withdrawn through the underflow pipe at the bottom of the insert bag [52]. As no seals
are required for connection of the single use insert bag and the conical rotor, and the
inserts have been approved by the FDA, these systems are attractive for large-scale
virus production [19,43]. To our knowledge no published study reported details re-
garding the use of centrifuges for the cultivation of viruses in perfusion mode, so far.
However, they have been routinely used in commercial perfusion processes for
production of labile proteins [19]. Drawbacks of the Centritech® system as well as the
other centrifuges are the high investment costs. Furthermore, long residence times of
the cells inside the centrifuge (up to 9 min) and high wall shear stress in the insert bags
are disadvantageous. Moreover, reliability and robustness of the perfusion process is
solely dependent on the quality of the insert bag, which has to be replaced at every 20
million revolutions or 31 days of continuous operation [19,53]. Compared to a
filtration-based perfusion system, usage of the Centritech® system has been shown to
reduce the productivity in MAb production by 30% [79].
Centrifuges can also be used as separate external “pseudo” retention devices for
small-scale screening systems. Particularly for research purposes including initial
process development and high-throughput screening, small-scale semi-perfusion
shake flask cultivations are a convenient alternative to full perfusion processes
[11,19]. Using small-scale systems (shake flasks or spin tubes), total medium usage
is significantly reduced, while even for HCD cultures, cell viabilities similar to
bioreactor perfusion systems can be achieved [11]. In semi-perfusion, cells are
Feed pump
Centrifuge
Balance
Weight control
Permeate pump
Spent medium
Feed
medium
FIGURE 6.7 Schematic illustration of a disc centrifuge setup for perfusion processes. The
main streams of the centrifuge can be divided into three parts: The feed stream containing
cells is pumped from the bioreactor into the centrifuge. Centrifugal forces push the cells
outward and separate them as the underflow, which can be pumped back into the bioreactor.
Cell-free supernatant is constantly removed from the overflow, allowing fresh medium to be
added to the bioreactor. Figure adapted from [ 65].
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Bioprocessing of Viral Vaccines