Collision-induced dissociation of Na-tagged ketohexoses: experimental and computational studies on fructose

• Published in: Physical chemistry chemical physics : PCCP Vol. 24; no. 35; pp. 2856 - 2866
• Main Authors: Huynh, Hai Thi, Tsai, Shang-Ting, Hsu, Po-Jen, Biswas, Anik, Phan, Huu Trong, Kuo, Jer-Lai, Ni, Chi-Kung, Chiu, Cheng-chau
• Format: Journal Article
• Language: English
• Published: Cambridge Royal Society of Chemistry 14.09.2022
• Subjects: Dehydration; Fructose; High performance liquid chromatography; Ions; Isomerization; Isomers; Mass spectra; Mass spectrometry; Mass spectroscopy; Trends
• ISSN: 1463-9076; 1463-9084
• DOI: 10.1039/d2cp02313j

Collision-induced dissociation tandem mass spectrometry (CID-MS n ) and computational investigation at the MP2/6-311+G(d,p) level of theory have been employed to study Na + -tagged fructose, an example of a ketohexose featuring four cyclic isomers: α-fructofuranose (αFru f ), β-fructofuranose (βFru f ), α-fructopyranose (αFru p ), and β-fructopyranose (βFru p ). The four isomers can be separated by high-performance liquid chromatography (HPLC) and they show different mass spectra, indicating that CID-MS n can distinguish the different fructose forms. Based on a simulation using a micro-kinetic model, we have obtained an overview of the mechanisms for the different dissociation pathways. It has been demonstrated that the preference for the C-C cleavage over the competing isomerization of linear fructose is the main reason for the previously reported differences between the CID-MS spectra of aldohexoses and ketohexoses. In addition, the kinetic modeling helped to confirm the assignment of the different measured mass spectra to the different fructose isomers. The previously reported assignment based on the peak intensities in the HPLC chromatogram had left some open questions as the preference for the dehydration channels did not always follow trends previously observed for aldohexoses. Setting up the kinetic model further enabled us to directly compare the computational and experimental results, which indicated that the model can reproduce most trends in the differences between the dissociation pathways of the four cyclic fructose isomers. Collision-induced dissociation of fructose is studied with experiments and first-principles kinetic modeling. The preference for dehydration cannot be easily predicted by the relative orientation of the OH groups as done for aldohexoses.