S. Heron scite author profile

We describe the fabrication of a surface acoustic wave (SAW) device on a LiNbO 3 piezoelectric transducer for the transfer of non-volatile analytes to the gas-phase at atmospheric pressure (a process referred to as nebulization or atomization). We subsequently show how such a device can be used in the field of mass spectrometry (MS) detection, demonstrating that SAW nebulization (SAWN) can be performed either in a discontinuous or pulsed mode, similar to that for matrix assisted laser desorption ionization (MALDI) or in a continuous mode like electrospray ionization (ESI). We present data showing the transfer of peptides to the gas-phase, where ions are detected by MS. These peptide ions were subsequently fragmented by collision-induced dissociation, from which the sequence was assigned. Unlike MALDI mass spectra, which are typically contaminated with matrix ions at low m/z, the SAWN generated spectra had no such interference. In continuous mode, the SAWN plume was sampled on a microsecond time scale by a linear ion trap mass spectrometer, and produced multiply charged peptide precursor ions with a charge state distribution shifted to higher m/z compared to an identical sample analyzed by ESI. The SAWN technology also provides the opportunity to re-examine a sample from a flat surface, repeatedly. The process can be performed without the need for capillaries, which can clog, reservoirs, which dilute sample, and electrodes which, when in direct contact with sample, cause unwanted electrochemical oxidation. In both continuous and pulsed sampling modes, the quality of precursor ion scans and tandem mass spectra of peptides was consistent across the plume's lifetime.

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Detection and simultaneous identification of microorganisms from headspace samples using an electronic nose.

Gibson

Prosser

Hulbert

et al. 1997

Sensors and Actuators B: Chemical

148

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Surface Acoustic Wave Nebulization Produces Ions with Lower Internal Energy than Electrospray Ionization

Huang

Yoon

Heron

et al. 2012

J. Am. Soc. Mass Spectrom.

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Surface acoustic wave nebulization (SAWN) has recently been reported as a novel method to transfer non-volatile analytes directly from solution to the gas phase for mass spectrometric analysis. Here we present a comparison of the survival yield of SAWN versus electrospray ionization (ESI) produced ions. A series of substituted benzylpyridinium (BzPy) compounds were utilized to measure ion survival yield from which ion energetics were inferred. We also estimated bond dissociation energies using higher level quantum chemical calculations than previously reported for BzPy ions. Additionally, the effects on BzPy precursor ion survival of SAWN operational parameters such as inlet capillary temperature and solution flow-rate were investigated. Under all conditions tested, SAWN-generated BzPy ions displayed a higher tendency for survival and thus have lower internal energies than those formed by ESI.

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Surface Acoustic Wave Nebulization Facilitating Lipid Mass Spectrometric Analysis

et al. 2012

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Surface acoustic wave nebulization (SAWN) is a novel method to transfer non-volatile analytes directly from the aqueous-phase to the gas-phase for mass spectrometric analysis. The lower ion energetics of SAWN and its planar nature make it appealing for analytically challenging lipid samples. This challenge is a result of their amphipathic nature, labile nature, and tendency to form aggregates, which readily precipitate clogging capillaries used for electrospray ionization (ESI). Here we report the use of SAWN to characterize the complex glycolipid, lipid A, which serves as the membrane anchor component of lipopolysaccharide (LPS) and has a pronounced tendency to clog nano-ESI capillaries. We also show that unlike ESI SAWN is capable of ionizing labile phospholipids without fragmentation. Lastly, we compare the ease of use of SAWN to the more conventional infusion-based ESI methods and demonstrate the ability to generate higher order tandem mass spectral data of lipid A for automated structure assignment using our previously reported hierarchical tandem mass spectrometry (HiTMS) algorithm. The ease of generating SAWN-MSn data combined with HiTMS interpretation offers the potential for high throughput lipid A structure analysis.

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S. Heron

Surface Acoustic Wave Nebulization of Peptides As a Microfluidic Interface for Mass Spectrometry

Detection and simultaneous identification of microorganisms from headspace samples using an electronic nose.

Surface Acoustic Wave Nebulization Produces Ions with Lower Internal Energy than Electrospray Ionization

Surface Acoustic Wave Nebulization Facilitating Lipid Mass Spectrometric Analysis

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