RESUMEN
RATIONALE: Recently N-Fluoroarenesulfonamides (ArSO2 NHF) were found to be promising precursors for the preparation of N-fluorobenzenesulfonimide derivatives without applying F2 . However, very few studies have discussed the mass spectrometric behaviors of ArSO2 NHF with N-F structure. METHODS: In this article, we applied high-resolution electrospray ionization tandem mass spectrometry (HR-ESI-MS/MS) to study the effect on the mass spectrometric behaviors of ArSO2 NHF after the introduction of the F-atom to the N-atom of ArSO2 NH2 . RESULTS: High-resolution electrospray ionization mass spectrometry (HR-ESI-MS) experiments showed that ArSO2 NHF produced only good signals in negative ion mode, and the dominating product ion SO2 F- at m/z 83 was observed in all HR-ESI-MS/MS of ArSO2 NF- with different substituents in the Ar group. The formation of the product ion SO2 F- was proof of the gas-phase F-atom migration rearrangement from the N-atom to the S-atom in ESI-MS/MS of ArSO2 NF- . CONCLUSION: To fully explain the gas-phase reaction mechanism from ArSO2 NF- to SO2 F- , we studied the HR-ESI-MS/MS of deprotonated ArSO2 NHF and also performed theoretical calculations. Both results confirmed that ArSO2 NF- first underwent Smiles rearrangement to yield intermediate I (INT1) ArNFSO2 - , and then the F-atom of ArNFSO2 - migrated from the N-atom to the S-atom to form intermediate II (INT2) ArN- SO2 F, which finally dissociated to SO2 F- at m/z 83 with loss of a neutral nitrene (ArN). All these results showed that the formation of the product ion SO2 F- from ArSO2 NF- was a common and intrinsic gas-phase reactivity of ArSO2 NF- .
RESUMEN
RATIONALE: Deuterium-labeled organic compounds, reagents, and drugs are widely used in many scientific research fields. Isotopic purity as the feature parameter of deuterated compounds is of great importance. In this article, we used electrospray ionization with high-resolution mass spectrometry (ESI-HRMS) to study isotopic purity of deuterium-labeled organic compounds based on assigning and distinguishing the corresponding H/D (hydrogen-deuterium) isotopolog ions of deuterated compounds. METHODS: We systematically considered the specific requirements of accuracy and resolution of ESI-HRMS when measuring isotopic purity and demonstrated some actual cases using ESI-HRMS and ultraperformance liquid chromatography (UPLC)-HRMS. Meanwhile, ESI-HRMS/MS of deuterated compounds was performed to obtain more information on deuterium-labeled position characterization. RESULTS: Two isotopic purity calculation methods based on the relative abundance in ESI-HRMS and UPLC-HRMS of H/D isotopolog ions (D0 -Dn ) were compared, which gave consistent isotopic purity values and were in good agreement with the certified isotopic purity values. We further studied and monitored the H/D exchange reaction of ethyl 3-(4-bromophenyl)-3-oxopropanoate (EBPO) by evaluating the dynamic isotopic purity changes in EBPO-D2 in the H/D exchange reaction in situ. CONCLUSION: The isotopic purity characterization methods using ESI-HRMS discussed in this article have some outstanding advantages: rapid, highly sensitive, very low sample consumption (even below nanogram level), and deuterated solvent-free. Thus, this low-impact analytical method requires less time and is cost effective and might have good application potential for in-situ isotopic purity analysis and for monitoring the H/D exchange reactions.