Blaž Lebar, Mitja Zidar, Janez Mravljak, Roman Šink, Aleš Žula, Stane Pajk
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引用次数: 0
Abstract
The formulation of biopharmaceutical drugs is designed to eliminate chemical instabilities, increase conformational and colloidal stability of proteins, and optimize interfacial stability. Among the various excipients involved, buffer composition plays a pivotal role. However, conventional buffers like histidine and phosphate buffers may not always be the optimal choice for all monoclonal antibodies (mAbs). In this study, we investigated the effects of several alternative buffer systems on seven different mAbs, exploring various combinations of ionic strengths, concentrations of the main buffer component, mAb concentrations, and stress conditions. Protein stability was assessed by analyzing soluble aggregate formation through size exclusion chromatography. At low protein concentrations, protein instability after temperature stress was exclusively observed in the bis-TRIS/ glucuronate buffer. Conversely, freeze-thaw stress led to a significant increase in aggregate formation in tested formulations, highlighting the efficacy of several alternative buffers, particularly arginine/ citrate, in preserving protein stability. Under temperature stress, the introduction of arginine to histidine buffer systems provided additional stabilization, while the addition of lysine resulted in protein destabilization. Similarly, the incorporation of arginine into histi-dine/HCl buffer further enhanced protein stability during freeze--thaw cycles. At high protein concentrations, the histidine/citrate buffer emerged as one of the most optimal choices for addressing temperature and light-induced stress. The efficacy of histidine buffers in combating light stress might be attributed to the light-absorbing properties of histidine molecules. Our findings demonstrate that the development of biopharmaceutical formulations should not be confined to conventional buffer systems, as numerous alternative options exhibit comparable or even superior performance.
期刊介绍:
AP is an international, multidisciplinary journal devoted to pharmaceutical and allied sciences and contains articles predominantly on core biomedical and health subjects. The aim of AP is to increase the impact of pharmaceutical research in academia, industry and laboratories. With strong emphasis on quality and originality, AP publishes reports from the discovery of a drug up to clinical practice. Topics covered are: analytics, biochemistry, biopharmaceutics, biotechnology, cell biology, cell cultures, clinical pharmacy, drug design, drug delivery, drug disposition, drug stability, gene technology, medicine (including diagnostics and therapy), medicinal chemistry, metabolism, molecular modeling, pharmacology (clinical and animal), peptide and protein chemistry, pharmacognosy, pharmacoepidemiology, pharmacoeconomics, pharmacodynamics and pharmacokinetics, protein design, radiopharmaceuticals, and toxicology.