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Process validation studies to determine the ability of the downstream process to remove and/or inactivate potential viral contamination must be performed prior to clinical trials. These studies use either specific or model viruses depending upon the cell substrate or the tissue used. By spiking these viruses at known titers directly into a down-scaled version of the purification step to be studied, the effectiveness of its ability to inactivate or remove viruses is quantified by determining the log reductions factor. Examples of specific or model viruses routinely used for such studies are shown in the following table:
|
Envelope
|
Genome
|
Virus
|
Size in nm
|
Stability
|
|
yes
|
ssRNA
|
Para influenza
|
100 - 200
|
low
|
|
Sindbis
|
60 - 70
|
low
|
|
Bovine viral diarrhea
|
50 - 70
|
low
|
|
Murine leukemia
|
80 - 110
|
low
|
|
West nile virus
|
50 - 70
|
low
|
|
Human immunodeficiency
|
80 - 100
|
low
|
|
dsDNA
|
Bovine herpes
|
100 - 200
|
low - medium
|
|
Pseudo rabies
|
120 - 200
|
medium
|
|
no
|
dsRNA
|
Reo 3
|
60 - 80
|
medium
|
|
ssRNA
|
Encephalomyocarditis
|
20 - 30
|
medium - high
|
|
Hepatitis A
|
25 - 30
|
medium - high
|
|
Polio type 1
|
25 - 30
|
high
|
|
dsDNA
|
Simian 40 (SV-40)
|
40 - 50
|
high
|
|
ssDNA
|
Minute virus of mice
|
18 - 24
|
very high
|
|
Porcine parvo
|
18 - 24
|
very high
|
Prior to the main viral safety study, cytotoxicity and interference tests must be performed to ensure that it is the process that is removing or inactivating the virus and not the matrix itself. Once these tests have been performed, the viral safety study is performed using end point titrations in a TCID50 assay.
With more than 10 years experience in viral safety studies, NewLab has conducted more than 800 studies so far. The reports have been accepted by authorities worldwide including FDA, EMEA, PEI and the Japanese Ministry of Health.
Examples of some process steps which have been studied at NewLab BioQuality include:
| Process steps studied in the biotech industry |
| |
| Chromatography |
| Anion and cation exchange |
| Affinity |
| Hydrophobic interaction |
| Size exclusion |
| Membrane adsorption |
| Nanofiltration |
| Ultrafiltration |
| High temperature, short heat time treatments |
| pH inactivation |
| UVC inactivation |
| Process steps studied from the blood and plasma industry |
| Cohn / Kistler-Nitschmann fractionation |
| - Precipitation A |
| - Precipitation IV |
| - Precipitation C |
| Pasteurization |
| Dry heat treatment |
| Solvent / detergent treatment |
| Methylene blue / light treatment |
| pH inactivation |
| Treatment with intercalating agents |
| UV / beta-propiolactone treatment |
| Treatment with octanoic acid |
| PEG precipitation |
| Nanofiltration |
| Process steps studied from other industries |
| Vaccine industry |
| Inactivation by formaldehyde treatment |
| |
| Other biological products such as collagen, heparin, pancreatic enzymes, etc |
| Gamma irradiation |
| Oxidative treatment using H2O2 |
| Treatment with organic solvents such as acetone, acetonitrile, ethanol etc |
| Guanidine HCl treatment |
| Precipitation |
| UVC inactivation |
|