Bioprocessing Chromatography Techniques

Chromatography in downstream processing combines several modes, each serving a defined role. Affinity chromatography is typically used to capture the target molecule with high specificity and selectivity. Ion exchange and hydrophobic interaction steps are used to separate charge- or hydrophobic-variant proteins. In some workflows, mixed-mode resins serve as another tool, offering different selectivity through multiple interaction mechanisms in a single immobilized ligand.

Chromatography methods are used throughout downstream bioprocessing to purify biomolecules produced from upstream cell culture or fermentation. Each technique, such as affinity, ion exchange, hydrophobic interaction, mixed-mode, and size exclusion chromatography, targets specific molecular properties to reduce impurities. When combined into a purification process, these methods offer reproducibility and consistency suitable for the manufacturing of biologics.

Selecting a chromatography method depends on the molecule’s properties and overall process goals, often focusing on the minimization of process-related impurities. One of the first steps is to characterize the target molecule and impurities based on key factors, such as charge profile, isoelectric point (pI), hydrophobicity, and buffer stability. This information offers insight into which chromatography resin and separation techniques may be effective. Once a resin type is identified, resin screening can be performed using high-throughput formats, such as 96-well screening plates, to evaluate different buffer conditions to determine binding, wash, and elution parameters. Thermo Fisher Scientific has a team of technical specialists that can help with technique selection and process optimization. Please contact us for more information.

Traditional chromatography methods continue to be applied to emerging therapeutic formats, including mRNA, viral vectors, and ADCs. The same matrices enable selective separation of biomolecules based on chemical interactions, such as charge, hydrophobicity, or affinity-based binding. Innovations in resin chemistry, buffer systems, and operating modes have further advanced the purification and manufacturability of these molecules.

In purification optimization, it involves evaluating factors, such as buffer composition, pH, salt concentration, flow rate, resin selection, and loading conditions, to maximize yield and purity.

Proper scale-up enables process performance, purity, and recovery to remain consistent from laboratory to pilot and production scale. When scaling a purification step, several critical column parameters must be evaluated to maintain consistent product quality and performance. Key factors include column geometry, bed height, flow rate, residence time, load density, buffer composition, and resin packing. Additional considerations, such as hold-up volume, equipment compatibility, and automation control, also influence scale-up success.