protein production use ATF systems [28,73,74]. Vázquez-Ramírez et al. used an
ATF-based perfusion process for the production of MVA using suspension
AGE1.CR.pIX cells, reaching up to 50E06 cells/mL with high infectious MVA
titers around 1E10 TCID50/mL, thus demonstrating the potential of ATF systems
also in virus production [37]. However, several drawbacks limit the usability of
ATF systems, especially for the production of viruses. Due to the lytic nature of the
virus production process and larger sizes of some viruses (100–400 nm), mem-
branes tend to clog. Larger pore sizes in the membrane (currently available pore
sizes: 45 kDa-650 nm) could allow continuous harvesting of virus particles, facil-
itating higher CSVY and virus stability due to shortened RT in the bioreactor.
This was further investigated by Genzel et al. by comparing three different ATF
membrane cut-offs in the range of 45 kDa-650 nm for IAV production at
25E06 cells/mL. Pore sizes of 0.65 μm still not allowed to harvest IAV virus
particles of about 0.2 μm size through the membrane. This clearly illustrates the
need for larger cut-offs or other membrane materials [38]. A recent study performed
by Hein et al. described a novel tubular membrane (Artemis Biosystems), which
allowed 100% of produced virus particles (IAV) to pass through [40]. Finally,
compared to TFF systems, the shear stress generated by ATF systems is lower by a
Feed pump
HF Membrane
Diaphragm
pump
Vacuum and
pressure line
ATF controller
Balance
Weight control
Permeate pump
Spent medium
Feed
medium
1
2
FIGURE 6.6 Schematic illustration of an ATF setup and a hollow-fiber unit. The dia-
phragm pump pushes the liquid in a bidirectional flow direction: 1) Exhaust cycle:
Pressurized air is pressing the diaphragm into the liquid chamber, resulting in a backflush of
the cells and medium into the bioreactor. 2) Pressure cycle: A vacuum pulls the diaphragm
into the liquid chamber, resulting in an inflow of cell broth into the filter unit. Cell-free
supernatant is removed through the membrane pores during the pressure cycle, allowing fresh
medium to be added to the bioreactor. Figure adapted from [ 65].
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Bioprocessing of Viral Vaccines