virus, between 2−4 days after TOI (Figure 5.6). Typically, the infectious virus titer
peaks earlier than the total virus titer (infectious plus non-infectious virus particles),
and the total virus titer remains more or less constant after reaching its maximum,
whereas the infectious titer often decreases with time depending on the virus stability.
This is important for generation of seed virus and when infectious virus material is the
product (e.g., live-attenuated vaccines, viral vectors, oncolytic viruses). For lytic
viruses, the cytopathic effect leads to the termination of the process due to cell death.
Depending on titers and the level of contaminating by-products (e.g., host cell DNA,
proteins), the virus harvest is collected, clarified (depth filtration, centrifugation) and
inactivated by (e.g., formaldehyde, β-propiolactone or binary ethyleneimine (BEI) for
manufacturing of inactivated vaccines). Subsequently, it is subjected to DSP and
formulation (Figure 5.1). After sterilization of the equipment or exchange of the
single-use equipment, a new batch cycle can be conducted. Monitoring of the pro-
duction process is carried out by measuring the concentrations of cells and metabo-
lites, pH value, total and infectious virus titer, DNA and (host cell) protein levels (see
also chapter 8). Most of these measurements still rely on manual sampling. For off-
line analytics, samples are stored at −80°C and should only be thawed once for ti-
trations as viruses are sensitive to freeze-thaw cycles. For other assays, heat or other
inactivation of samples should be considered with respect to biosafety and virus
contaminations of equipment.
5.7.2
PROCESS DEVELOPMENT AND OPTIMIZATION
Ideally, process development should be based on comprehensive data available for
cultivations that were performed at various scales and under different conditions
with at least three replicates using a design of experiments (DoE) approach. To
obtain maximum virus titers, experiments should include the adaptation of viruses
to the specific host cell line selected and variations in TOI and MOI. Moreover, the
replicates should be performed from different precultures and with different ali-
quots from the virus seed. As animal cell culture is time consuming and many of the
assays to determine virus titers require several days before read-outs are available,
the total time for a set of experiments including analytics can require several weeks
(typically 4−6 weeks). In addition, contamination risks and handling issues with
small bioreactors can be challenging.
Furthermore, regarding data evaluation and the selection of optimum process
conditions, the error of the respective assays has to be taken into account. This
concerns in particular, virus titrations based on dilution series which often display
errors in the ±0.3 log range. Together with relatively high batch-to-batch variations
of cultivations performed in triplicates, the final selection of optimum process
conditions is not trivial. Depending on resources (staff, equipment, analytics), it’s
generally advisable to first perform scouting experiments (possibly in triplicates) at
very small scales (well plates, T-flasks, shake flasks) and then plan for DoE ap-
proaches at the bioreactor scale for a low number of (pre-)selected parameters only.
Another option is the use of small-scale or micro-bioreactors such as Ambr®
(Sartorius) or BioLector (m2plabs). However, working volumes and sampling have
to be selected carefully as for some analytics sample volumes of 1 mL are required.
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Bioprocessing of Viral Vaccines