Parallel electromembrane extraction in the 96-well format.

The repeatability and extraction recoveries of parallel electromembrane extraction (Pa-EME) was thoroughly investigated in the present project. Amitriptyline, fluoxetine, and haloperidol were isolated from eight samples of pure water, undiluted human plasma, and undiluted human urine, respectively; in total 24 samples were processed in parallel. The repeatability was found to be independent of the different sample matrices (pure water samples, human plasma, and water) processed in parallel, although the respective samples contained different matrix components. In another experiment seven of the 24 wells were perforated. Even though the perforation caused the total current level in the Pa-EME setup to increase, the intact circuits were unaffected by the collapse in seven of the circuits. In another approach, exhaustive extraction of amitriptyline, fluoxetine, and haloperidol was demonstrated from pure water samples. Amitriptyline and haloperidol were also isolated exhaustively from undiluted human plasma samples; the extraction recovery of fluoxetine from undiluted human plasma was 81%. Finally, the sample throughput was increased with the Pa-EME configuration. The extraction recoveries were investigated by processing 1, 8, 68, or 96 samples in parallel in 10min; neither the extraction recoveries nor the repeatability was affected by the total numbers of samples. Eventually, the Pa-EME was combined with ultra performance liquid chromatography (UPLC) to combine high-throughput sample preparation with high-throughput analytical instrumentation. The aim of the present investigation was to demonstrate the potential of electromembrane extraction as a high throughput sample preparation platform; and hopefully to increase the interest for EME in the bioanalytical field to solve exisiting and novel analytical challenges.

Development of a flat membrane based device for electromembrane extraction: a new approach for exhaustive extraction of basic drugs from human plasma.

In this work, a single-well electromembrane extraction (EME) device was developed based on a thin (100µm) and flat porous membrane of polypropylene supporting a liquid membrane. The new EME device was operated with a relatively large acceptor solution volume to promote a high recovery. Using this EME device, exhaustive extraction of the basic drugs quetiapine, citalopram, amitriptyline, methadone and sertraline was investigated from both acidified water samples and human plasma. The volume of acceptor solution, extraction time, and extraction voltage were found to be important factors for obtaining exhaustive extraction. 2-Nitrophenyl octyl ether was selected as the optimal organic solvent for the supported liquid membrane. From spiked acidified water samples (600µl), EME was carried out with 600µl of 20mM HCOOH as acceptor solution for 15min and with an extraction voltage of 250V. Under these conditions, extraction recoveries were in the range 89-112%. From human plasma samples (600µl), EME was carried out with 600µl of 20mM HCOOH as acceptor solution for 30min and with an extraction voltage of 300V. Under these conditions, extraction recoveries were in the range of 83-105%. When combined with LC-MS, the new EME device provided linearity in the range 10-1000ng/ml for all analytes (R(2)>0.990). The repeatability at low (10ng/ml), medium (100ng/ml), and high (1000ng/ml) concentration level for all five analytes were less than 10% (RSD). The limits of quantification (S/N=10) were found to be in the range 0.7-6.4ng/ml.

Parallel electromembrane extraction in a multiwell plate.

This paper describes the concept of parallel electromembrane extraction (Pa-EME) with flat membranes in a multiwell format for the first time. The setup is based on a multiwell plate and provided simultaneous and selective isolation, cleanup, and enrichment of several human plasma samples as well as LC-MS-compatible extracts within 8 min of extraction. Undiluted human plasma samples spiked with four antidepressant drugs were added to separate wells in the donor plate. Subsequently, the samples were extracted with Pa-EME. The four drugs migrated electrokinetically from undiluted human plasma through a flat polypropylene membrane impregnated with 2-nitrophenyl octyl ether, and were isolated into formic acid. Extraction time, extraction voltage, agitation rate, sample volume, and acceptor solution volume were all optimized with an experimental design. The optimal conditions were as follows: The agitation rate was 1,040 rpm, and an extraction voltage of 200 V was applied. The sample volume and acceptor solution volume was 240 and 70 µL, respectively. The extraction was continued for 8 min. Eventually, the extracts were analyzed by LC-MS/MS. The combination of Pa-EME with LC-MS/MS provided quantitation limits below the therapeutic level and reported relative standard deviations in the range 5-13 %. Linear calibration curves were obtained for all analytes, and the correlation coefficients were above 0.9974 in the range 1-400 ng mL(-1). The drug concentrations from two subjects treated with quetiapine and sertraline were successfully determined with Pa-EME combined with LC-MS/MS. Post-column infusion experiments demonstrated that Pa-EME provided extracts free from interfering matrix components.

Alginate and chitosan foam combined with electromembrane extraction for dried blood spot analysis.

