Design and economic investigation of a Multicolumn Countercurrent Solvent Gradient Purification unit for the separation of an industrially relevant PEGylated protein

• Published in: Journal of Chromatography A Vol. 1681; p. 463487
• Main Authors: Kim, Tae Keun, Sechi, Benedetta, Romero Conde, Juan Jose, Angelo, James, Xu, Xuankuo, Ghose, Sanchayita, Morbidelli, Massimo, Sponchioni, Mattia
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 11.10.2022
• Subjects: Continuous chromatography; Cost analysis; MCSGP; Optimization; PEGylated protein; PEGylated protein; MCSGP; Continuous chromatography; Cost analysis; Optimization
• ISSN: 0021-9673
• DOI: 10.1016/j.chroma.2022.463487

•Purification of PEGylated proteins is critical for the similarity of product and impurities.•Batch chromatography has low yield and productivity at a given purity specification.•The MCSGP for a PEGylated protein is designed from an optimized batch process.•MCSGP outperforms the batch process in yield, productivity and process mass intensity.•A cost analysis for different scenarios reveals the economic advantages of MCSGP. Conjugation of biopharmaceuticals to polyethylene glycol chains, known as PEGylation, is nowadays an efficient and widely exploited strategy to improve critical properties of the active molecule, including stability, biodistribution profile, and reduced clearance. A crucial step in the manufacturing of PEGylated drugs is the purification. The reference process in industrial settings is single-column chromatography, which can meet the stringent purity requisites only at the expenses of poor product recoveries. A valuable solution to this trade-off is the Multicolumn Countercurrent Solvent Gradient Purification (MCSGP), which allows the internal and automated recycling of product-containing side fractions that are typically discarded in the batch processes. In this study, an ad hoc design procedure was applied to the single-column batch purification of an industrially relevant PEGylated protein, with the aim of defining optimal collection window, elution duration and elution buffer ionic strength to be then transferred to the MCSGP. This significantly alleviates the design of the continuous operation, subjected to manifold process parameters. The MCSGP designed by directly transferring the optimal parameters allowed to improve the yield and productivity by 8.2% and 17.8%, respectively, when compared to the corresponding optimized batch process, ensuring a purity specification of 98.0%. Once the efficacy of MCSGP was demonstrated, a detailed analysis of its cost of goods was performed and compared to the case of single-column purification. To the best of our knowledge, this is the first example of a detailed economic investigation of the MCSGP across different manufacturing scenarios and process cadences of industrial relevance, which demonstrated not only the viability of this continuous technology but also its flexibility.