Characterization by LC-MS/MS of oxidized products identified in synthetic peptide somatostatin and cetrorelix submitted to forced oxidative stress by hydrogen peroxide: Two case studies.

In a broader scenario, the forced degradation studies provided by the ICH guidelines for Q1A, Q1B, and Q2B degradation studies allow to know the CQA of the molecule used as a drug product, to determine the appropriate analytical methods, excipients, and storage conditions ensuring the quality of the drug, its efficacy, and patient safety. In this study, we focused our attention on understanding how oxidative stress is performed by H2 O2 -impacted small synthetic peptides that do not contain residues susceptible to oxidation such as methionine. Among the amino acids susceptible to oxidation, methionine is the most reactive and depending on the structure of the protein where it is exposed, it tends to oxidize by converting into methionine sulfone or methionine sulfoxide by oxidation of its sulfur atom. Scouting experiments obtained by forced oxidative stress conditions are presented on two small synthetic peptides that do not contain any methionine residues spiked with different amounts of H2 O2 , and they are analyzed by LC-MS/MS. Less frequent oxidation products than those commonly observed on proteins/peptides-containing methionine have been characterized on both peptides. The study demonstrated that somatostatin, by means of one residue of tryptophan on the molecule, can generate traces of several oxidized products detected by UPLC-MS. Furthermore, even at a negligible level, oxidation on tyrosine and proline in cetrorelix that does not contain methionine nor tryptophan has been detected by UHPLC-MS/MS. Identification and quantification of oxidized species were achieved by high-resolution MS and MS/MS experiments. Thus, FDSs undoubtedly aid the evaluation of the CQAs as an important component of the characterization package as recommended by HAs and ICH, facilitating the understanding of unforeseen features of the studied molecule used as drugs.

Impact of four inorganic impurities - iron, copper, nickel and zinc - on the quality attributes of a Fc-fusion protein upon incubation at different temperatures.

A key aspect that must be supervised during the development of a biotherapeutic is the presence of elemental impurities in the final drug product: they must be quantified as to ensure that their concentrations does not affect patients' safety. Regulatory guidelines such as ICH Q3D provides Permitted Daily Exposure (PDE) limits for those impurities considered having a higher potential safety risk. However, one of the limits of such PDE values is that they account for the safety risk, while alterations of certain Quality Attributes (QA) of a biologic may also take place. In order to understand how certain impurities could affect not only the safety of patients, but also the physicochemical properties of biotherapeutics, here we present a study in which we examined how four commonly observed elemental impurities could impact the QAs of a Fc-fusion protein, under normal storage conditions and after six weeks of incubation at +25 °C and +40 °C. The molecule was indeed treated with increasing concentrations of Ni2+, Cu2+, Zn2+ and Fe3+ and the potential changes in conformation, oxidation, aggregation, and fragmentation were monitored. Our data suggest that keeping the levels of these impurities under the safety threshold limits does not guarantee the product quality. While nickel and zinc slightly altered the physicochemical properties of our Fc-fusion protein, iron and copper appeared to be more harmful for the QAs stability. Indeed, these latter elements might cause significant alterations of the product quality such as to potentially alter its efficacy.