Performance Characteristics of Mass Spectrometry-Based Analytical Procedures for Quantitation of Nitrosamines in Pharmaceuticals: Insights from an Inter-laboratory Study.

With the discovery of carcinogenic nitrosamine impurities in pharmaceuticals in 2018 and subsequent regulatory requirements for risk assessment for nitrosamine formation during pharmaceutical manufacturing processes, storage or from contaminated supply chains, effective testing of nitrosamines has become essential to ensure the quality of drug substances and products. Mass spectrometry has been widely applied to detect and quantify trace amounts of nitrosamines in pharmaceuticals. As part of an effort by regulatory authorities to assess the measurement variation in the determination of nitrosamines, an inter-laboratory study was performed by the laboratories from six regulatory agencies with each of the participants using their own analytical procedures to determine the amounts of nitrosamines in a set of identical samples. The results demonstrated that accurate and precise quantitation of trace level nitrosamines can be achieved across multiple analytical procedures and provided insight into the performance characteristics of mass spectrometry-based analytical procedures in terms of accuracy, repeatability and reproducibility.

Identification and quantification of ethylene oxide in sterilized medical devices using multiple headspace GC/MS measurement.

This manuscript, based on the ISO 10993-7 approach, describes a multiple HS-GC measurement of residual EO present in sterilized plastic samples. The quantification of EO is done, according to the ISO standard, by addition of EO amounts extracted for each repeated extraction. During the method development, the specificity of the detection of EO regarding acetaldehyde (structural isomer of EO) which may be formed from EO has been ensured and different tests were performed to check a possible influence of the sample preparation. Assays to maximize EO extraction were performed for different materials (Cyclo-olefine Copolymer (COC), Cyclo-olefine Polymer (COP), Silicon, Polyurethane (PUR)) changing extraction temperatures and times for the headspace and the pre-thermal treatment. Results highlight that depending on the material, EO can be more or less retained and thus thermal extraction conditions to maximize the amount of extractible EO from plastics may change accordingly. For COC syringes a validation according to ICH guidelines and an inter-laboratories study were performed. The method has been used for a market survey of EO sterilized medical devices, results obtained are reported in this manuscript.