The invention relates to a liquid sample preparation device such as a disposable, collapsible, flexible polymeric bag containing an adsorptive curtain of a functionalized shaped polymeric fiber bed for the direct capture of biomolecules from liquid samples. The functionalized shaped polymeric fiber bed includes fibrillated, ridged or winged-shaped fiber structures that significantly increases the surface area of the fiber resulting in enhanced separation, retention and/or purification of liquid samples containing biomolecules of interest as the liquid samples contact the adsorptive curtain of functionalized shaped fibers. Liquid samples include unclarified liquid feeds or other liquids containing one or more biomolecules of interest, including, but not limited to vaccines, recombinant proteins, cells, stem cells, monoclonal antibodies (mAbs), proteins, antibody, peptides, oligopeptides, nucleic acids, oligonucleotides, RNA, DNA, oligosaccharides and polysaccharides.

The invention relates to a liquid sample preparation device such as a disposable, collapsible, flexible polymeric bag containing an adsorptive curtain of a functionalized shaped polymeric fiber bed for the direct capture of biomolecules from liquid samples. The functionalized shaped polymeric fiber bed includes fibrillated, ridged or winged-shaped fiber structures that significantly increases the surface area of the fiber resulting in enhanced separation, retention and/or purification of liquid samples containing biomolecules of interest as the liquid samples contact the adsorptive curtain of functionalized shaped fibers. Liquid samples include unclarified liquid feeds or other liquids containing one or more biomolecules of interest, including, but not limited to vaccines, recombinant proteins, cells, stem cells, monoclonal antibodies (mAbs), proteins, antibody, peptides, oligopeptides, nucleic acids, oligonucleotides, RNA, DNA, oligosaccharides and polysaccharides.

The present invention provides a new chemical process, a new cassette configuration, and new software for the automated production of multiple batches of an [.sup.18F]labelled compound on a single cassette. The invention allows one synthesizer in one hot cell to produce sequentially a plurality of batches of [.sup.18F]-labelled PET tracer in the same day. In particular, the present invention provides a novel arrangement useful for the trapping of [.sup.18F]fluoride and recovery of [.sup.18O]water.

The present invention provides a new chemical process, a new cassette configuration, and new software for the automated production of multiple batches of an [.sup.18F]labelled compound on a single cassette. The invention allows one synthesizer in one hot cell to produce sequentially a plurality of batches of [.sup.18F]-labelled PET tracer in the same day. In particular, the present invention provides a novel arrangement useful for the trapping of [.sup.18F]fluoride and recovery of [.sup.18O]water.

An ion exchanger includes a case that is provided with an opening, an intake port, and a discharge port. The opening opens upward in the case. Coolant is drawn into the lower portion of the case through the intake port and discharged through the discharge port. An ion exchanging resin member and a cap are provided in the case. The ion exchanging resin member removes ions from the coolant. The cap is detachably attached to the case and closes the opening of the case. The ion exchanger further includes a tube member that is arranged to extend vertically in the case. The lower end aperture of the tube member is connected to the discharge port of the case. The upper end aperture of the tube member faces the inner top surface of the lid portion of the cap.

An ion exchanger includes a case that is provided with an opening, an intake port, and a discharge port. The opening opens upward in the case. Coolant is drawn into the lower portion of the case through the intake port and discharged through the discharge port. An ion exchanging resin member and a cap are provided in the case. The ion exchanging resin member removes ions from the coolant. The cap is detachably attached to the case and closes the opening of the case. The ion exchanger further includes a tube member that is arranged to extend vertically in the case. The lower end aperture of the tube member is connected to the discharge port of the case. The upper end aperture of the tube member faces the inner top surface of the lid portion of the cap.

A hyper-productive chromatography technique includes providing a scalable and stackable chromatographic cassette, loading a sample to be processed, operating the scalable chromatographic cassette having an adsorptive chromatographic bed having a volume greater than 0.5 liter by establishing a flow at a linear velocity greater than 500 cm/hr with a residence time of the loading step of less than one minute.

An ion exchange chromatography column contains an ion exchange stationary phase that includes a charged substrate, a plurality of first particles, and a plurality of second particles. The plurality of first particles each include first ion exchange groups and the first particles are ionically bound to the charged substrate. The plurality of second particles each include second ion exchange groups and the second particles are ionically bound to the charged substrate. The first particles having a first ion exchange group density, and the second particles having a second ion exchange group density. The first ion exchange group density is greater than the second ion exchange group density. The ion exchange chromatography column has a number of zones connected in series where each zone can have a varying level of first ion exchange groups and second ion exchange group from the inlet zone to the outlet zone.

An ion exchange chromatography column contains an ion exchange stationary phase that includes a charged substrate, a plurality of first particles, and a plurality of second particles. The plurality of first particles each include first ion exchange groups and the first particles are ionically bound to the charged substrate. The plurality of second particles each include second ion exchange groups and the second particles are ionically bound to the charged substrate. The first particles having a first ion exchange group density, and the second particles having a second ion exchange group density. The first ion exchange group density is greater than the second ion exchange group density. The ion exchange chromatography column has a number of zones connected in series where each zone can have a varying level of first ion exchange groups and second ion exchange group from the inlet zone to the outlet zone.

The present invention relates to recovery of lithium from liquid resources to produce lithium solutions while limiting impurity precipitation in the lithium solutions.