hydrophilic and charged surface [33,34]. Typical microcarrier materials are dextran,
polyester and collagen and the surface is modified with DEAE (diethylethanola-
mine) or cations. Moreover, attachment factors are crucial to ensure the attachment,
which are either provided by the serum or addition of exogenously fibronectin under
serum-free conditions [33]. For optimal growth, homogenous cell attachment is
required, thus, the ratio of cells to microcarriers needs optimization. As second
phase, cell flattening occurs to enlarge the contact area for stable binding, a process
called cell spreading [32]. By using serum-free medium, the cells tend not to flatten,
resulting in easier cell detachment due to shear stress during agitation (Figure 5.2B).
To help cell attachment, intermediate stirring can be tried, in which a short stirring
for homogenization is followed by 30 minutes without stirring, repeated over about
2 hours in total. Moreover, using macroporous microcarriers, adherent cells are
attached within the carriers reducing the shear stress by agitation and sparging
[33,35]. Furthermore, volume can be reduced after cell seeding to increase the
chance of cell surface contact.
5.5
CULTIVATION MEDIA AND METABOLISM
5.5.1
MEDIA AND ADDITIVES
The choice of cell growth medium is essential for a successful cultivation of animal
cells and, consequently, the virus production. Media developed over many years
now allow growth of suspension cells in batch mode up to 2E07 cells/mL and in
perfusion mode up to 2E08 cells/mL. Traditionally, cell-culture−based viral vaccines
are produced in serum-containing media (e.g., fetal bovine serum, FBS). This may be
required even today as many adherent cells, and in particular primary cells, are the
only host cells that can be used to propagate some viruses at high yield. However,
serum-containing media pose numerous disadvantages for efficient viral vaccine
production by complicating the purification process and therefore increasing the costs.
Moreover, serum can be contaminated with adventitious agents and unwanted by-
products (i.e., antibodies against the virus to be produced). In addition, the quality of
serum is difficult to assess and batch-to-batch variation can cause significant incon-
sistencies in cell growth and virus yields. Thus, serum-free media were developed,
where only particular serum components, including hydrolysates, amino acids,
growth factors, hormones, lipids, adhesion factors, and other compounds are added at
a defined concentration (see Table 5.3). This trend is moving towards the use of
animal component-free (AFM) or even chemically defined media (CDM), where all
ingredients are defined and, thus, contribute to process robustness. To enable the
formulation of AFM variants of media, non-animal substitutes have been developed
for the various supplements derived from serum (see Table 5.5). Today, the preferred
media for production are chemically defined, free of animal components, and certified
for GMP production. The adaptation to serum-free variants of medium typically
follows two different protocols, the sequential adaptation (changing the ratio of
serum-containing and serum-free medium) or the adaptation by using conditioned
medium (also see “Adherent versus suspension cells”).
Upstream processing for viral vaccines
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