Impact of micro and macroporous TFF membranes on product sieving and chromatography loading for perfusion cell culture

Pinto, Nuno D.S.; Napoli, William; Brower, Mark

doi:10.1002/bit.27192

Cited by 24 publications

(38 citation statements)

References 28 publications

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“…Here, both Antibody and DNA average sieving coefficients were both reduced only when employing the 0.65-µm membrane (Figure 3). This finding confirms our previous (Pinto et al, 2020) With the membrane hydraulic permeability (shown in Table 1) and assuming uniform cylindrical pores, the mean pore radius (r p ) was determined using the equation as follows (Zeman & Zydney, 1996):…”

Section: Perfusion Membrane Assessmentsupporting

confidence: 85%

“…Our previous study (Pinto, Napoli, & Brower, 2020) showed an integrated continuous bioprocess with practically nonproduct retention when employing macroporous (>1 µm pore size) perfusion membranes. This observation, corroborated by Wang et al (2017) and Wang et al (2019), highlights that microfiltration membranes retain particles within its pore size range, which leads to product sieving.…”

mentioning

confidence: 99%

“…This way, molecules can pass through the membrane pores even with several fold greater lengths than the membrane's nominal retention rating. Although a typical perfusion cell culture operates at permeate fluxes that are theoretically favorable of inducing DNA transmission (Latulippe et al, 2007), severe DNA sieving decay was reported (Pinto et al, 2020). In a potential pertinent study for perfusion cell culture, Li, Borujeni, and Zydney (2015) showed that DNA transmission is enhanced in asymmetric hollow fibers.…”

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confidence: 99%

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Wide‐surface pore microfiltration membrane drastically improves sieving decay in TFF‐based perfusion cell culture and streamline chromatography integration for continuous bioprocessing

Pinto

Brower

2020

Biotech & Bioengineering

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Although several compelling benefits for bioprocess intensification have been reported, the need for a streamlined integration of perfusion cultures with capture chromatography still remains unmet. Here, a robust solution is established by conducting tangential flow filtration-based perfusion with a wide-surface pore microfiltration membrane. The resulting integrated continuous bioprocess demonstrated negligible retention of antibody, DNA, and host cell proteins in the bioreactor with average sieving coefficients of 98 ± 1%, 124 ± 28%, and 109 ± 27%, respectively. Further discussion regarding the potential membrane fouling mechanisms is also provided by comparing two membranes with different surface pore structures and the same hollow fiber length, total membrane area, and chemistry. A cake-growth profile is reported for the narrower surface pore, 0.65-µm nominal retention perfusion membrane with final antibody sieving coefficients ≤70%. Whereas the sieving coefficient remained ≥85% during 40 culture days for the wide-surface pore, 0.2-µm nominal retention rating membrane. The wide-surface pore structure, confirmed by scanning electron microscopy imaging, minimizes the formation of biomass deposits on the membrane surface and drastically improves product sieving. This study not only offers a robust alternative for integrated continuous bioprocess by eliminating additional filtration steps while overcoming sieving decay, but also provides insight into membranes' fouling mechanism.

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Section: Perfusion Membrane Assessmentsupporting

confidence: 85%

mentioning

confidence: 99%

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confidence: 99%

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Wide‐surface pore microfiltration membrane drastically improves sieving decay in TFF‐based perfusion cell culture and streamline chromatography integration for continuous bioprocessing

Pinto

Brower

2020

Biotech & Bioengineering

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“…Disadvantages regarding the use of ATF systems in viral vaccine production due to an accumulation and eventual degradation of virions inside of the bioreactor may be alleviated by selection of membranes that are better suited for this type of application or specifically designed for virus production processes. Similarly to what was tested for membrane-based perfusion culture in recombinant protein production (Esclade et al 1991;Mercille et al 1994;Pinto et al 2019), different membrane chemistries, pore sizes, and properties such as hydrophobicity and surface charge should be characterized regarding product sieving and membrane fouling. For example, Genzel et al (2014) tested various polysulfone and polyether sulfone membranes for influenza virus production in perfusion mode.…”

Section: Discussionmentioning

confidence: 99%

Performance of an acoustic settler versus a hollow fiber–based ATF technology for influenza virus production in perfusion

