GEN-MKT-18-7897-A
Jan 8, 2026 | Blogs, Pharma | 0 comments
Read time: 3 minutes
During an LC-MS/MS experiment, traditional fragmentation techniques like collision-induced dissociation (CID) have long been the gold standard. Electron-activated dissociation (EAD) is emerging as a transformative tool that enhances structural elucidation, particularly for complex or labile metabolites.
What is EAD and why does it matter?
EAD is a fragmentation technique used in tandem mass spectrometry (MS/MS) that utilizes high-energy electrons to break molecular ions into fragments. EAD preserves labile bonds and generates rich, diverse fragmentation patterns that complements CID data. This makes it particularly valuable for identifying isomeric metabolites, phase II conjugates, and metabolites with fragile functional groups.
Key advantages of EAD in Met ID
The real test of any analytical technology is in the information it can provide in the real-world. Here are a two examples that that have been published in peer-reviewed publications.
Springer Nature: Streamlined high-throughput data analysis workflow for antibody-drug conjugate biotransformation characterization
Abstract
Research into antibody-drug conjugates (ADCs) is currently at an inflection point due to recent clinical impact. ADC biotransformation analysis is key for understanding the structural integrity of ADCs in vivo and is a critical aspect of drug development, especially at the lead selection stage. Data analysis of biotransformed products is hindered by the manual and time-consuming analyte identification process oftentimes taking days to weeks. We developed a streamlined data analysis workflow enabling more automated peak identification using several commercial software tools that significantly improve data processing efficiency. A linker-payload biotransformation library was created for each new molecule and combined with antibody sequence information for peak matching. As a proof of concept, we tested this workflow across different payload and linker types, acquired using different mass spectrometers: an example using a topoisomerase I inhibitor-conjugated ADC (SCIEX ZenoTOF 7600) and a comparison to a published in vivo ADC biotransformation data set for a pyrrolobenzodiazepine-conjugated ADC (ThermoFisher QE HF-X). Using this more automated workflow, we rapidly identified major biotransformation species that were previously found manually including loss of linker-payload, thiosuccinimide ring hydrolysis, cysteinylation at the deconjugation site(s), and partial linker-payload cleavage. This improved data analysis workflow has demonstrated superb effectiveness in streamlining overall ADC biotransformation identification and enabled quantification that was highly comparable to previously obtained results. Broadening application of advanced analytical techniques to study biotherapeutic biotransformation can now more effectively impact drug development by enabling faster design-test-analyze cycle times, critical in early drug discovery settings opening new avenues for more effective collaboration between analytical chemists and bioconjugate engineers.
Read more >
Rapid Communications in Mass Spectrometry: Advancing structural elucidation of conjugation drug metabolites in metabolite profiling with novel electron-activated dissociation
This study focuses on the advantage of using the novel electron-activated dissociation (EAD) technology on the QTOF system for structural elucidation of conjugation metabolites. In drug metabolite identification, conceptual “boxes” are generally used to represent potential sites of modifications, which are proposed based on MS/MS data. Electron-activated dissociation (EAD) provides unique fragmentation patterns, potentially allowing for more precise localization of the metabolic modification sites compared to CID, particularly for conjugations.
Future Outlook
At SCIEX we see pharmaceutical companies continuing to adopt high-resolution, information-rich analytical platforms, EAD is poised to become an enabling option for Met ID workflows. Its ability to provide deeper insights into metabolite structures, especially in challenging scenarios, aligns with the industry’s push toward precision medicine, faster development timelines, and regulatory robustness.
For more than 20 years, the CDCO has supported academic, commercial, and not‑for‑profit drug discovery programs with deep expertise in pharmaceutical lead optimization. Within the bioanalytical group, their role is to enable rapid and reliable decision‑making through quantitative analysis of candidate drugs in biological matrices.
PFAS are increasingly at the center of regulatory change, scientific research, and industry discussion worldwide. As analytical capabilities improve and expectations around environmental responsibility continue to evolve, understanding the role PFAS play, and how they are being addressed, has never been more important. This blog provides an overview of what PFAS are, why they matter, and how responses from regulators and industry are changing.
Pesticides are widely used in agriculture to protect crops and maintain yield, but their presence in food must be carefully monitored. To safeguard consumers, regulatory authorities worldwide set maximum residue limits (MRLs), often at very low concentrations and across a wide range of compound classes.
Posted by
You must be logged in to post a comment.
Share this post with your network