Abstract
BACKGROUND: The foot and mouth disease virus (FMDV) remains a significant threat to livestock health and agricultural economies, particularly in endemic regions such as Egypt. Although suspension cultures of baby hamster kidney (BHK)-21 cells are widely used for FMD vaccine production. Suspension cells play a vital role in biomanufacturing, but their high cost often limits their accessibility. This straightforward method offers an efficient and economical solution for obtaining BHK-adapted suspension cells that are ideal for large-scale cultivation in bioreactors. AIM: We developed a simplified and cost-effective method for adapting BHK-21 cells to suspension culture using a progressive accelerated rolling system, eliminating the need for microcarriers or complex bioreactor systems. The resulting suspension-adapted cells (BHK-S) were assessed for growth kinetics, sterility, postthaw viability, and their ability to support FMDV replication and 146S antigen production. METHODS: Conversion of adherent BHK-21 to BHK suspension was performed, followed by investigation of cell counts, cell viability, cell morphology, and growth curve analysis. RESULTS: BHK-S cells demonstrated robust growth with >95% viability and a density of 2 × 10(6) cells/ml. After FMDV infection, suspension cultures yielded significantly higher virus titers (>10(8) TCID(50)/ml) compared with adherent cultures (10(6.8) TCID(50)/ml; p < 0.001). Furthermore, 146S antigen yield was substantially improved, with suspension cultures producing 4.4 µg/ml compared to 1.5 µg/ml in adherent cells. Scale-up to a 10L bioreactor confirmed the stability of growth parameters and viral productivity. CONCLUSION: This streamlined and scalable approach for adapting BHK-21 cells to suspension culture offers a practical and affordable alternative for FMD vaccine production in resource-limited settings, facilitating the transition from bench-to-bioprocessing scale.