A Flow Imaging Microscopy-Based Method Using Mass-to-Volume Ratio to Derive the Porosity of PLGA Microparticles.

The release of drugs from poly(lactic-co-glycolic acid) (PLGA) microparticles depends to a large extent on the porosity of the particles. Therefore, porosity determination of PLGA microparticles is extremely important during pharmaceutical product development. Currently, mercury intrusion porosimetry (MIP) is widely used despite its disadvantages, such as the need for a large amount of sample (several hundreds of milligrams) and residual toxic waste.

Micro-Flow Imaging as a quantitative tool to assess size and agglomeration of PLGA microparticles.

The purpose of this study was to explore the potential of flow imaging microscopy to measure particle size and agglomeration of poly(lactic-co-glycolic acid) (PLGA) microparticles. The particle size distribution of pharmaceutical PLGA microparticle products is routinely determined with laser diffraction. In our study, we performed a unique side-by-side comparison between MFI 5100 (flow imaging microscopy) and Mastersizer 2000 (laser diffraction) for the particle size analysis of two commercial PLGA microparticle products, i.

Control of IgG LC:HC ratio in stably transfected CHO cells and study of the impact on expression, aggregation, glycosylation and conformational stability.

Immunoglobulin G (IgG), the most common class of commercial monoclonal antibodies (mAbs), exists as multimers of two identical light chains (LC) and two identical heavy chains (HC) assembled together by disulfide bridges. Due to the kinetics of mAb assembly, it is suggested that expression of LC and HC in equal amounts is not optimal for IgG production. We designed a set of vectors using internal ribosome entry site (IRES) elements to control LC and HC expression.

Identification of oxidation sites and covalent cross-links in metal catalyzed oxidized interferon Beta-1a: potential implications for protein aggregation and immunogenicity.

Oxidation via Cu(2+)/ascorbate of recombinant human interferon beta-1a (IFNβ1a) leads to highly immunogenic aggregates, however it is unknown which amino acids are modified and how covalent aggregates are formed. In the present work we mapped oxidized and cross-linked amino acid residues in aggregated IFNβ1a, formed via Cu(2+)/ascorbate catalyzed oxidation. Size exclusion chromatography (SEC) was used to confirm extensive aggregation of oxidized IFNβ1a.

Minimizing immunogenicity of biopharmaceuticals by controlling critical quality attributes of proteins.

Adverse immune responses severely hamper the success of biopharmaceutical therapies. Possible clinical consequences include anaphylaxis, reduced drug half-life and neutralization of the therapeutic protein as well as the endogenous human homologue. Controlling potential triggers of the immune system helps to minimize the immunogenicity of biopharmaceuticals, a crucial consideration in biopharmaceutical manufacturing.

Antibody response against Betaferon® in immune tolerant mice: involvement of marginal zone B-cells and CD4+ T-cells and apparent lack of immunological memory.

Purpose: The immunological processes underlying immunogenicity of recombinant human therapeutics are poorly understood. Using an immune tolerant mouse model we previously demonstrated that aggregates are a major trigger of the antidrug antibody (ADA) response against recombinant human interferon beta (rhIFNβ) products including Betaferon®, and that immunological memory seems to be lacking after a rechallenge with non-aggregated rhIFNβ. The apparent absence of immunological memory indicates a CD4+ T-cell independent (Tind) immune response underlying ADA formation against Betaferon®.

Immunogenicity of recombinant human interferon beta interacting with particles of glass, metal, and polystyrene.

Aggregates play a major role in the immunogenicity of recombinant human interferon beta (rhIFNβ), a protein used to treat multiple sclerosis. A possible cause of aggregation is interaction between therapeutic protein and surfaces encountered during processing, storage, and administration. Moreover, proteins may adsorb to particles shed from these surfaces.

Oxidized and aggregated recombinant human interferon beta is immunogenic in human interferon beta transgenic mice.

Purpose: To study the effect of oxidation on the structure of recombinant human interferon beta-1a (rhIFNβ-1a) and its immunogenicity in wild-type and immune-tolerant transgenic mice.

Methods: Untreated rhIFNβ-1a was degraded by metal-catalyzed oxidation, H(2)O(2)-mediated oxidation, and guanidine-mediated unfolding/refolding. Four rhIFNβ-1a preparations with different levels of oxidation and aggregation were injected intraperitoneally in mice 15× during 3 weeks.

On the role of aggregates in the immunogenicity of recombinant human interferon beta in patients with multiple sclerosis.

Like many other therapeutic proteins, recombinant human interferon beta (rhIFN-β) elicits undesirable immune responses. rhIFN-β-treated multiple sclerosis patients may form binding antibodies and neutralizing antibodies (NAbs), with the latter being responsible for inhibition of the therapeutic effect of the protein. The incidence of binding antibodies and NAbs against rhIFN-β as well as the titer and persistence of NAbs differ among the marketed products.

Aggregated recombinant human interferon Beta induces antibodies but no memory in immune-tolerant transgenic mice.

Purpose: To study the influence of protein aggregation on the immunogenicity of recombinant human interferon beta (rhIFNbeta) in wild-type mice and transgenic, immune-tolerant mice, and to evaluate the induction of immunological memory.

Methods: RhIFNbeta-1b and three rhIFNbeta-1a preparations with different aggregate levels were injected intraperitoneally in mice 15x during 3 weeks, and the mice were rechallenged with rhIFNbeta-1a. The formation of binding (BABs) and neutralizing antibodies (NABs) was monitored.

Hybrid transgenic immune tolerant mouse model for assessing the breaking of B cell tolerance by human interferon beta.

To date, the therapeutic efficacy of recombinant human proteins is limited by their potential to break B cell tolerance in patients. The formation of neutralising antibodies (NABs) directed against recombinant human interferon beta (rhIFNbeta) is associated with a decrease in the therapeutic effect of the protein. For this reason, there is a need to study factors that can cause the immunogenicity of rhIFNbeta.

Development of a bioassay for quantification of neutralising antibodies against human interferon-beta in mouse sera.

Therapeutic proteins like recombinant human interferon-beta (rhIFNbeta) may induce neutralising antibodies (NABs), which inhibit their efficacy. Hence, there is a great need for strategies to predict whether a formulation will induce an immune response. Immune tolerant transgenic animals are important tools to study this phenomenon.

Allergen Ara h 1 occurs in peanuts as a large oligomer rather than as a trimer.

Ara h 1, a major peanut allergen, is known as a stable trimeric protein. Nevertheless, upon purification of native Ara h 1 from peanuts using only size exclusion chromatography, the allergen appeared to exist in an oligomeric structure, rather than as a trimeric structure. The oligomeric structure was independent of the salt concentration applied.