Maximizing yield of perfusion cell culture processes: Evaluation and scale-up of continuous bleed recycling

Bleed recycling is a novel method to increase the yield of steady-state perfusion processes by concentrating process bleed to selectively remove biomass and recycle the liquid fraction. This results in significant product saving which otherwise would go to waste. As long as cells can be concentrated...

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Bibliographic Details
Published in:Biochemical engineering journal 2023-04, Vol.193, p.108873, Article 108873
Main Authors: Romann, Patrick, Kolar, Jakub, Chappuis, Loïc, Herwig, Christoph, Villiger, Thomas K., Bielser, Jean-Marc
Format: Article
Language:English
Subjects:
Acoustic separation
acoustics
biomass
Bleed recycling characterization
cell culture
gravity
Inclined gravity settling
liquids
metabolites
Monoclonal antibody production
product quality
Scale-up
Steady-state perfusion
wastes
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Summary:Bleed recycling is a novel method to increase the yield of steady-state perfusion processes by concentrating process bleed to selectively remove biomass and recycle the liquid fraction. This results in significant product saving which otherwise would go to waste. As long as cells can be concentrated and separated, existing cell separation devices can be used for such an application. However, limited information comparing operation modes and efficiency for bleed recycling applications is available. For the first time, inclined gravity settling has been used as bleed recycling technology and was compared to acoustic separation. Except for lower debris removal, inclined gravity settling showed similar bleed recycling efficiency and no negative impact on cell viabilities, nutrient and metabolite levels and product quality. Additionally considering reduced system complexity and facilitated scale-up, inclined gravity settling was the preferred technology for further evaluation during a 42-day lab-scale perfusion process. Up to a 3.5-fold bleed reduction and an average harvest rate increase of 19% was achieved. Scalability was subsequently tested with a large-scale inclined gravity settler suitable for a 2000 L perfusion process confirming performance of lab-scale experiments. Bleed recycling characterization data from screening experiments combined with scalability demonstration facilitates decision making when considering bleed recycling for novel perfusion process settings to reduce perfusion waste, increase process sustainability and boost overall process yield. [Display omitted] •Novel application of inclined gravity settling in bleed recycling.•Acoustic separation vs. inclined gravity settling for bleed recycling.•Characterization of bleed recycling for a wide range of process parameters.•Successful bleed recycling automation during long-term perfusion culture.•Scale-up of inclined gravity settling to perfusion manufacturing scale.
ISSN:1369-703X
1873-295X
DOI:10.1016/j.bej.2023.108873