systems seeded with HGRs in comparison to wild-type viruses [23]. HGR gen-
eration, performed only by a few laboratories in the world, consists of coinfecting
the same egg with both viruses and screening the viral progeny for a reassortant
with the desired characteristics, a process that takes between 4–6 weeks to be
completed [17,18]. To reduce the time required for HGR generation and increase
responsiveness to potential pandemics, the use of reverse genetics for viral seed
stock production have been studied. This technique consists of generating live
viruses by co-transfecting cells with a set of plasmid-cloned cDNA encoding the
influenza viral genome [24]. Rapid production of influenza virus seed stocks using
reverse genetics have been demonstrated for different cell lines [25–27].
9.4.1
INACTIVATED INFLUENZA VACCINE (IIV)
IIVs, which represent almost 90% of influenza vaccines produced globally, may be
composed of virus sub-unit, whole or split virus. Inactivated vaccines are safe, owing
to the inability of the virus to replicate, and are highly effective, promoting mostly
humoral immune response [16,28]. Cellular immune response may be increased if
viral structures are successfully preserved during the inactivation process. While virus
inactivation may be achieved through chemical (formaldehyde, β-propiolactone) or
physical processes (UV, gamma irradiation, USP laser), each technique results in a
different product and, consequently, may trigger slightly different immunological
responses [29].
The majority of IIVs, around 80%, is produced using embryonated hens’ eggs, a
technology established in 1940s where fertilized eggs are used for virus propagation
[17]. Yet, driven by advances in large-scale cell culture for recombinant protein pro-
duction [30,31], the last decades have seen an increase in the use of cell culture plat-
forms as a faster alternative for IIV production [32–37]. In short, cells are cultivated
until sufficiently high cell densities are achieved, followed by infection with the desired
virus strain. Currently, five IIVs produced using cell-culture systems are approved for
use, and only two of them are in production for commercial use (Table 9.3).
Advantages of cell-culture−based systems over traditional egg production include: i)
scalability, notably with the use of suspension cell lines [30]; ii) greater process control,
which results in a more reliable product [38]; iii) a better match between vaccine and
circulating strains, as egg-growth adaptation may generate undesirable antigenic
modification [39,40]; iv) shorter production cycles, and consequently faster responses to
TABLE 9.2
Approved antiviral drugs for the influenza disease
Mechanism of action
Drug
Neuraminidase inhibitor (blocks particle
release)
Rapivab (Peramivir), Relenza (Zanamivir), Tamiflu
(Oseltamivir phosphate)
Inhibitor of viral polymerase activity (inhibits
viral replication)
Xofluza (Baloxavir marboxil)
Manufacturing of influenza vaccines
229