In-situ biophysical characterization of high-concentration protein formulations using w NMR

MAbs. 2024 Jan-Dec;16(1):2304624. doi: 10.1080/19420862.2024.2304624. Epub 2024 Feb 1.

Abstract

High-concentration protein formulation is of paramount importance in patient-centric drug product development, but it also presents challenges due to the potential for enhanced aggregation and increased viscosity. The analysis of critical quality attributes often necessitates the transfer of samples from their primary containers together with sample dilution. Therefore, there is a demand for noninvasive, in situ biophysical methods to assess protein drug products directly in primary sterile containers, such as prefilled syringes, without dilution. In this study, we introduce a novel application of water proton nuclear magnetic resonance (wNMR) to evaluate the aggregation propensity of a high-concentration drug product, Dupixent® (dupilumab), under stress conditions. wNMR results demonstrate a concentration-dependent, reversible association of dupilumab in the commercial formulation, as well as irreversible aggregation when exposed to accelerated thermal stress, but gradually reversible aggregation when exposed to freeze and thaw cycles. Importantly, these results show a strong correlation with data obtained from established biophysical analytical tools widely used in the pharmaceutical industry. The application of wNMR represents a promising approach for in situ noninvasive analysis of high-concentration protein formulations directly in their primary containers, providing valuable insights for drug development and quality assessment.

Keywords: Accelerated stress; NMR; biologics; drug product stability; high-concentration drug product; mABs; protein aggregation; wNMR.

MeSH terms

  • Drug Industry* / methods
  • Magnetic Resonance Spectroscopy*
  • Viscosity
  • Water / chemistry

Substances

  • Water

Grants and funding

The collaboration received funding from Merck & Co., Inc., Rahway, NJ, USA and was partially supported by the MPower from the University of Maryland to Y.B.Y.