The present invention relates to an improved method of purifying an immunoglobulin, and more particularly to a method of purifying an immunoglobulin which is capable of sufficiently removing impurities from an immunoglobulin-containing plasma protein sample through a simple process, comprising a single anion-exchange chromatography and a single cation-exchange chromatography.

The present invention relates to a method of purifying a recombinant polypeptide from Host Cell Proteins (HCP), the method comprising: (a) applying a solution comprising the recombinant polypeptide and HCP to a superantigen chromatography solid support, (b) washing the superantigen chromatography solid support with a wash buffer comprising caprylate and arginine; and (c) eluting the recombinant polypeptide from the superantigen chromatography solid support.

Systems and methods to characterize dimerization interfaces at the subdomain level of a protein are provided. An exemplary method includes digesting a protein dimer sample into subdomains, labeling the digested protein sample, isolating labeled dimeric and monomeric subdomain fragments, and peptide mapping the labeled sample to determine where the dimer fragments are labeled and where the dimer fragments are not labeled. Regions that show decreased labeling extents in the dimer fraction than that in the monomer fraction are likely involved or in close proximity to the dimerization interface.

The present invention provides for a new therapeutic tools capable of treating infectious diseases, in particular, a new pharmaceutical composition comprising an IgM-enriched immunoglobulin preparation for use in the adjunctive treatment of severe Community Acquired Pneumonia (sCAP).

Provided herein are PD-1 antigen-binding proteins and related nucleic acids, vectors, host cells, kits and pharmaceutical compositions. Methods of making PD-1 antigen-binding proteins and methods of treating a subject are further provided.

The present invention relates to a method for the separation and purification of glycoforms with an ion exchange separation material with amino-acid based endgroups.

Disclosed is a method for production of a fusion protein in which an antibody and a lysosomal enzyme are fused. The method comprises; (a) a step of culturing mammalian cells producing the fusion protein in a serum-free medium to let the mammalian cells secrete the fusion protein in the culture medium, (b) a step of collecting culture supernatant by removing the mammalian cells from the culture medium, and (c) a step of purifying the fusion protein from the culture supernatant by using a column chromatography employing as a solid phase a material to which a substance having affinity for the fusion protein has been bound, a column chromatography employing as a solid phase a material having affinity for the phosphate group, and a size exclusion column chromatography.

The invention relates to high salt load conditioning during cation exchange chromatography for removal of low isoelectric point product-related impurities during manufacture of recombinant multispecific proteins.

The invention relates to methods for removal of low isoelectric point product-related impurities during cation exchange purification operations.

A method for manufacturing a mixed-mode chromatography medium is provided. The method can include, for example, oxidizing diol groups on diol-functionalized solid particles having pores of a median diameter of 0.5 micron or greater with substantially no pores of 0.1 micron or less in diameter and having a diol density of from about 200 to about 300 μmol/mL to aldehyde groups, thereby converting said diol-functionalized solid particles to aldehyde-functionalized solid particles; and coupling amine-functionalized ligands to said aldehyde-functionalized solid particles, said amine-functionalized ligands comprising an amine-substituted hydrophobic group joined to an acid moiety selected from the group consisting of a carboxyl group and a sulfo group.