Mixed-mode size-exclusion silica resin for polishing human antibodies in flow-through mode.

The polishing step in the downstream processing of therapeutic antibodies removes residual impurities from Protein A eluates. Among the various classes of impurities, antibody fragments are especially challenging to remove due to the broad biomolecular diversity generated by a multitude of fragmentation patterns. The current approach to fragment removal relies on ion exchange or mixed-mode adsorbents operated in bind-and-gradient-elution mode. However, fragments that bear strong similarity to the intact product or whose biophysical features deviate from the ensemble average can elude these adsorbents, and the lack of a chromatographic technology enabling robust antibody polishing is recognized as a major gap in downstream bioprocessing. Responding to this challenge, this study introduces size-exclusion mixed-mode (SEMM) silica resins as a novel chromatographic adsorbent for the capture of antibody fragments irrespective of their biomolecular features. The pore diameter of the silica beads features a narrow distribution and is selected to exclude monomeric antibodies, while allowing their fragments to access the pores where they are captured by the mixed-mode ligands. The static and dynamic binding capacity of the adsorbent ranged respectively between 30-45 and 25-33 gs of antibody fragments per liter of resin. Selected SEMM-silica resins also demonstrated the ability to capture antibody aggregates, which adsorb on the outer layer of the beads. Optimization of the SEMM-silica design and operation conditions - namely, pore size (10 nm) and ligand composition (quaternary amine and alkyl chain) as well as the linear velocity (100 cm/h), ionic strength (5.7 mS/cm), and pH (7) of the mobile phase - afforded a significant reduction of both fragments and aggregates, resulting into a final antibody yield up to 80% and monomeric purity above 97%.

Novel peptoid-based adsorbents for purifying IgM and IgG from polyclonal and recombinant sources.

Polyclonal immunoglobulin therapeutics comprising dosed IgG and IgM combinations are powerful tools in fighting cancer and severe infections. The inability of protein ligands to produce polyclonal IgG- and IgM-enriched formulations and recover monoclonal IgM calls for novel ligands with superior biorecognition activity. In this study, a peptoid ligand discovered by our group, and integrated into affinity adsorbents LigaTrap Technologies' "Human IgG" and "Human IgM", were utilized to purify IgG and IgM from complex fluids. IgG purification from human serum using LigaTrap IgG afforded 94.6% purity and 62.9% yield, on par with Protein A/G resins. When challenged with CHO and HEK cell culture harvests with low IgG titer (<1 mg/mL), LigaTrap IgG returned values of yield and purity well above 60% and 90%. LigaTrap IgM was evaluated for purifying IgM in comparison with commercial adsorbents, and afforded a product purity of 93% from a CHO harvest (IgM titer of 1 mg/mL) and 75.1% yield from a HEK harvest (0.5 mg/mL). LigaTrap-M provided IgM enrichment up to 11-fold higher than HiTrap resin. The peptoid adsorbents separated IgG-depleted human serum into IgM- and IgA-enriched fractions. These results demonstrate the potential of the peptoid ligand for manufacturing polyclonal Ig formulations and monoclonal IgM therapeutics.