DNA aptamer affinity ligands for highly selective purification of human plasma-related proteins from multiple sources.

Nucleic acid aptamers are promising ligands for analytical and preparative-scale affinity chromatography applications. However, a full industrial exploitation requires that aptamer-grafted chromatography media provide a number of high technical standards that remained largely untested. Ideally, they should exhibit relatively high binding capacity associated to a very high degree of specificity.

The quest for affinity chromatography ligands: are the molecular libraries the right source?

Affinity chromatography separations of proteins call for highly specific ligands. Antibodies are the most obvious approach; however, except for specific situations, technical and economic reasons are arguments against this choice especially for preparative purposes. With this in mind, the rationale is to select the most appropriate ligands from collections of pre-established molecules.

Fast purification process optimization using mixed-mode chromatography sorbents in pre-packed mini-columns.

Pre-packed MediaScout MiniChrom columns of 2.5, 5 and 10 mL were investigated for screening three mixed-mode chromatography sorbents (HEA, PPA and MEP HyperCel). Packing performance was of good quality and the three sorbents displayed higher capacity than traditional HIC sorbents in physiological-like conditions.

Capture of a monoclonal antibody and prediction of separation conditions using a synthetic multimodal ligand attached on chips and beads.

A synthetic ligand called 2-mercapto-5-benzimidazolesulfonic acid has been successfully used for the specific chromatographic capture of antibodies from a cell culture supernatant. Adsorption occurred at physiological ionic strength and pH range between 5.0 and 6.

Endostatin capture from Pichia pastoris culture in a fluidized bed. From on-chip process optimization to application.

One of the characteristics of the methylothrophic yeast Pichia pastoris is its ability to grow to a very high cell density. Biomass concentrations of 300-400 g wet mass/l are common. It is therefore obvious that the recovery processes of extracellular proteins from this microorganism should take into account the effect of high biomass content.