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INTRODUCTION: SB15 is a proposed biosimilar product of reference aflibercept (Eylea®), an approved biological drug product for retinal diseases including neovascular age-related macular degeneration (nAMD). This study aimed to assess the analytical similarity between SB15 and its commercially available reference product (RP) sourced from the United States (US-aflibercept) and European Union (EU-aflibercept) in terms of structural, physicochemical, and biological properties. METHODS: A panel of state-of-the-art analytical methods was used for the comprehensive characterization of SB15 and US/EU-aflibercept. In terms of the structural and physicochemical properties, primary structure; post-translational modifications (PTM); higher-order structure; purity and impurities; charge variants; and glycosylation were compared. In addition, biological characterization including mechanism of action (MoA)-related and Fc-related biological activities was conducted. RESULTS: Analytical similarity between SB15 and US/EU-aflibercept was demonstrated. The primary and higher-order structure of SB15 was confirmed to be comparable to that of US/EU-aflibercept. In addition, there were no meaningful differences in the physicochemical properties in terms of size and charge heterogeneity between SB15 and its RP. SB15 and RP were similar in biological activities including MoA-related binding activities, potencies, and Fc-related biological functions. Consequently, SB15 was confirmed to be highly similar to US/EU-aflibercept. CONCLUSIONS: Based on a comprehensive analytical similarity assessment of structural, physicochemical, and biological properties, SB15 was demonstrated to be highly similar to US/EU-aflibercept RP, supporting safe and effective use of SB15.
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INTRODUCTION: SB11 was recently approved as a ranibizumab biosimilar by the US Food and Drug Administration (FDA) and the European Commission (EC) as a therapy for retinal vascular disorders under the brand name Byooviz™. This study was performed to assess the analytical similarity between SB11 and reference products from the European Union (EU-ranibizumab) and United States (US-ranibizumab). METHODS: A comprehensive structural, physicochemical, and biological characterization was performed utilizing state-of-the-art analytical methods. Comparisons included the following: primary structure related to amino acid sequence and post-translational modifications; higher order structure; product-related substances and purity/impurity including size and charge variants. In addition, biological characterization included a series of mechanism of action (MoA)-related bioassays such as vascular endothelial growth factor (VEGF)-A binding assay (VEGF-A 165 and its isoforms), cell-based VEGF-A 165 neutralization assay, and anti-proliferation assay using human umbilical vein endothelial cells (HUVEC). RESULTS: The amino acid sequence of SB11 was identical to that of reference products, and post-translational modification profiles and higher order structures of SB11 were shown to be indistinguishable from the reference products. Product-related size and charge variants and aggregates were also similar. Using a broad range of VEGF-related functional assays, we demonstrated that SB11 has similar biological properties to reference products in VEGF-A binding activities (VEGF-A 165 and isoforms (VEGF-A 110, VEGF-A 121, and VEGF-A 189)), VEGF-A 165 neutralization, and HUVEC anti-proliferation. Overall, SB11 exhibits high similarity compared to EU/US-ranibizumab. CONCLUSION: Based on the comprehensive analytical similarity assessment, SB11 is highly similar to the EU/US-ranibizumab with respect to structural, physicochemical, and biological properties.
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We previously demonstrated that cell-surface gC1qR is a key regulator of lamellipodia formation and cancer metastasis. Here, we screened a monoclonal mouse antibody against gC1qR to prevent cell migration by neutralizing cell-surface gC1qR. The anti-gC1qR antibody prevented growth factor-stimulated lamellipodia formation, cell migration and focal adhesion kinase activation by inactivating receptor tyrosine kinases (RTKs) in various cancer cells such as A549, MDA-MB-231, MCF7 and HeLa cells. The antibody neutralization of cell-surface gC1qR also inhibited angiogenesis because the anti-gC1qR antibody prevented growth factor-stimulated RTK activation, lamellipodia formation, cell migration and tube formation in HUVEC. In addition, we found that A549 tumorigenesis was reduced in a xenograft mouse model by following the administration of the anti-gC1qR antibody. With these data, we can conclude that the antibody neutralization of cell-surface gC1qR could be a good therapeutic strategy for cancer treatment.