The effect of vacuum: an emerging experimental parameter to consider during headspace microextraction sampling
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The effect of vacuum: an emerging experimental parameter to consider during headspace microextraction sampling Elefteria Psillakis 1 Received: 9 April 2020 / Revised: 16 May 2020 / Accepted: 25 May 2020 # Springer-Verlag GmbH Germany, part of Springer Nature 2020
Abstract The effect of vacuum is an emerging experimental parameter to consider during optimization of a variety of headspace microextraction methodologies. The positive effect of vacuum was initially demonstrated for headspace solid-phase microextraction and was recently expanded to single-drop microextraction and higher capacity sorbents i.e. stir bar sorptive extraction. In all cases, sampling under vacuum greatly accelerated the extraction kinetics of analytes exhibiting long equilibration times under atmospheric pressure. At the same time, the extraction of analytes that reached equilibrium fast was not affected. In all optimized methods, extraction times were greatly reduced and/or sampling temperatures were lower to those reported with the standard methodology under atmospheric pressure. This work succinctly overviews the effect of vacuum on the different headspace microextraction technologies reported so far. The fundamental concepts describing the pressure dependence of each methodology are pulled together and presented in a simplified manner. The latest findings on the combined effects of vacuum and several selected experimental parameters typically examined during method optimization are then presented and the practical aspects of past outcomes are highlighted. The discussion also includes the air-evacuation step and the analysis of complex matrices. This article is intended for readers who are either new to the field of vacuum headspace microextraction sampling or its use and want to exploit this powerful approach. Keywords Vacuum sampling . Reduced pressure . Headspace solid-phase microextraction . Headspace single-drop microextraction . Headspace sorptive extraction . Headspace sampling
Introduction Microextraction techniques are equilibrium non-exhaustive methods, developed to address the need for a reduction in solvent use to facilitate rapid and convenient sample preparation [1]. Depending on the type of extracting phase used, microextraction methods are commonly categorized as solidand liquid-phase techniques. In solid-phase techniques, the extracting phase can be referred to as sorbent and includes certain solid-supported liquid phases like polydimethylsiloxane (PDMS) [2]. The most common and commercially Published in the topical collection featuring Female Role Models in Analytical Chemistry. * Elefteria Psillakis [email protected] 1
Laboratory of Aquatic Chemistry, School of Environmental Engineering, Technical University of Crete, Polytechneioupolis, 73100 Chania, Greece
available solid-based microextraction technique is solidphase microextraction (SPME) that uses a thin fused silica fiber which is coated with a polymeric film to extract target analytes [1, 3]. Stir bar sorptive extraction (SBSE) is another method of choi
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