Vasco Filipe

Mass Spectrometric Analysis of Intact Human Monoclonal Antibody Aggregates Fractionated by Size-Exclusion Chromatography

ABSTRACTPurposeThe aim of this study was to develop a method to characterize intact soluble monoclonal IgG1 antibody (IgG) oligomers by mass spectrometry.MethodsIgG aggregates (dimers, trimers, tetramers and high-molecular-weight oligomers) were created by subjecting an IgG formulation to several pH jumps. Protein oligomer fractions were isolated by high performance size exclusion chromatography (HP-SEC), dialyzed against ammonium acetate pH 6.0 (a mass spectrometry-compatible volatile buffer), and analyzed by native electrospray ionization time-of-flight mass spectrometry (ESI-TOF MS).ResultsMonomeric and aggregated IgG fractions in the stressed IgG formulation were successfully isolated by HP-SEC. ESI-TOF MS analysis enabled us to determine the molecular weight of the monomeric IgG as well as the aggregates, including dimers, trimers and tetramers. HP-SEC separation and sample preparation proved to be necessary for good quality signal in ESI-TOF MS. Both the HP-SEC protocol and the ESI-TOF mass spectrometric technique were shown to leave the IgG oligomers largely intact.ConclusionsESI-TOF MS is a useful tool complementary to HP-SEC to identify and characterize small oligomeric protein aggregates.

Photodynamic therapy with conventional and PEGylated liposomal formulations of mTHPC (temoporfin): comparison of treatment efficacy and distribution characteristics in vivo

A major challenge in the application of a nanoparticle-based drug delivery system for anticancer agents is the knowledge of the critical properties that influence their in vivo behavior and the therapeutic performance of the drug. The effect of a liposomal formulation, as an example of a widely-used delivery system, on all aspects of the drug delivery process, including the drug’s behavior in blood and in the tumor, has to be considered when optimizing treatment with liposomal drugs, but that is rarely done. This article presents a comparison of conventional (Foslip®) and polyethylene glycosylated (Fospeg®) liposomal formulations of temoporfin (meta-tetra[hydroxyphenyl]chlorin) in tumor-grafted mice, with a set of comparison parameters not reported before in one model. Foslip® and Fospeg® pharmacokinetics, drug release, liposome stability, tumor uptake, and intratumoral distribution are evaluated, and their influence on the efficacy of the photodynamic treatment at different light–drug intervals is discussed. The use of whole-tumor multiphoton fluorescence macroscopy imaging is reported for visualization of the in vivo intratumoral distribution of the photosensitizer. The combination of enhanced permeability and retention-based tumor accumulation, stability in the circulation, and release properties leads to a higher efficacy of the treatment with Fospeg® compared to Foslip®. A significant advantage of Fospeg® lies in a major decrease in the light–drug interval, while preserving treatment efficacy.

Asymmetrical Flow Field-Flow Fractionation Method for the Analysis of Submicron Protein Aggregates

For the analysis of protein aggregates in the submicron size range, there is still a need for reliable, quantitative methods that can assist the development of therapeutic protein formulations. The aim of our study was to develop an asymmetrical flow field-flow fractionation (AF4) method for the analysis of protein aggregates in the size range of up to approximately 1000 nm. Method development was performed with polystyrene standard beads (60, 200, and 1000 nm) and a heat-stressed IgG formulation containing a substantial amount of submicron aggregates. By AF4, the analysis of these heterodisperse submicron IgG aggregates, as well as the monomer, could be achieved by a stepwise reduction of the cross-flow. The suitability of the developed AF4 method for aggregate analysis in general was demonstrated by analyzing several other stressed therapeutic protein samples (another IgG and etanercept). In each case, a clearly better separation and a more reproducible (although in some cases incomplete) recovery was achieved with AF4 as compared with high-performance size-exclusion chromatography. In conclusion, AF4 proved to be a valuable method for the characterization and quantification of submicron protein aggregates.

Transient Molten Globules and Metastable Aggregates Induced by Brief Exposure of a Monoclonal IgG to Low pH

The presence of aggregates in therapeutic protein formulations is of great concern due to quality, safety, and efficacy issues. Nonetheless, the mechanisms and kinetics of protein aggregation are only partly understood. In this study, metastable immunoglobulin G (IgG) aggregates induced by a brief exposure to pH 1 were kept at 4°C and analyzed over time by size-exclusion chromatography (SEC), nanoparticle tracking analysis, light obscuration, dynamic light scattering, fluorescence spectroscopy, and circular dichroism. The results show the formation of polydisperse aggregates (from dimers to 10-μm particles) shortly after the pH-shift stress. These aggregates increased in size and number over time until a pseudo-equilibrium was reached after 5-7 days. The presence of transient, partially unfolded monomers (molten globules) was detected by SEC with online fluorescent dye detection. The molten globules seemed to either refold into the native state or become involved in aggregation pathways. Seeding pH-shift-induced aggregates into unstressed IgG did not accelerate aggregation during incubation for 3 weeks at 55°C. These results reinforce the role of partially unfolded species in the aggregation of therapeutic proteins. We conclude that the formation of pH-shift-induced IgG aggregates is likely driven by downhill polymerization, as a consequence of successive additions of molten globular monomers.

Stability of rituximab in freeze‐dried formulations containing trehalose or melibiose under different relative humidity atmospheres

The objective of the study was to compare the effectiveness of trehalose with that of melibiose in protecting a monoclonal antibody (rituximab) from aggregation, fragmentation, and secondary structure alterations during processing and subsequent storage. Because reducing disaccharides such as melibiose participate in Maillard reaction with proteins, especially in the presence of water, the lyophilizates were stored under different relative humidity (RH 5%, 11%, and 23%) atmospheres. Freeze drying was shown to cause clear alterations in rituximab secondary structure, an increase in noncovalent protein aggregation, and in some cases fragmentation. However, these changes were less pronounced in the formulation containing melibiose. Storing the lyophilizates under low RH (5%) proved to be most harmful to the stability of rituximab, intensifying secondary structure alterations and increasing protein aggregate content. Again, these changes were less aggravated in the formulation containing melibiose. Surprisingly, the concentration of aggregates larger than 1 μm decreased in some cases during storage at RH 11% and 23%. There was no indication that storage even under the highest RH (23%) would have caused significant amounts of Maillard reaction end products to be formed during 3 months of storage.