5.6.2.1
Temperature
Typically, cultivation temperature is set to 37°C (<±1°C)). Decreasing to 32−34°C
at TOI can help to increase virus yield as enzyme activities of cellular proteases are
reduced and the produced virus can be more stable. Furthermore, oxygen supply
will change.
5.6.2.2
pH and CO2
The pH set point is equally important. There will always be an optimal pH for cell
growth, one for virus production and one for enzyme activities such as trypsin or
other important enzymes for virus binding for example. Thus, different pH regimes
during the different process phases might be accepted. Typically, the pH value is
controlled in the interval of 7.2−7.4. Lactate and ammonia produced by the cells
exert the major changes in cell culture supernatant, which are buffered preferably by
a CO2/bicarbonate system. For this buffer system, there is a very fragile balance
between aeration rate, CO2 addition, choice of sparger, stirring speed and head
space aeration that needs to be fine-tuned for each filling height of the STRs.
However, also for static bioreactors in CO2 incubators, the CO2 and NaHCO3
buffering has to be considered, as pH decreases and increases occur when a T-flask
is taken in or out of the incubator, respectively. Equilibration of fresh medium in the
incubator might take as long as 1 hour Increasing CO2 set point of the incubator
from e.g., 5 to 10% can reduce the pH by up to 0.5.
To increase the pH value often either CO2 supply is decreased or a base is added.
Typically, this base is NaHCO3. Addition of more NaHCO3 to a medium that already
contains up to 12 mM will increase the pH sharply (up to 1 log unit). In contrast, with
NaHCO3 concentrations exceeding 12 mM, further addition of NaHCO3 will not
increase pH significantly anymore. Often, NaOH is used as an alternative for pH
control, but it is not well tolerated by many cell lines. Thus, both options should be
evaluated at small scale. Intracellular pH is often overlooked but of great relevance for
cell physiology. As long as the extracellular pH is above 7.2, the intracellular pH
value is typically lower than the extracellular value [54].
5.6.2.3
Shear Stress
Cells, but equally virus particles, are sensitive to shear stress. Shear stress can be
understood as a force applied tangentially on a fluid element at rest over a static
surface that deforms the fluid element parallelly through planes slippage. Newton’s
first law relates the velocity gradient and the shear stress as follows [55]:
u
y
=
x
(5.1)
where
[Pa] is the shear tress,
[Pa.s] the dynamic viscosity and u
y
x [s−1] the
velocity gradient. The resulting flow has a characteristic velocity profile. Two
general flow regimes are distinguished depending on the hydrodynamic properties
of the fluid and the flow conditions. Low shear stress conditions are found in la-
minar flow regimes, where the fluid flows in layers in one direction. Increasing
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Bioprocessing of Viral Vaccines