Trace Phosphate Improves ZIC-pHILIC Peak Shape, Sensitivity, and Coverage for Untargeted Metabolomics

• Published in: Journal of proteome research Vol. 17; no. 10; pp. 3537 - 3546
• Main Authors: Spalding, Jonathan L, Naser, Fuad J, Mahieu, Nathaniel G, Johnson, Stephen L, Patti, Gary J
• Format: Journal Article
• Language: English
• Published: United States American Chemical Society 05.10.2018
• Subjects: Chromatography, Liquid - methods; Hydrophobic and Hydrophilic Interactions; Mass Spectrometry - methods; Metabolome; Metabolomics - methods; Phosphates - metabolism; Reproducibility of Results; Static Electricity; coverage; untargeted metabolomics; peak detection; hydrophilic interaction liquid chromatography; credentialing; bioinformatics; phosphate; electrostatic interactions
• ISSN: 1535-3893; 1535-3907
• DOI: 10.1021/acs.jproteome.8b00487

Existing hydrophilic interaction liquid chromatography (HILIC) methods, considered individually, each exhibit poor chromatographic performance for a substantial fraction of polar metabolites. In addition to limiting metabolome coverage, such deficiencies also complicate automated data processing. Here we show that some of these analytical challenges can be addressed for the ZIC-pHILIC, a zwitterionic stationary phase commonly used in metabolomics, with the addition of trace levels of phosphate. Specifically, micromolar phosphate extended metabolome coverage by hundreds of credentialed features, improved peak shapes, and reduced peak-detection errors during informatic processing. Although the addition of high levels of phosphate (millimolar) as a HILIC mobile phase buffer has been explored previously, such concentrations interfere with mass spectrometric (MS) detection. We show that using phosphate as a trace additive at micromolar concentrations improves analysis by electrospray MS, increasing signal for a diverse set of polar standards. Given the small amount of phosphate needed, comparable chromatographic improvements were also achieved by direct addition of phosphate to the sample during reconstitution. Our results suggest that defects in ZIC-pHILIC performance are predominantly driven by electrostatic interactions, which can be modulated by phosphate. These findings constitute both a methodological improvement for untargeted metabolomics and an advance in our understanding of the mechanisms limiting HILIC coverage.