Obtaining sufficient suppression effect of channel diffusion and stably transferring solution are made possible even in a piping having an extremely small inner diameter used for an analysis apparatus such as an HPLC. A piping device for an analysis apparatus includes a piping equipped with a folded shape that suppresses inner channel diffusion, and a member directly or indirectly in contact with the piping from at least one side to support the piping to suppress deformation of the folded shape.

A method and apparatus involving the configuration of an open capillary channel for size-based separation of analytes is described. The open capillary channel contains numerous turns of defined angles separated by intervening linear or curvilinear segments of capillary tubing. The configuration of the channel allows analyte differentiation based on diffusion coefficients and thus separates analytes by size.

The invention relates to containers or bags for chromatographic media and methods of packing chromatography columns using such containers. The bags may be used for storing and/or transporting chromatographic media and can be inserted directly into the chamber of a chromatography column in readiness for

A chromatographic device includes a primary channel having a cross-sectional area and characteristic length such that analyte travel within the primary channel is substantially convective. A plurality of secondary channels each having a cross-sectional area and characteristic length such that analyte flow into and out of a secondary channel is substantially diffusive, each of the plurality of secondary channels having an entrance in fluidic communication with the primary channel wherein the entrance intersects the primary channel.

A laterally-fed membrane chromatography device for removing a solute from a fluid is provided. The device has a top plate, a middle plate and a bottom plate. The top plate has an inlet and a top channel for directing the fluid from the inlet towards a membrane stack. The middle plate houses the membrane stack. The membrane stack has a leading edge for receiving the fluid from the top channel, a trailing edge for distributing the fluid to the bottom channel, and is configured to remove the solute from the fluid as the fluid passes through the membrane stack. The bottom plate has a bottom channel and an outlet. The bottom channel is for directing the fluid from the membrane stack to the outlet. The top channel directs the fluid form the inlet over the leading edge in a direction that is transverse to the direction of flow of the fluid through the membrane stack.

A method of forming a frame around a membrane stack for a laterally-fed membrane chromatography device is provided. The method includes placing a membrane stack having one or more membrane layers on a bottom surface of body of a master mold, the body having opposed side walls and opposed end walls, the opposed side walls spaced apart by a distance greater than a length of the membrane stack, the opposed end walls spaced apart by a distance greater than a width of the membrane stack; placing a cap on the body of the master mold to enclose the membrane stack in the master mold, the cap having at least one opening for injecting a material into a space defined by the end walls of the master mold, the side walls of the master mold, end walls of the membrane stack side walls of the membrane stack, the bottom surface of the body and an inner surface of the cap; injecting the material into the space around the membrane stack; and curing the material to form a frame around the membrane stack.

A liquid chromatography (LC) column includes a wall having a length along a central axis from the inlet end to the outlet end, the wall enclosing a column interior and having a column radius relative to the central axis, the wall comprising a structured portion configured such that the column radius varies along the length; and a plurality of particles packed in the column interior, wherein at least some of the particles are in contact with the structured portion.

Disclosed is a separation column for micro gas chromatography, having superior separation performance and including a microchannel formed on a substrate and having a serpentine shape, and bumps formed on the surface of the microchannel, wherein the bumps are alternately disposed to face each other on the surface of the microchannel. In the separation column for micro gas chromatography, a sufficient pressure drop occurs, and thus an interaction between a gas mixture to be analyzed and a stationary phase in the column sufficiently takes place, whereby individual gas components are efficiently separated from the gas mixture, discharged from the column, and detected.

Obtaining sufficient suppression effect of channel diffusion and stably transferring solution are made possible even in a piping having an extremely small inner diameter used for an analysis apparatus such as an HPLC. A piping device for an analysis apparatus includes a piping equipped with a folded shape that suppresses inner channel diffusion, and a member directly or indirectly in contact with the piping from at least one side to support the piping to suppress deformation of the folded shape.

The invention relates to containers or bags for chromatographic media and methods of packing chromatography columns using such containers. The bags may be used for storing and/or transporting chromatographic media and can be inserted directly into the chamber of a chromatography column in readiness for use.