The present invention discloses a preparation method for a disubstituted PEGylated interleukin 2, which comprises the steps of: (1) PEGylating IL-2 to obtain a crude product of a PEGylated interleukin; (2) performing gel chromatography filtration to remove free interleukin 2 from the crude product; (3) performing affinity chromatography on the product in the step (2) by means of an α receptor column, and collecting a flow-through peak component and an elution peak component; (4) performing ion exchange separation on the flow-through peak component and the elution peak component in the step (3); and (5) collecting components of the disubstituted PEGylated interleukin 2.

A method for purification of a sulfatase using metal chelating chromatography without using tags such as His-tag, etc. is disclosed. An embodiment provides a method for purifying a sulfatase including the steps of: (a) providing a sulfatase-containing solution comprising one or a plurality of impurities; (b) performing a first chromatographic separation of the sulfatase-containing solution using a metal affinity chromatography resin; (c) performing a second chromatographic separation using a cation exchange chromatography resin; and (d) performing a final chromatographic separation using an anion exchange chromatography resin, wherein the impurities are removed thereby.

A method for purification of a sulfatase using metal chelating chromatography without using tags such as His-tag, etc. is disclosed. An embodiment provides a method for purifying a sulfatase including the steps of: (a) providing a sulfatase-containing solution comprising one or a plurality of impurities; (b) performing a first chromatographic separation of the sulfatase-containing solution using a metal affinity chromatography resin; (c) performing a second chromatographic separation using a cation exchange chromatography resin; and (d) performing a final chromatographic separation using an anion exchange chromatography resin, wherein the impurities are removed thereby.

The present invention is in the field of purification and protein purification in particular. The invention provides improved techniques for the industrial-scale purification of proteins and other biomolecules. More specifically, it relates to a process for the purification of a compound of interest, such as a protein, preferably an antibody or an antibody fragment using a chromatography step, preferably a semi-continuous chromatography step.

The present invention is in the field of purification and protein purification in particular. The invention provides improved techniques for the industrial-scale purification of proteins and other biomolecules. More specifically, it relates to a process for the purification of a compound of interest, such as a protein, preferably an antibody or an antibody fragment using a chromatography step, preferably a semi-continuous chromatography step.

The disclosure relates to systems and methods for improving the manufacturing of silk solutions and powders containing silk fibroin obtained from silkworm cocoons. The solutions and powders can be used to improve the post-harvest preservation of perishables and to improve the performance of packaging, including biodegradable packaging.

The disclosure relates to systems and methods for improving the manufacturing of silk solutions and powders containing silk fibroin obtained from silkworm cocoons. The solutions and powders can be used to improve the post-harvest preservation of perishables and to improve the performance of packaging, including biodegradable packaging.

The present disclosure is in the field of ‘pharmacognosy’ and ‘chemistry of natural products’. The present disclosure generally relates to a process of isolation and purification of Biochemical Constituents from algae. The present disclosure particularly relates to a process of isolation and purification of Biochemical Constituents from a biomass of cyanobacteria. The present disclosure provides a process for isolating and extracting phycocyanins, chlorophylls, proteins and polysaccharides from the spirulina biomass.

It is disclosed an improved multi-step process for the preparation of a highly concentrated liquid formulation containing biomolecules comprising the steps of (a) a first ultrafiltration UF1; (b) a first diafiltration DF1; (c) a second diafiltration DF2; and (d) a second ultrafiltration UF2; wherein an aqueous solution of one or more salts, as liquid medium B, is used for step (b) and water or an aqueous solution of one or more salts, as liquid medium C, is used for step (c), wherein the one or more salts used for step (b) are the same or different from the one or more salts used for step (c) and wherein the liquid medium B has an ionic strength which is higher than the ionic strength of the liquid medium C. The process according to the present invention allows the preparation of well-defined highly concentrated formulations containing biomolecules, particularly proteins, intended for pharmaceutical or non-pharmaceutical use. Unwanted excipient(s) of the starting liquid biomolecule formulation, may be reduced under solution conditions, to very low levels or levels lower than the detection limit.

It is disclosed an improved multi-step process for the preparation of a highly concentrated liquid formulation containing biomolecules comprising the steps of (a) a first ultrafiltration UF1; (b) a first diafiltration DF1; (c) a second diafiltration DF2; and (d) a second ultrafiltration UF2; wherein an aqueous solution of one or more salts, as liquid medium B, is used for step (b) and water or an aqueous solution of one or more salts, as liquid medium C, is used for step (c), wherein the one or more salts used for step (b) are the same or different from the one or more salts used for step (c) and wherein the liquid medium B has an ionic strength which is higher than the ionic strength of the liquid medium C. The process according to the present invention allows the preparation of well-defined highly concentrated formulations containing biomolecules, particularly proteins, intended for pharmaceutical or non-pharmaceutical use. Unwanted excipient(s) of the starting liquid biomolecule formulation, may be reduced under solution conditions, to very low levels or levels lower than the detection limit.