TY - JOUR
T1 - Evaluation of a downstream process for the recovery and concentration of a Cell-Culture-Derived rVSV-Spike COVID-19 vaccine candidate
AU - Makovitzki, Arik
AU - Lerer, Elad
AU - Kafri, Yaron
AU - Adar, Yaakov
AU - Cherry, Lilach
AU - Lupu, Edith
AU - Monash, Arik
AU - Levy, Rona
AU - Israeli, Ofir
AU - Dor, Eyal
AU - Epstein, Eyal
AU - Levin, Lilach
AU - Toister, Einat
AU - Hefetz, Idan
AU - Hazan, Ophir
AU - Simon, Irit
AU - Tal, Arnon
AU - Girshengorn, Meni
AU - Tzadok, Hanan
AU - Rosen, Osnat
AU - Oren, Ziv
N1 - Publisher Copyright:
© 2021 Elsevier Ltd
PY - 2021/11/26
Y1 - 2021/11/26
N2 - rVSV-Spike (rVSV-S) is a recombinant viral vaccine candidate under development to control the COVID-19 pandemic and is currently in phase II clinical trials. rVSV-S induces neutralizing antibodies and protects against SARS-CoV-2 infection in animal models. Bringing rVSV-S to clinical trials required the development of a scalable downstream process for the production of rVSV-S that can meet regulatory guidelines. The objective of this study was the development of the first downstream unit operations for cell-culture-derived rVSV-S, namely, the removal of nucleic acid contamination, the clarification and concentration of viral harvested supernatant, and buffer exchange. Retaining the infectivity of the rVSV-S during the downstream process was challenged by the shear sensitivity of the enveloped rVSV-S and its membrane protruding spike protein. Through a series of screening experiments, we evaluated and established the required endonuclease treatment conditions, filter train composition, and hollow fiber-tangential flow filtration parameters to remove large particles, reduce the load of impurities, and concentrate and exchange the buffer while retaining rVSV-S infectivity. The combined effect of the first unit operations on viral recovery and the removal of critical impurities was examined during scale-up experiments. Overall, approximately 40% of viral recovery was obtained and the regulatory requirements of less than 10 ng host cell DNA per dose were met. However, while 86–97% of the host cell proteins were removed, the regulatory acceptable HCP levels were not achieved, requiring subsequent purification and polishing steps. The results we obtained during the scale-up experiments were similar to those obtained during the screening experiments, indicating the scalability of the process. The findings of this study set the foundation for the development of a complete downstream manufacturing process, requiring subsequent purification and polishing unit operations for clinical preparations of rVSV-S.
AB - rVSV-Spike (rVSV-S) is a recombinant viral vaccine candidate under development to control the COVID-19 pandemic and is currently in phase II clinical trials. rVSV-S induces neutralizing antibodies and protects against SARS-CoV-2 infection in animal models. Bringing rVSV-S to clinical trials required the development of a scalable downstream process for the production of rVSV-S that can meet regulatory guidelines. The objective of this study was the development of the first downstream unit operations for cell-culture-derived rVSV-S, namely, the removal of nucleic acid contamination, the clarification and concentration of viral harvested supernatant, and buffer exchange. Retaining the infectivity of the rVSV-S during the downstream process was challenged by the shear sensitivity of the enveloped rVSV-S and its membrane protruding spike protein. Through a series of screening experiments, we evaluated and established the required endonuclease treatment conditions, filter train composition, and hollow fiber-tangential flow filtration parameters to remove large particles, reduce the load of impurities, and concentrate and exchange the buffer while retaining rVSV-S infectivity. The combined effect of the first unit operations on viral recovery and the removal of critical impurities was examined during scale-up experiments. Overall, approximately 40% of viral recovery was obtained and the regulatory requirements of less than 10 ng host cell DNA per dose were met. However, while 86–97% of the host cell proteins were removed, the regulatory acceptable HCP levels were not achieved, requiring subsequent purification and polishing steps. The results we obtained during the scale-up experiments were similar to those obtained during the screening experiments, indicating the scalability of the process. The findings of this study set the foundation for the development of a complete downstream manufacturing process, requiring subsequent purification and polishing unit operations for clinical preparations of rVSV-S.
KW - Clarification
KW - Downstream process
KW - Endonuclease digestion
KW - Hollow fiber
KW - SARS-CoV-2
KW - rVSV
UR - http://www.scopus.com/inward/record.url?scp=85118355968&partnerID=8YFLogxK
U2 - 10.1016/j.vaccine.2021.10.045
DO - 10.1016/j.vaccine.2021.10.045
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C2 - 34756612
AN - SCOPUS:85118355968
SN - 0264-410X
VL - 39
SP - 7044
EP - 7051
JO - Vaccine
JF - Vaccine
IS - 48
ER -