Internal virus polarization model for virus retention by the Ultipor<sup>®</sup>VF Grade DV20 membrane

Jackson, Nigel B.; Bakhshayeshi, Meisam; Zydney, Andrew L.; Mehta, Amit; Reis, Robert van; Kuriyel, Ralf

doi:10.1002/btpr.1897

Cited by 41 publications

(40 citation statements)

References 15 publications

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“…These results suggest that previously captured virus within the DV20 and Viresolve ® NFP membranes are able to diffuse out of the pores (capture sites) when the filtration pressure is removed, with the released phage either recaptured deeper within the filter or transmitted through the membrane when the filtration is continued. This behavior is qualitatively consistent with predictions of the internal polarization model proposed by Woods and Zydney () and Jackson et al (), although the more complex capture pattern seen with the Viresolve ® NFP would likely require a much more sophisticated mathematical description.…”

Section: Discussionsupporting

confidence: 87%

“…In both experiments, the phages were captured near the filter inlet, consistent with the slight asymmetry in the pore size of the DV20 membrane (Bakhshayeshi et al, ). This upper region was described by Jackson et al () as the “reservoir zone” within the DV20 membrane. The results obtained after the pressure release experiment were quite different, with the red phage (in the challenge before the pressure release) captured in two distinct bands separated by approximately 5 μm within the depth of the filter.…”

Section: Resultsmentioning

confidence: 99%

“…Confocal microscopy using a green carboxyfluorescein‐labeled phage showed two separate green bands near the entrance of the filter after the pressure release. This behavior was described using a modified version of the internal polarization model developed by Jackson et al (), with some of the previously captured phage migrating deeper into the filter after the pressure release. However, it was difficult to validate some of the critical assumptions in this model since it was impossible to distinguish between phage that were captured before and after the pressure release.…”

Section: Introductionmentioning

confidence: 99%

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Probing effects of pressure release on virus capture during virus filtration using confocal microscopy

Dishari

Venkiteshwaran

Zydney

2015

Biotech & Bioengineering

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Virus filtration is used to ensure drug safety in the production of biotherapeutics. Several recent studies have shown a dramatic decrease in virus retention as a result of a process disruption, e.g., a transient pressure release. In this work, a novel two-label fluorescence technique was developed to probe virus capture within virus filtration membranes using confocal microscopy. Experiments were performed with Ultipor® DV20, Viresolve® Pro, and Viresolve® NFP membranes using bacteriophage φx174 as a model virus. The filters were challenged with two batches of fluorescently labeled phage: one labeled with red dye (Cy5) and one with green dye (SYBR Gold) to visualize captured phage from before and after the pressure release. The capture patterns seen in the confocal images were a strong function of the underlying membrane morphology and pore structure. The DV20 and Viresolve® NFP showed migration of previously captured phage further into the filter, consistent with the observed loss of virus retention after the pressure release. In contrast, there was no migration of captured virus in the Viresolve® Pro membranes, and these filters were also the only ones to show stable virus retention after a pressure release. The direct visualization of virus capture using the two-label fluorescence technique provides unique insights into the factors controlling the retention characteristics of virus filters with different pore structure.

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Section: Discussionsupporting

confidence: 87%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Probing effects of pressure release on virus capture during virus filtration using confocal microscopy

Dishari

Venkiteshwaran

Zydney

2015

Biotech & Bioengineering

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“…Significant viral clearance can also be achieved in chromatographic processes (Miesegaes et al, ), although most manufacturers also employ a virus filtration step to provide a robust, primarily size‐based, method for virus removal. Although virus filtration cannot be directly converted to continuous operation due to issues of membrane fouling and LRV decline (Jackson et al, ), it would be possible to operate two virus filters in parallel with the feed switched to the second filter when the capacity of the first filter was achieved.…”

Section: Viral Clearancementioning

confidence: 99%

Continuous downstream processing for high value biological products: A Review

Zydney

2015

Biotech & Bioengineering

Self Cite

233

166

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There is growing interest in the possibility of developing truly continuous processes for the large-scale production of high value biological products. Continuous processing has the potential to provide significant reductions in cost and facility size while improving product quality and facilitating the design of flexible multi-product manufacturing facilities. This paper reviews the current state-of-the-art in separations technology suitable for continuous downstream bioprocessing, focusing on unit operations that would be most appropriate for the production of secreted proteins like monoclonal antibodies. This includes cell separation/recycle from the perfusion bioreactor, initial product recovery (capture), product purification (polishing), and formulation. Of particular importance are the available options, and alternatives, for continuous chromatographic separations. Although there are still significant challenges in developing integrated continuous bioprocesses, recent technological advances have provided process developers with a number of attractive options for development of truly continuous bioprocessing operations.

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“…Woods and Zydney and Dishari et al have shown that confocal microscopy can provide important insights into the key phenomena governing virus capture during virus filtration. This includes both the decline in virus retention seen in some virus filtration experiments as well as the transient jump in virus transmission seen in response to a disruption in the filtration process . In particular, Dishari et al developed a novel two‐dye approach to visualize the capture of viruses before and after a disruption in the filtration pressure.…”

Section: Introductionmentioning

confidence: 99%

Effects of solution conditions on virus retention by the Viresolve^®NFP filter

Dishari

Micklin

Sung

et al. 2015

Biotechnol Progress

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Virus filtration can provide a robust method for removal of adventitious parvoviruses in the production of biotherapeutics. Although virus filtration is typically thought to function by a purely size-based removal mechanism, there is limited data in the literature indicating that virus retention is a function of solution conditions. The objective of this work was to examine the effect of solution pH and ionic strength on virus retention by the Viresolve(®) NFP membrane. Data were obtained using the bacteriophage ϕX174 as a model virus, with retention data complemented by the use of confocal microscopy to directly visualize capture of fluorescently labeled ϕX174 within the filter. Virus retention was greatest at low pH and low ionic strength, conditions under which there was an attractive electrostatic interaction between the negatively charged membrane and the positively charged phage. In addition, the transient increase in virus transmission seen in response to a pressure disruption at pH 7.8 and 10 was completely absent at pH 4.9, suggesting that the trapped virus are unable to overcome the electrostatic attraction and diffuse out of the pores when the pressure is released. Further confirmation of this physical picture was provided by confocal microscopy. Images obtained at pH 10 showed the migration of previously captured phage; this phenomenon was absent at pH 4.9. These results provide important new insights into the factors governing virus retention using virus filtration membranes.

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Internal virus polarization model for virus retention by the Ultipor^®VF Grade DV20 membrane

Cited by 41 publications

References 15 publications

Probing effects of pressure release on virus capture during virus filtration using confocal microscopy

Probing effects of pressure release on virus capture during virus filtration using confocal microscopy

Continuous downstream processing for high value biological products: A Review

Effects of solution conditions on virus retention by the Viresolve^®NFP filter

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Internal virus polarization model for virus retention by the Ultipor®VF Grade DV20 membrane

Cited by 41 publications

References 15 publications

Probing effects of pressure release on virus capture during virus filtration using confocal microscopy

Probing effects of pressure release on virus capture during virus filtration using confocal microscopy

Continuous downstream processing for high value biological products: A Review

Effects of solution conditions on virus retention by the Viresolve®NFP filter

Contact Info

Product

Resources

About

Internal virus polarization model for virus retention by the Ultipor^®VF Grade DV20 membrane

Effects of solution conditions on virus retention by the Viresolve^®NFP filter