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1. Enhanced filtration performance using feed‐and‐bleed configuration for purification of antibody precipitates

   https://doi.org/10.1002/btpr.3082  

   Li, Zhao; Chen, Ting‐Hsi; Andini, Erha; Coffman, Jonathan L; Przybycien, Todd; Zydney, Andrew L. (September 2020, Biotechnology Progress)

   null (Ed.)

   Precipitation can be used for the initial purification of monoclonal antibodies (mAbs), with the soluble host cell proteins removed in the permeate by tangential flow microfiltration. The objective of this study was to examine the use of a feed‐and‐bleed configuration to increase the effective conversion (ratio of permeate to feed flow rates) in the hollow fiber module to enable more effective washing of the precipitate. Experiments were performed using human serum Immunoglobulin G (IgG) precipitates formed with 10 mM zinc chloride and 7 wt% polyethylene glycol. The critical flux was evaluated as a function of the shear rate and IgG concentration, with the resulting correlation used to predict conditions that can achieve 90% conversion in a single pass with minimal fouling. Experimental data for both the start‐up and steady‐state performance are in good agreement with model calculations. These results were used to analyze the performance of an enhanced continuous precipitation–microfiltration process using the feed‐and‐bleed configuration for the initial capture / purification of a mAb product. 

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2. Enhanced filtration performance using feed-and-bleed configuration for purification of antibody precipitates

   https://doi.org/doi.org/10/1002/btpr.3082  

   Li, Z; Chen, TH; Andini, E; Coffman, JL; Przybycien, T; Zydney, AL (January 2021, Biotechnology progress)

   null (Ed.)

   Precipitation can be used for the initial purification of monoclonal antibodies (mAbs), with the soluble host cell proteins removed in the permeate by tangential flow microfiltration. The objective of this study was to examine the use of a feed-and-bleed configuration to increase the effective conversion (ratio of permeate to feed flow rates) in the hollow fiber module to enable more effective washing of the precipitate. Experiments were performed using human serum Immunoglobulin G (IgG) precipitates formed with 10 mM zinc chloride and 7 wt% polyethylene glycol. The critical flux was evaluated as a function of the shear rate and IgG concentration, with the resulting correlation used to predict conditions that can achieve 90% conversion in a single pass with minimal fouling. Experimental data for both the start-up and steady-state performance are in good agreement with model calculations. These results were used to analyze the performance of an enhanced continuous precipitation–microfiltration process using the feed-and-bleed configuration for the initial capture / purification of a mAb product. 

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3. Downstream Process Intensification for AAV Purification by Affinity Chromatography Using Single Pass Tangential Flow Filtration

   https://doi.org/10.1002/bit.70090  

   Chaubal, Akshay S; Horax, Ronny; Yehl, Christopher J; Wickramasinghe, S Ranil; Qian, Xianghong; Wang, Lu; Zydney, Andrew L (January 2026, Biotechnology and Bioengineering)

   ABSTRACT To enable adeno‐associated viral vectors (AAV) to achieve their maximum potential, next‐generation manufacturing processes must be developed to make gene therapies more affordable and accessible. This study focused on the design of two different intensified AAV downstream manufacturing processes at bench and pilot scale. Novel clarification methods were studied at bench scale, including the use of BioOptimal™ MF‐SL tangential flow microfilters for continuous removal of cell debris. Membrane adsorbers were used for further clarification, including DNA removal. Single pass tangential flow filtration (SPTFF) was implemented at bench scale by feeding the clarified cell lysate (CCL) into two Pellicon XL50 cassettes with 100 kDa regenerated cellulose membranes. At pilot scale, a multi‐membrane staged SPTFF module was designed to concentrate 10 L of AAV CCL. Both SPTFF systems provided 12X inline volumetric concentration with AAV yield > 99% after an appropriate buffer chase. Host cell protein removal was 48% and 37% for the bench and pilot scale processes, respectively. As an initial proof‐of‐concept, an integrated process was developed at pilot‐scale which linked clarification, SPTFF, and affinity chromatography. The integrated process offered an 81% reduction in total operating time (due to the reduced volume of load material for the affinity column after preconcentration by SPTFF), 36% improvement in affinity resin utilization (due to the higher AAV concentration in the column load), and an estimated 10% reduction in raw material costs. These improvements translated to an 8.5‐fold increase in overall productivity compared to an equivalent batch process, underscoring the potential for SPTFF to intensify large‐scale AAV downstream processing. 

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4. Continuous precipitation for monoclonal antibody capture using countercurrent washing by microfiltration

   https://doi.org/doi.org/10.1002/btpr.2886  

   Li, Z; Gu, Q; Coffman, JL; Przybycien, T; Zydney, AL (January 2019, Biotechnology progress)

   null (Ed.)

   There is renewed interest in the possibility of using precipitation for initial capture of high-value therapeutic proteins as part of an integrated continuous downstream process. Precipitation is greatly facilitated by the high product titers now achieved in most cell culture processes, in sharp contrast to chromatographic processes whose performance is reduced at high titers. The current study used a combination of reversible cross-linking (zinc chloride, ZnCl2) and volume exclusion (polyethylene glycol) agents to precipitate a monoclonal antibody product directly from harvested cell culture fluid using a continuous tubular precipitation reactor. The precipitates were then dewatered and continuously washed using tangential flow filtration, with a countercurrent-staged configuration used to reduce the amount of wash buffer required and increase host cell protein removal. Long-term operation was achieved by operating the membrane modules below the critical filtrate flux to avoid fouling. Experimental results demonstrate the feasibility of this fully continuous integrated precipitation process at bench scale, with design calculations used to explore the key factors affecting the performance of this system for initial antibody capture. 

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5. Proteomic analysis of host cell protein fouling during bioreactor harvesting

   https://doi.org/10.1002/btpr.3453  

   Zhang, Da; Wickramasinghe, S Ranil; Zydney, Andrew L; Smelko, John P; Loman, Abdullah; Wheeler, April; Qian, Xianghong (July 2024, Biotechnology Progress)

   Abstract Chinese hamster ovary (CHO) cells are among the most common cell lines used for therapeutic protein production. Membrane fouling during bioreactor harvesting is a major limitation for the downstream purification of therapeutic proteins. Host cell proteins (HCP) are the most challenging impurities during downstream purification processes. The present work focuses on identification of HCP foulants during CHO bioreactor harvesting using reverse asymmetrical commercial membrane BioOptimal™ MF‐SL. In order to investigate foulants and fouling behavior during cell clarification, for the first time a novel backwash process was developed to effectively elute almost all the HCP and DNA from the fouled membrane filter. The isoelectric points (pIs) and molecular weights (MWs) of major HCP in the bioreactor harvest and fouled on the membrane were successfully characterized using two‐dimensional gel electrophoresis (2D SDS‐PAGE). In addition, a total of 8 HCP were identified using matrix‐assisted laser desorption/ionization‐mass spectroscopy (MALDI‐MS). The majority of these HCP are enzymes or associated with exosomes, both of which can form submicron‐sized particles which could lead to the plugging of the filters. 

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