methods for the preparation thereof. The chromatographic materials of the invention are chromatographic materials comprising having a narrow particle size distribution.

The present invention relates generally to a sample processing device, such as a microfluidic device, comprising a substrate, wherein the substrate comprises a plurality of channels configured to transport a fluid, and wherein the plurality of channels are substantially coated with lubricin, or a functional variant thereof. Also disclosed herein are methods of manufacturing such devices, methods of preventing fouling of a channel in a device using lubricin, or a functional variant thereof and methods of controlling the electrokinetic flow of an analyte through a channel that is substantially coated with lubricin, or a functional variant thereof. Also disclosed herein is chromatographic material for the electrophoretic and/or chromatographic separation of an analyte, wherein the chromatographic material is substantially coated with lubricin, or a functional variant thereof.

Disclosed is a chromatographic separation column assembly (100) comprising a column cylinder (120) having a cylinder wall (126) including an inner wall surface (124) partially defining a column volume (50), and a column component (110/130) insertable into to the cylinder (120), wherein at least an edge region (113/133) of the column component is intended to be in contact or adjacent a part of the inner wall surface (124) in use, the edge region and the contacting or adjacent part of inner wall surface each being formed from a compatible heat fusible material or materials, and wherein at least the cylinder wall in the area of the contacting or adjacent part of the inner wall is formed from a material which allows transmission of the light energy needed to cause said fusing of the adapter plate edge region to the inner wall surface.

The present invention relates to axial flow chromatography columns, methods for separating one or more analytes in a liquid by the use of such columns, and systems employing such columns. The column comprises a first port and a second port, the first port and said second port being at essentially the same level or elevation above the level of the bed space on the chromatography column.

Novel materials for chromatographic separations, processes for their preparation, and separation devices containing the chromatographic materials. In particular, hybrid inorganic/organic monolith materials comprising a polymerized scaffolding nanocomposite (PSN), wherein the nanocomposite contains a scaffolding functionality capable of chemically interacting with a surface of a second material are described. The hybrid inorganic/organic materials have enhanced wall adhesion and increased resistance to shrinkage as compared to prior art monolith materials. The improved adhesion of the monoliths enable the preparation of capillary columns with an internal diameter (I.D.) ?50 ?m.

Supercritical fluid extraction can experience problems of prolonged extraction times and undesired elution of target components of a trap sample. To resolve these problems, a sample is stored in a container (125) disposed upstream of a back-pressure control valve (140). A mixed fluid of carbon dioxide in a supercritical state and a modifier is introduced into the container, and a component contained in the sample is extracted. The extracted component is introduced into a trap column (135) together with the carbon dioxide and the modifier and collected in the trap column. The trap column is loaded with polymer beads as a filler to securely collect an extracted component in the trap column, even when the modifier in the supercritical fluid is increased.