Samples of 10 µL of whole blood containing citalopram, loperamide, methadone, and sertraline as model substances were spotted on alginate and chitosan foams as sampling media. After drying and storage at room temperature, the punched out dried blood spot and the foam was dissolved in 300 µL of 1 mM HCl. With alginate foam as sampling medium, the analytes dissolved completely after 3 min. Enrichment and cleanup was performed with electromembrane extraction for 10 min. The analytes were collected in 21 µL of 10 mM formic acid as the acceptor phase, and the extracts were analyzed by liquid chromatography-mass spectrometry (LC-MS). Sample preparation of blood spots on commercial cards was also performed (Whatman FTA DMPK and Agilent Bond Elut DMS) using elution procedures recommended by the manufacturers. The recoveries obtained with the commercial cards were lower for most of the model analytes compared to the recoveries obtained with alginate and chitosan foams as sampling media. The procedure used for Agilent Bond Elut DMS showed higher recoveries than the procedure used for Whatman FTA DMPK-A, but the time needed for sample preparation was significantly longer (nearly 2 h). The stability of the model substances on the alginate foam was acceptable within 50 days of storage. The limit of quantification (LOQ) defined as S/N = 10, was 1.2, 5.5, 2.0, and 5.3 ng/mL for citalopram, loperamide, methadone, and sertraline, respectively. Linear calibration graphs were obtained in the range 17.5-560 ng/mL with r(2) values 0.983-0.995, and the relative standard deviations were below 20%.

Electromembrane extraction of stimulating drugs from undiluted whole blood.

For the first time, electromembrane extraction (EME) of six basic drugs of abuse from undiluted whole blood and post mortem blood in a totally stagnant system is reported. Cathinone, methamphetamine, 3,4-methylenedioxy-amphetamine (MDA), 3,4-methylenedioxy-methamphet-amine (MDMA), ketamine and 2,5-dimethoxy-4-iodoamphetamine (DOI) were extracted from the whole blood sample, through a supported liquid membrane (SLM) consisting of 1-ethyl-2-nitrobenzene (ENB) immobilized in the pores of a hollow fiber, and into an aqueous acceptor solution inside the lumen of the hollow fiber. The SLM acts as a barrier with efficient exclusion of all macromolecules and acidic substances in the sample. Due to the application of the electrical field, only the cationic compounds of interest are extracted efficiently across the membrane, thus providing extremely clean extracts for analysis with liquid chromatography-mass spectrometry, LC-MS. Recoveries in the range 10-30% were obtained from 80 µl whole blood within 5 min extraction time and an applied voltage of 15V across the SLM. The optimized technique was tested on real forensic whole blood samples taken from three forensic autopsy cases and on five forensic whole blood samples from living persons. The results were in agreement with the analysis using standard sample preparation methods (liquid-liquid extraction) performed on the same samples by Norwegian Institute of Public Health (NIPH), Division of Forensic Toxicology and Drug Abuse Research. Evaluation data were acceptable, with limit of detections (LODs) in the range 40-2610 pg/mL, well below concentrations associated with drug abuse; linearites in the range between 10 and 250 ng/mL with r(2) values above 0.9939, and with repeatability (RSD) of 7-32%.

Exhaustive electromembrane extraction of some basic drugs from human plasma followed by liquid chromatography-mass spectrometry.

Citalopram, loperamide, methadone, paroxetine, pethidine, and sertraline were extracted exhaustively with electromembrane extraction (EME) by increasing the number of hollow fibers from one to three. Experiments reported recoveries in the range 97-115% from 1000µl spiked water samples. EME was accomplished with 200V as extraction voltage, the extraction time was set to 10min (equilibrium), and the extraction unit was subjected to 1200 revolutions per minute (rpm). The same experiment with different geometry in a stagnant system conducted with 21µl acceptor solution provided recoveries from 50µl undiluted human plasma (pH 7.4) in the range of 56-102% for the six basic model substances. In each experiment the acceptor solution was distributed into three separately hollow fibers in the same sample vial. The importance of an electrical field was verified by comparing EME with liquid-phase microextraction (LPME) under optimal conditions and demonstrated that the time needed to reach equilibrium was reduced by EME. EME-LC/MS provided linearity >0.99 (r(2) values) for the six basic model substances, and the repeatability within the low therapeutic range (10ng/ml) was in the range 5.1-21.4% RSD. LC-MS provided estimated limit of quantification (S/N=10) in the range 0.6-3.2ng/ml. Eventually, patient samples from a reference laboratory were analyzed and provided reliable results with a relative difference <14% compared to stated values from the reference laboratory.

Kinetic electro membrane extraction under stagnant conditions--fast isolation of drugs from untreated human plasma.

Amitriptyline, citalopram, fluoxetine, and fluvoxamine were isolated by electro membrane extraction (EME) from 70microl of untreated plasma (pH 7.4), through a supported liquid membrane (SLM) of 1-ethyl-2-nitrobenzene immobilized in the pores of a porous polypropylene hollow fiber, and into 30microl of 10mM HCOOH as acceptor solution inside the lumen of the hollow fiber. The driving force of the extraction was a 9V potential sustained over the SLM with a common battery, with the positive electrode placed in the plasma sample and the negative electrode placed in the acceptor solution. Extractions were performed under totally stagnant conditions with a very simple device for 1min (kinetic regime), and subsequently the acceptor solution was analyzed directly by liquid chromatography-mass spectrometry (LC-MS). Recoveries were 12, 13, 22, and 17% for fluoxetine, amitriptyline, citalopram, and fluvoxamine, respectively. Sample clean-up was comparable to reversed-phase solid-phase extraction (SPE), but EME required substantially less time than SPE. The time advantage of EME was further improved by parallel extraction of three samples (for 1min) with the same 9V battery. EME from plasma combined with LC-MS provided limits of quantification (S/N=10) in the range 0.4-2.3ng/ml, linearity in the range 1-1000ng/ml with r(2)-values of 0.998-0.999, and repeatability in the range 3.2-8.9% RSD in the mid-therapeutic window (100ng/ml).