Fully automated electromembrane extraction

The implementation of microextraction techniques in process laboratories usually depends on their automation degree. In reality, the use of too manual procedures is not practical when a large number of samples must be processed. In addition, manual workflows are labor intensive and prone to errors. This situation can be further complicated when risky samples, pretty common in bioanalysis, are handled.

The potential of electromembrane extraction (EME) has been highlighted several times in Microextraction Tech blog. Among other advantages, EME is a rapid process thanks to the migration of the target compounds from the sample to the acceptor phase (through an appropriate supported liquid membrane) under an electrical voltage gradient. No doubt, the automation of EME and its hyphenation to chromatographic techniques would have a high impact in the field.

Researchers from the universities of Copenhagen and Oslo have reported this year two interesting articles in this context. Earlier in this year, they described the direct combination of EME and liquid chromatography-mass spectrometry (LC-MS) in a highly recommendable article published in Analytica Chimica Acta (1). Despite the interest of this approach, this post is focused on a recent article accepted for publication in Analytical Chemistry. In this case, our colleagues go beyond to the "simple" automation and coupling. In fact, they propose the integration of EME in a LC-MS autosampler.

The modification of the autosampler syringe makes this integration possible while enabling the subsequent extraction of several samples (each one located in a different vial of the autosampler tray). Although we recommend reading the original article to fully understand the proposal, a brief description is outlined before.

The core of the system, which is schematically shown in the Figure, consists of a hollow fiber (HF) whose ends are attached to fused capillary tubes. The acceptor phase flows through that inner volume and it is finally placed in the loop of a switching valve that allows its injection in the LC. The hollow fiber is located in the luer adapter of the syringe in such a way that the sample comes in close contact with the HF when it is aspirated from the vial by the syringe. An electrical wire and a voltage sequencer are the last elements needed to integrate EME with LC. Several steps (e.g aspiration of the sample, extraction and injection) are developed in a sequential and automated way. We strongly recommend the movie published as supplementary information and freely available on the journal webpage since it clearly explains all the process.

Scheme of the proposed device (more info in the original manuscript)

This is just a brief excerpt of the article and you will find additional info in the original article. Among this info, you will read a comprehensive description of the device, the optimization of the experimental variables involved in the extraction and the practical application to study the in-vivo conversion of methadone by rat liver microsomes.

References

(1) Direct coupling of a flow–flow electromembrane extraction probe to LC-MS. Link to the article

(2) Fully Automated Electro Membrane Extraction Autosampler for LC–MS Systems Allowing Soft Extractions for High-Throughput Applications. Link to the article

Related posts

(A) Electromembrane extraction of biological samples: determining stimulant drugs in whole blood. Link to the post

(B) Simultaneous electromembrane extraction of acidic and basic drugs. Link to the post

(C) Dynamic electromembrane extraction. Link to the post