A chromatography and synthesis column that includes a main tube, a plurality of lower media ports, and an internal groove. The internal groove is formed in an interior surface of the main tube and selectively provides an internal flow path between each of the internal lower media ports. This, in turn, facilitates quick and easy maintenance of the internal lower media ports and other components of the chromatography and synthesis column.

The present invention discloses methods for packing chromatography columns using dual-purpose valve assemblies. The key components of the dual-purpose valve comprise of the following; the inlet port (224) which sits on the first adaptor (212), the hollow nozzle (320) which passes through the first adaptor (212) cavity and is closed on the bottom end, and the internal movable plug (322). Different components of our de-vice work in way that the mobile phase and analyte(s) distribution is not blocked in the centre of the column, allowing for a uniform and homogeneous fluid distribution. This simple yet novel design offers uniform fluid distribution, stable packed bed, eliminates any void volume, and prevents bacterial contamination/growth. Ease of use, scalability, ease of cleaning, cost-efficiency and fine-tuning packing conditions such as pressure are key features of this invention.

In this invention, chromatography is integrated on a centrifugal platform to enable low-cost automated purification. Differing from the traditional chromatography method, purification and separation of a centrifugal compound collecting platform disclosed in the present invention mainly uses a centrifugal force to drive the fluid to flow outward in the radial direction when the motor rotates. The compounds to be separated react with the column packing during the flow, and the compounds with different polarities in the sample are gradually separated. The flow of the fluid can be governed by the motor and the geometry of the fluidic design such that compounds with different characteristics can be separated and collected in different collecting chambers.

Chromatography apparatus and methods are described, especially for expanded bed adsorption. A column tube has a process fluid input device at the bottom and a movable piston in the top. The piston is enclosed in the column by a cover plate. The piston body has an inflatable seal, and is connected by a frame to a contact ring which carries another inflatable member to contact the tube wall. Process fluid leaves the operating volume through an opening of the piston and flexible hose, through the enclosed space and out through the cover plate. The space above the piston can be pressurised to control piston movement. The contact ring maintains piston alignment. The inflatable seals are used to fix the piston in position, allow it to slide or allow washing. The piston outlet may include a vortex-inhibitor. Bed and piston levels may be monitored by ultrasound sensors.

A chromatography and synthesis column that includes a main tube, a plurality of lower media ports, and an internal groove. The internal groove is formed in an interior surface of the main tube and selectively provides an internal flow path between each of the internal lower media ports. This, in turn, facilitates quick and easy maintenance of the internal lower media ports and other components of the chromatography and synthesis column.

The present invention relates to a nozzle assembly 200 for a fraction collection unit 120 configured to collect one or more fluid samples, said nozzle assembly comprising a conduit adapter 210 configured to fluidly couple to a conduit, a nozzle body 220, wherein the nozzle body comprises at least a nozzle part 221 configured to release drops of the one or more collected fluid samples at a tip 223 of the nozzle part 221, and an interface part 222 configured to mechanically couple the assembly 200 to the fraction collection unit, wherein the assembly, when the conduit adapter 210 is attached to the nozzle body 220, forms a fluid channel from an inlet 219 of the conduit adapter 210 to the tip 223 of the nozzle part 221.

There is provided an integrated system for liquid separation, such as LC, CE, affinity chromatography, and ion exchange chromatography, comprising a column and end-fittings embedded in a plastic material, such as a thermoplastic polymer. The system may further comprise an electrospray emitter directly connected with the outlet of the column, wherein a substantial part of the emitter is covered with the polymer material. There is also provided a method by which a separation column along with the accompanying end fittings for connection with adjacent liquid conduits is embedded in a polymer matrix. This configuration e.g. ensures that the factory-made, correct attachment of the fittings to the column is preserved (since the matrix prevents further user intervention, accidental or otherwise). Accordingly, the responsibility for the correct attachment of the fittings is shifted from the end user to the manufacturer.

Exemplary embodiments integrate a tee or valve into an outlet end fitting of a liquid chromatography column. The tee or valve is suitable for providing additional fluidic flow paths to ports of the end fitting and eliminates the need for post-column fluidic conduits connecting to tees or valves to insert fluidic inputs or divert flow to outputs. This integration decreases the distance that eluent from the liquid chromatography column has to travel to reach a detector relative to systems that use external tees or valves while providing tee/valve functionality and reducing the fluidic volume post-column. As a result, the exemplary embodiments help decrease sample dispersion.

The exemplary embodiments provide chromatography column positioning assemblies that can ensure that the distance between face seals or other sealing surfaces/mechanisms at the respective ends of a liquid chromatography column is a desired distance (i.e., the length of the liquid chromatography column). The exemplary embodiments can adjust the separation between the face seals to accommodate different length liquid chromatography columns. For example, a chromatography column positioning assembly of an exemplary embodiment can set the distance between face seals to accommodate a 25 mm column, a 50 mm column or a 100 mm column.

A compression fitting includes a nut with a threaded end for receiving a threaded tube and a receiving end for holding a plunger head; and a plunger with an inner bore for receiving a capillary tube and the plunger head for engaging a ferrule positioned within the receiving end between the plunger head and the threaded tube, the plunger slidingly engaged with the nut to force the ferrule from the nut.