a century. IVs have been successfully used against polio, hepatitis A, rabies, and
influenza. Similarly, LAVs have been used against measles, mumps, rubella, var-
icella, rotavirus, polio, yellow fever, and influenza [17,19]. Because the development
of whole virus vaccines does not require very much knowledge of the viral compo-
nents and involves mainly cell-culture, this method of vaccine production, especially
IVs, can be relied upon in circumstances when a new pathogen emerges, and a
vaccine is rapidly needed [1]. However, since their production involves the propa-
gation of live virus, they must be manufactured in biosafety level 3 facilities [56].
There are several IVs that have been developed against SARS-CoV-2, including
two vaccines from the Chinese biotech companies Sinovac and Sinopharm, as well
as a candidate from the Indian Bharat Biotech. Both Chinese vaccines use Vero
cells to propagate the virus. Sinopharm’s vaccine, also known as BBIBP-CorV, was
designed and produced as follows: several different strains of SARS-CoV-2 were
isolated from the bronchoalveolar lavage samples of hospitalized patients. These
strains were then grown in Vero cells and serially passaged over 10 generations in a
basket reactor. The strain with the highest replication and viral yields was selected,
because highly efficient proliferation and high genetic stability are key features for
the development of IV vaccines [57]. The selected strain, known as HB02, was
sequenced and compared to other global strains of SARS-CoV-2 demonstrating
sequence homology and 100% homology of the S-protein. It was, subsequently,
purified and inactivated with ß-propiolactone at a ratio of 1:4000 at 2–8°C [57].
Phase 3 trial results for the Sinopharm vaccine showed efficacies of 79.34% [56].
Sinovac’s vaccine, also known as CoronaVac, was propagated in African green
monkey kidney cells (WHO Vero 10–87 cells). At the end of the incubation period,
the virus was harvested, inactivated with β-propiolactone, concentrated, purified,
and then adsorbed onto aluminium hydroxide. The aluminium hydroxide complex
was then diluted in sodium chloride, phosphate-buffered saline, and water before
being sterilized and filtered for injection [58,59]. Phase 3 trial results for the
Sinovac vaccine showed varying results ranging from efficacies of 50.7% in Brazil
to 83.5% in Turkey [60].
12.4.4
PROTEIN SUB-UNIT VACCINES
Protein sub-unit vaccines have been successfully used for many decades. They
consist of antigenic proteins produced by the purification of specific viral proteins
or via the production of recombinant proteins in host cells [4]. They may be pro-
duced using bacterial, yeast, insect, or even mammalian cells depending on the need
for specific post-translational modifications [9]. They are widely used due to their
high safety profiles with little adverse effects and because they do not include whole
viruses, they are safe for use in immunocompromised individuals. Furthermore,
from a production standpoint, they are advantageous since they do not require the
handling of live viruses and are readily scalable for mass production at GMP
standards [26]. Further, their distribution is not as dependent on cold-chain systems
as some of the other vaccine platforms. However, their manufacturing processes
may be expensive in the event they require animal cell expression systems [4].
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Bioprocessing of Viral Vaccines