Moderate Signal Enhancement in Electrospray Ionization Mass Spectrometry by Focusing Electrospray Plume with a Dielectric Layer Around the Mass Spectrometer's Orifice

Overview

Journal Molecules

Publisher MDPI

Specialty Biology

Date 2024 Jan 23

PMID 38257229

Authors

Zi Qing Chua

Gurpur Rakesh D Prabhu

Yi-Wun Wang

Chamarthi Maheswar Raju

Krzysztof Buchowiecki

Ochir Ochirov

Decibel P Elpa

Pawel L Urban

Affiliations

Soon will be listed here.

Abstract

Electrospray ionization (ESI) is among the commonly used atmospheric pressure ionization techniques in mass spectrometry (MS). One of the drawbacks of ESI is the formation of divergent plumes composed of polydisperse microdroplets, which lead to low transmission efficiency. Here, we propose a new method to potentially improve the transmission efficiency of ESI, which does not require additional electrical components and complex interface modification. A dielectric plate-made of ceramic-was used in place of a regular metallic sampling cone. Due to the charge accumulation on the dielectric surface, the dielectric layer around the MS orifice distorts the electric field, focusing the charged electrospray cloud towards the MS inlet. The concept was first verified using charge measurement on the dielectric material surface and computational simulation; then, online experiments were carried out to demonstrate the potential of this method in MS applications. In the online experiment, signal enhancements were observed for dielectric plates with different geometries, distances of the electrospray needle axis from the MS inlet, and various compounds. For example, in the case of acetaminophen (15 μM), the signal enhancement was up to 1.82 times (plate B) using the default distance of the electrospray needle axis from the MS inlet ( = 1.5 mm) and 12.18 times (plate C) using a longer distance ( = 7 mm).

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