12.4.2.2
Adenovirus Vectored COVID-19 Vaccines: Design,
Manufacturing, and Efficacy
One such example of a vaccine utilizing a chimpanzee adenoviral vector is the
Oxford/AstraZeneca vaccine (OA), also known as ChAdOx1 nCoV-19; AZD-1222.
It contains a DNA sequence coding for a full length, codon optimized S protein. The
European Medicines Agency assessment report on the OA vaccine describes
the finished product as a multidose suspension for injection containing ≥2.5 × 108
infectious units of ChAdOx1 adenovirus vector per 0.5 mL dose [48]. The antigen is
the S-protein fused to the tPA leader sequence using a modified CMV promoter.
The vector is described as derived from chimpanzee adenovirus Y25 that was
rendered replication-deficient through the deletion of E1. It also includes deletion of
E3 and substitution of ORFs from human Ad5. The viral vector is propagated in a
derivative of HEK-293 cells known as T-Rex-293. This cell line contains an E1
Ad5 gene stably integrated into chromosome 19, making this cell line ideal for the
propagation of E1-deleted replication deficient adenoviruses.
The manufacturing process is divided into the two conventional steps to produce
a biopharmaceutic: upstream and downstream processing. For the upstream phase,
the cell culture is expanded from a pre-inoculum in shake flasks and rocker bags
which are used to seed a bioreactor for further expansion. This inoculum is then
transferred to the production bioreactor to generate the crude AZD-1222 active
principle. The cell culture in the bioreactor is then lysed, treated with nuclease to
degrade host-cell DNA and then sterile filtered. Chromatography and concentration
steps followed by diafiltration to remove any remaining impurities are well estab-
lished steps in the generic downstream process of adenoviral vectors. Finally, there
is a formulation step followed by freezing the final product at −55 to −90°C. For
more details of the adenovirus vectored-vaccines manufacturing, see Chapter 11.
The OA vaccine was originally designed as a single dose vaccine, but due to
lower protection than expected (43% and 80% reduction in risk of emergent hos-
pitalization and severe infection, respectively), a booster dose was suggested
within 4–12 weeks of the initial dose. This booster dose resulted in an efficacy of
70.4% [49]. Clinical trials also demonstrated good safety results [50]. However,
vaccine rollout was notably temporarily ceased in March 2021 after reports of
thromboembolic events including several unexpected deaths. Among the 5 million
vaccine recipients at the time, there were 30 cases of thrombotic events, mostly
venous thromboembolisms that were believed to have occurred due to the gen-
eration of antibodies against platelet factor 4 resulting in a vaccine induced
thrombotic thrombocytopenia similar to a heparin induced thrombocytopenia [51].
Another adenoviral vector vaccine approved for emergency use against COVID-
19 is the Johnson & Johnson vaccine (J&J), also known as Ad26.COV2-S. The
vaccine uses an adenovirus serotype 26 as the vector and is administered as a single
dose. Phase 3 clinical trials demonstrated 66% and 85% protection against moderate
and severe disease, respectively, and 100% efficacy against COVID-19 induced
hospitalization and death [52,53].
One example of a heterologous vaccine approach is the Russian Sputnik V, also
known as Gam-COVID-Vac. They use two recombinant adenovirus vectors (Ad5
306
Bioprocessing of Viral Vaccines