Characterisation of protein aggregation with the Smoluchowski coagulation approach for use in biopharmaceuticals.

Mitja Zidar,Drago Kuzman,Miha Ravnik

doi:10.1039/c8sm00919h

Mitja Zidar, Drago Kuzman + Show 1 more

Open Access

https://doi.org/10.1039/c8sm00919h

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Journal: Soft matter	Publication Date: Jan 1, 2018
Citations: 35	License type: CC BY 3.0

Affiliation: University of Ljubljana, Novartis (China)

Abstract

Protein aggregation is a field of increasing importance in the biopharmaceutical industry. Aggregated particles decrease the effectiveness of the drug and are associated with other risks, such as increased immunogenicity. This article explores the possibility of using the Smoluchowski coagulation equation and similar models in the prediction of aggregate-particle formation. Three different monoclonal antibodies, exhibiting different aggregation pathways, are analysed. Experimental data are complemented with aggregation dynamics calculated by a coagulation model. Different processes are implemented in the coagulation equation approach, needed to cover the actual phenomena observed in the aggregation of biopharmaceuticals, such as the initial conformational change of the native monomer and reversibility of smaller oligomers. When describing the formation of larger particles, the effect of different aggregation kernel parameters on the corresponding particle size distribution is studied. A significant impact of the aggregate fractal nature on overall particle size distribution is also analysed. More generally, this work is aimed to establish a mesoscopic phenomenological approach for characterisation of protein aggregation phenomena in the context of biopharmaceuticals, capable of covering various aggregate size scales from nanometres to micrometres and reach large time-scales, up to years, as needed for drug development.

Highlights

Aggregated particles are unable to perform biological functions of native protein
This study explores protein aggregation dynamics from the distinct perspective of biopharmaceutical design
Experimental data from three different mAbs are presented and complemented with a coagulation model based on the modified Smoluchowski coagulation equation

Summary

Introduction

Aggregated particles are unable to perform biological functions of native protein. What is more, they can trigger an immune response in the patient, resulting in rejection of the drug. The conformational as well as colloidal stability of the proteins and their biological functions depend on various solution properties, including pH, temperature and presence of other molecules in the solution, such as salts and sugars.[10,11,12,13] Even small changes in these environmental conditions greatly affect the long-term stability and efficacy of the drug via their impact on hydrophobic interactions, electrostatic interactions, van der Waals forces and other contributions to the total intra- and inter-molecular potential. Protein aggregation is a process which spans multiple size scales, from the nanometre scale of individual protein macromolecules to the visible particles, comprised of millions of these elementary building blocks.

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