Gränicher

Coronel

Trampler³

et al. 2020

Appl Microbiol Biotechnol

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Process intensification and integration is crucial regarding an ever increasing pressure on manufacturing costs and capacities in biologics manufacturing. For virus production in perfusion mode, membrane-based alternating tangential flow filtration (ATF) and acoustic settler are the commonly described cell retention technologies. While acoustic settlers allow for continuous influenza virus harvesting, the use of commercially available membranes for ATF systems typically results in the accumulation of virus particles in the bioreactor vessel. Accordingly, with one single harvest at the end of a cultivation, this increases the risk of lowering the product quality. To assess which cell retention device would be most suitable for influenza A virus production, we compared various key performance figures using AGE1.CR.pIX cells at concentrations between 25 and 50 × 10 6 cells/mL at similar infection conditions using either an ATF system or an acoustic settler. Production yields, process-related impurities, and aggregation of viruses and other large molecules were evaluated. Taking into account the total number of virions from both the bioreactor and the harvest vessel, a 1.5-3.0-fold higher volumetric virus yield was obtained for the acoustic settler. In addition, fewer large-sized aggregates (virus particles and other molecules) were observed in the harvest taken directly from the bioreactor. In contrast, similar levels of process-related impurities (host cell dsDNA, total protein) were obtained in the harvest for both retention systems. Overall, a clear advantage was observed for continuous virus harvesting after the acoustic settler operation mode was optimized. This development may also allow direct integration of subsequent downstream processing steps. Key points• High suspension cell density, immortalized avian cell line, influenza vaccine.

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“…Hence, the use of PS membranes can be equally important for related perfusion processes where expressed proteins are considered as product, but retained by PES membranes with a nominal cutoff of 0.2 μm (Karst, Serra, Villiger, Soos, & Morbidelli, 2016;Kelly et al, 2014). Alternatively, other studies identified the use of large-pore membranes of 2 μm and larger as a solution for production retention (Pinto, Napoli, & Brower, 2019;S. B. Wang, Godfrey, Radoniqi, Lin, & Coffman, 2019).…”

Section: Membrane Fouling Dynamics and Its Impact On Product Retentionmentioning

confidence: 99%

Virus harvesting in perfusion culture: Choosing the right type of hollow fiber membrane

Nikolay

Grooth

Genzel

et al. 2020

Biotech & Bioengineering

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The use of bioreactors coupled to membrane‐based perfusion systems enables very high cell and product concentrations in vaccine and viral vector manufacturing. Many virus particles, however, are not stable and either lose their infectivity or physically degrade resulting in significant product losses if not harvested continuously. Even hollow fiber membranes with a nominal pore size of 0.2 µm can retain much smaller virions within a bioreactor. Here, we report on a systematic study to characterize structural and physicochemical membrane properties with respect to filter fouling and harvesting of yellow fever virus (YFV; ~50 nm). In tangential flow filtration perfusion experiments, we observed that YFV retention was only marginally determined by nominal but by effective pore sizes depending on filter fouling. Evaluation of scanning electron microscope images indicated that filter fouling can be reduced significantly by choosing membranes with (i) a flat inner surface (low boundary layer thickness), (ii) a smooth material structure (reduced deposition), (iii) a high porosity (high transmembrane flux), (iv) a distinct pore size distribution (well‐defined pore selectivity), and (v) an increased fiber wall thickness (larger effective surface area). Lowest filter fouling was observed with polysulfone (PS) membranes. While the use of a small‐pore PS membrane (0.08 µm) allowed to fully retain YFV within the bioreactor, continuous product harvesting was achieved with the large‐pore PS membrane (0.34 µm). Due to the low protein rejection of the latter, this membrane type could also be of interest for other applications, that is, recombinant protein production in perfusion cultures.

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Impact of micro and macroporous TFF membranes on product sieving and chromatography loading for perfusion cell culture

Cited by 24 publications

References 28 publications

Wide‐surface pore microfiltration membrane drastically improves sieving decay in TFF‐based perfusion cell culture and streamline chromatography integration for continuous bioprocessing

Wide‐surface pore microfiltration membrane drastically improves sieving decay in TFF‐based perfusion cell culture and streamline chromatography integration for continuous bioprocessing

Performance of an acoustic settler versus a hollow fiber–based ATF technology for influenza virus production in perfusion

Virus harvesting in perfusion culture: Choosing the right type of hollow fiber membrane

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