Physicochemical and biological similarity assessment of LBAL, a biosimilar to adalimumab reference product (Humira®).

LBAL was developed as an adalimumab (Humira®) biosimilar using Chinese hamster ovary cell lines. Comparable quality, safety, and efficacy between a biosimilar and its reference product should be ensured for regulatory approval. Here, we present the results of a comprehensive physicochemical and biological characterization between LBAL and Humira®. As physicochemical attributes, primary and higher-order structure, N-glycan profile, and disulfide linkage were investigated. Biological attributes were evaluated by target/receptor binding analysis and in vitro/ex vivo cell-based assays, which are linked to mechanisms of action. As a result, LBAL had the identical amino acid sequence, similar post-translational modifications and N-/C-terminal variants, and comparable primary, secondary, and tertiary structures and disulfide linkage profile. However, some differences in N-glycan profiles were observed. Biological activities, including tumor necrosis factor (TNF) binding, TNF-neutralization, apoptosis, Fc receptor binding, and complement-dependent cytotoxicity, were largely consistent. Despite a slightly lower antibody-dependent cellular cytotoxicity activity in LBAL, this difference was not significant under physiological conditions. As indicated, this extensive analytical characterization and functional comparison assessment showed that LBAL was similar to Humira®, with minor differences of no clinical relevance. Taken together, our comparative assessment of physicochemical and biological attributes demonstrated that LBAL is structurally and functionally very similar to Humira®, supporting the biosimilarity of clinical efficacy and safety.

Comprehensive Physicochemical and Biological Characterization of the Proposed Biosimilar Darbepoetin Alfa, LBDE, and Its Originator Darbepoetin Alfa, NESP®.

BACKGROUND: For regulatory approval, the comparability of a biosimilar product to an originator product should be ensured through thorough physicochemical and biological characterization. OBJECTIVE: To evaluate the biosimilarity between LBDE, the proposed biosimilar darbepoetin alfa, and NESP®, its originator, we performed a comprehensive physicochemical and biological characterization study. METHODS: Primary and higher-order protein structures were analyzed using Lys-C peptide mapping with liquid chromatography-mass spectrometry (LC-MS), disulfide bond identification, circular dichroism, and fluorescence spectroscopy. Glycosylation and isoform distribution were analyzed using MS, LC, and capillary zone electrophoresis. Size variants were evaluated with size-exclusion chromatography-high-performance liquid chromatography (SEC-HPLC) and sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). Biological characterization included binding affinity for human erythropoietin receptor, in vitro cell proliferation, and in vivo potency. Pharmacokinetics (PK) were evaluated using rats through two injection routes. RESULTS: Non-reducing and reducing Lys-C peptide mapping showed a highly similar peak profile, confirming that LBDE and NESP® have the same primary structure and disulfide bonds. Glycosylation and isoform analyses showed that the attached N-glycan and O-glycan structures were the same and their relative contents were similar. Spectroscopic analysis of LBDE showed indistinguishable spectra with NESP®. For both LBDE and NESP®, a very small amount of size variants was found in SEC-HPLC, and no minor bands were detected in SDS-PAGE. Furthermore, LBDE did not show any difference with NESP® in the in vitro and in vivo functional analyses. PK parameters of LBDE were in good agreement with those of NESP®. CONCLUSION: LBDE shows high similarity to NESP® with regard to structure and function.

Effect of D-allose on prostate cancer cell lines: phospholipid profiling by nanoflow liquid chromatography-tandem mass spectrometry.

D-Allose, a rare, naturally occurring monosaccharide, is known to exert anti-proliferative effects on cancer cells. The effects of D-allose on the cellular membranes of hormone-refractory prostate cancer cell line (DU145), hormone-sensitive prostate cancer cell line (LNCaP), and normal prostate epithelial cells (PrEC) were studied at the molecular level by phospholipid (PL) profiling using a shotgun lipidomic method. The molecular structures of 85 PL species including 23 phosphatidylcholines, 12 phosphatidylethanolamines (PEs), 11 phosphatidylserines (PSs), 16 phosphatidylinositols, 9 phosphatidic acids (PAs), and 14 phosphatidylglycerols (PGs) were identified by data-dependent collision-induced dissociation of nanoflow liquid chromatography-tandem mass spectrometry, and the PL amounts were quantified. The addition of D-allose to prostate cancer cell lines during their growth phases had negligible or decreased effects on the relative regulation of PL species, but several new PS molecules (two for DU145 and three for LNCaP) emerged. In contrast, experiments on the PrEC cell line revealed that some high abundant species (14:0/14:0-PE, 16:2/16:0-PG, and 20:6/18:1-PA) showed significant increases in concentration. These findings support a mechanism for the anti-proliferative effect of D-allose on prostate cancer cell lines that involves the induction of programmed cell death since PS molecules are known to induce apoptosis. Principal component analysis was carried out to examine differences in PL distributions among the three cell lines promoted by D-allose.