On developing a process for conducting extractable-leachable assessment of components used for storage of biopharmaceuticals.

Extractables and leachables are product-related impurities that result from product contact with components such as gaskets, stoppers, storage bags, cartridges, and prefilled syringes that are used for processing, storage, and/or delivery of biopharmaceuticals. These impurities are a concern for patients due to potential effects on product quality and safety. It is possible that such an impurity could directly impact the patient or indirectly impact the patient by interacting with the protein therapeutics and forming protein adducts. Adducts and leachables may or may not be detected as product-related impurities in routine stability indicating assays depending on the rigor of the analytical program. The need for the development of a thorough and holistic extractable and leachable program based on risk assessment, review of existing literature, and consolidation of industry best practices is discussed. Standardizing component use within an organization enables streamlining of the extractable-leachable program. Our strategy for an extractable-leachable program is divided into different stages, each stage detailing the activities and the department within the organization that is responsible for execution of these activities. The roles and responsibilities of the key stakeholders are identified. The integration of analytical activities with health-based risk-assessment information into the design of an extractable-leachable program is highlighted.

A study in glycation of a therapeutic recombinant humanized monoclonal antibody: where it is, how it got there, and how it affects charge-based behavior.

The glycated form of a basic recombinant humanized monoclonal antibody (rhuMAb) was separated and quantitated by boronate affinity chromatography using optimized shielding reagents. Characterization on the isolated glycated material by peptide mapping analysis, using liquid chromatography-mass spectrometry (LC-MS) and tandem mass spectrometry (MS/MS) sequencing techniques, identified eight reactive lysine primary amine sites. The glycation reaction extent was similar among the various reactive sites, ranging from approximately 1 to 12%, and a single histidine residue separated the most and least reactive sites. Boronate chromatography run in a linear gradient mode separated monoglycated rhuMAb from higher order glycated species and indicated that the majority ( approximately 90%) of glycated rhuMAb is monoglycated. Low-level glycation on a heavy chain lysine located within a complementarity-determining region (CDR) did not significantly affect binding activity in potency measurements. The glycated forms also behaved as slightly more acidic than the nonglycated antibody in charge-based separation techniques, observable by capillary isoelectric focusing (cIEF) and ion exchange chromatography (IEC). The boronate column has significantly increased retention of aggregated rhuMAb material under separation conditions optimized for the monomer form. Recombinant protein glycation initially occurred during production in mammalian cell culture, where feed sugar and protein concentrations contribute to the total overall glycation on this antibody product.

Differential in vivo effects of rituximab on two B-cell subsets in cynomolgus monkeys.

Cynomolgus monkeys (Macaca fascicularis) are widely used animal models in biomedical research and have been used to study new therapeutics aimed at B-cell depletion. We have recently identified two different B-cell subsets in cynomolgus monkey, with the CD20lowCD40highCD21+ subset being phenotypically closer to human B cells and having a similar responsivness to anti-CD20 mAb, rituximab, in in vitro depletion assays. Here, we show that similar to in vitro findings CD20highCD40lowCD21- and CD20lowCD40highCD21+ cynomolgus monkey B cells differ significantly in their in vivo susceptibility to rituximab, as the low dose of 0.05 mg/kg of rituximab resulted in more than 70% depletion of the former B-cell subset and virtually no depletion of the latter B-cell subset. Our data suggest that for the B-cell-targeting anti-CD20 therapeutics, depletion of CD20lowCD40highCD21+ subset rather than depletion of all cynomolgus monkey B cells is more relevant to dose-efficacy projections for humans. In addition, we show that differential cell surface expression of CD80/CD86 costimulatory molecules on the two different cynomolgus monkey B-cell subsets is similar to that identified in rhesus monkeys, suggesting that our in vivo study may be relevant to other monkey models.

Effect of anti-CD20 monoclonal antibody, Rituxan, on cynomolgus monkey and human B cells in a whole blood matrix.

BACKGROUND: Cynomolgus monkeys are widely used animal models in biomedical research. The differences between cynomolgus monkey and human B cells are not completely understood. However, these differences are of crucial importance for interpretation of data from studies on new therapeutic agents aimed at B-cell depletion, such as anti-CD20 monoclonal antibodies. METHODS: Multicolor fluorescence-activated cell sorting analysis of peripheral blood B cells was performed on samples treated ex vivo with the anti-CD20 therapeutic monoclonal antibody, Rituxan, in a whole blood matrix. RESULTS: In contrast to humans, cynomolgus monkeys had two distinct B-cell subsets, CD20highCD40lowCD21- and CD20lowCD40highCD21+. These B-cell subsets had a 2.5-fold difference in the EC50 for Rituxan binding and differed significantly in their in vitro susceptibility to Rituxan depletion. Human B cells were similar to the CD20lowCD40highCD21+ cynomolgus monkey B cells with regard to their EC50 for Rituxan and response to Rituxan in a whole blood matrix assay. CD21 was upregulated, whereas CD40 was downregulated at incubation with Rituxan in the CD20lowCD40highCD21+ monkey and human B cells in a concentration-dependent manner. CONCLUSIONS: These findings have direct implications for in vivo studies of therapeutic agents that target B cells in cynomolgus monkeys and for extrapolation of the results to humans. In addition, our data are consistent with the model in which CD20, CD21, and CD40 exist in a supramolecular complex that is affected by anti-CD20 monoclonal antibodies.