Abstract
The performance of an original CE-MS interface that allows the in-axis positioning of the electrospray with respect to the MS inlet was evaluated. The variations in the geometrical alignment of this configuration in the absence of a nebulizing gas afforded a significant reduction in the sheath-liquid flow rate from 3 µL/min to as low as 300 nL/min. The sheath liquid and BGE were respectively composed of H2O—iPrOHCH3COOH 50:50:1 (v/v/v) and 10% acetic acid (pH 2.2). A significant gain in sensitivity was obtained, and it was correlated to the effective mobility of the analytes. Compounds with low mobility values showed a greater sensitivity gain. Special attention was paid to the detection of proteinogenic amino acids. Linear response functions were obtained from 15 ng/mL to 500 ng/mL. The limits of quantification, as low as 34.3 ng/mL, were improved by a factor of up to six compared to the conventional configuration. The in-axis setup was ultimately applied to the absolute quantification of four important amino acids, alanine, tyrosine, methionine and valine, in standard reference material (NIST plasma). The accuracies ranged from 78 to 113%, thus demonstrating the potential of this configuration for metabolomics.
Highlights
CE has the great advantages of high resolution, high selectivity and short analysis time with low samples and solvent consumption
CE-electrospray ionization mass spectrometry (ESI-MS) interfaces can be classified as (i) nano-ESI interfaces operating at low flow rate or without additional liquid (1–1000 nL/min) with no nebulizing gas required or (ii) ESI interfaces with an additional sheath liquid support operating at 1–1000 μL/min and mostly assisted with a nebulizing gas
The commercial CE-ESI-MS interface employs a sheath liquid in addition to a background electrolyte (BGE) to provide electrical contact and uses heated nitrogen as a nebulizing gas to help desolvation
Summary
CE has the great advantages of high resolution, high selectivity and short analysis time with low samples and solvent consumption. When combined with electrospray ionization mass spectrometry (ESI-MS), it is one of the most relevant tools for the characterization of ionizable polar compounds [1,2]. The two techniques can be coupled via several modes based on the flow rate and the presence of an assisting nebulizing gas [3]. CE-ESI-MS interfaces can be classified as (i) nano-ESI interfaces operating at low flow rate or without additional liquid (1–1000 nL/min) with no nebulizing gas required or (ii) ESI interfaces with an additional sheath liquid support operating at 1–1000 μL/min and mostly assisted with a nebulizing gas. The sheath liquid provides electrical contact to close the CE circuit, enabling more robustness and flexibility through its composition including the potential for postcapillary derivatization. It has been reported that the significant additional vol-
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