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« Previous AbstractSize resolved metal distribution in the PM matter of the city of Turin (Italy)    Next AbstractStudies pertaining to the monitoring of volatile halogenated anaesthetics in breath by proton transfer reaction mass spectrometry »

J Breath Res


Title:Proton transfer reaction time-of-flight mass spectrometric measurements of volatile compounds contained in peppermint oil capsules of relevance to real-time pharmacokinetic breath studies
Author(s):Malaskova M; Henderson B; Chellayah PD; Ruzsanyi V; Mochalski P; Cristescu SM; Mayhew CA;
Address:"Institute for Breath Research, Leopold-Franzens-Universitat Innsbruck, Rathausplatz 4, A-6850, Dornbirn, Austria"
Journal Title:J Breath Res
Year:2019
Volume:20190718
Issue:4
Page Number:46009 -
DOI: 10.1088/1752-7163/ab26e2
ISSN/ISBN:1752-7163 (Electronic) 1752-7155 (Linking)
Abstract:"With the growing interest in the use of breath volatiles in the health sciences, the lack of standardization for the sampling and analysis of exhaled breath is becoming a major issue leading to an absence of conformity, reproducibility and reliability in spectrometric measurements. Through the creation of a worldwide 'peppermint consortium', the International Association of Breath Research has set up a task force to deal with this problem. Pharmacokinetic studies are proposed, and a real-time analytical technique that is being used is proton transfer reaction-time-of-flight-mass spectrometry (PTR-ToF-MS). This paper presents details on how the volatile compounds contained in a peppermint oil capsule, and hence on breath, appear in a PTR-ToF-MS. To aid that study, the key volatiles in the headspace of peppermint oil were first identified using gas chromatography-mass spectrometry, notably: menthol, menthone, 1,8-cineole, menthofuran, limonene, alpha-pinene and beta-pinene. A PTR-ToF-MS analysis of these compounds has been undertaken, divorced from the complexity of the peppermint oil matrix using 'normal' and 'saturated' humidity drift-tube conditions, with the latter used to mimic breath samples, and over a range of reduced electric fields. There are no characteristic product ions that can distinguish monoterpenes and 1,8-cineole, and hence, without pre-separation, a combined washout for these volatiles can only be provided. By operating the drift tube above about 130 Td, there are characteristic product ions for menthone, menthofuran and menthol, namely m/z 155.14 (protonated menthone), m/z 151.11 (protonated menthofuran), m/z 139.15 (loss of H(2)O from protonated menthol) and m/z 83.09 (a fragment ion, C(6)H(11) (+), from menthol). These have been used to monitor, with a high specificity, the temporal profile of these three compounds in breath following the ingestion of a peppermint oil capsule. To aid in the analyses, the proton affinities and gas-phase basicities for the key volatiles investigated have been determined using density functional theory"
Keywords:Breath Tests/*methods Capsules Density Functional Theory Electricity Exhalation Gas Chromatography-Mass Spectrometry/*methods Humans Ions Mentha piperita Plant Oils/*chemistry *Protons Reference Standards Reproducibility of Results Time Factors Volatile O;
Notes:"MedlineMalaskova, Michaela Henderson, Ben Chellayah, Prema D Ruzsanyi, Veronika Mochalski, Pawel Cristescu, Simona M Mayhew, Chris A eng Research Support, Non-U.S. Gov't England 2019/06/05 J Breath Res. 2019 Jul 18; 13(4):046009. doi: 10.1088/1752-7163/ab26e2"

 
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