Liquid-Phase Microextraction or Electromembrane Extraction?

Wan, Libin; Lin, Bingcheng; Zhu, Ruiqin; Huang, Chuixiu; Pedersen‐Bjergaard, Stig; Shen, Xiantao

doi:10.1021/acs.analchem.9b00946

Cited by 41 publications

(24 citation statements)

References 55 publications

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“…Moreover, dynamic LPME resulted in amelioration of the enrichment factors and shortening of the extraction times. Electric-field-driven LPME has also been recently seen as a viable option for expedient SLM extraction of ionizable or polar species, − also in micro/mesofluidic platforms. − Additional advantages of using an electric field are (i) improved selectivity for transfer of ionized species, (ii) efficient matrix cleanup, and (iii) modulation of the sample preparation process for potentially exhaustive extraction of target species. , …”

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confidence: 99%

Fully Automated Electric-Field-Driven Liquid Phase Microextraction System with Renewable Organic Membrane As a Front End to High Performance Liquid Chromatography

et al. 2019

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This article reports for the first time a programmable-flow-based mesofluidic platform that accommodates electric-field-driven liquid phase microextraction (μ-EME) in a fully automated mode. The miniaturized system is composed of a computer-controlled microsyringe pump and a multiposition rotary valve for handling aqueous and organic solutions at a low microliter volume and acts as a front-end to online liquid chromatographic separation. The organic membrane is automatically renewed and disposed of in every analytical cycle, thus minimizing analyte carry-over effects while avoiding analyst intervention. The proof-of-concept applicability of the automated mesofluidic device is demonstrated by the liquid chromatographic determination of nonsteriodal antiinflammatory drugs in μ-EME processed complex samples (such as urine and influent wastewater) using online heart-cut approaches. Using 5 μL of 1-octanol, 7.5 μL of untreated sample and 7.5 μL of acceptor solution (25 mM NaOH), and 250 V for only 10 min in a stopped-flow mode, the extraction recoveries for the μ-EME of ibuprofen, ketoprofen, naproxen, and diclofenac exceed 40% in real samples. The flow-through system features moderately selective extraction regardless of the sample matrix constituents with repeatability values better than 13%.

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confidence: 99%

Fully Automated Electric-Field-Driven Liquid Phase Microextraction System with Renewable Organic Membrane As a Front End to High Performance Liquid Chromatography

et al. 2019

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“…However, two important restrictions of current EFASP designs are the requirement for at least two immiscible phases and contact between at least one aqueous phase and the electrode . For example, electromembrane extraction (EME), the most studied EFASP technique in recent years, , features a liquid–liquid–liquid system that typically comprises aqueous donor and acceptor phases separated by a membrane (organic filter). − In supported liquid membranes (SLMs), the organic solvent is immobilized in the pores of a polymeric membrane, whereas free liquid membranes (FLMs) contain the organic solvent between two aqueous phases in a narrow channel . A further example is electroextraction (EE), in which two immiscible phases (i.e., aqueous and organic phases) are employed without membranes .…”

Section: Introductionmentioning

confidence: 99%

“…Regarding the second restriction, the use of an aqueous phase can adversely impact the accuracy, speed, and applicability of the method. For example, electrolysis , of the aqueous phase is a common and undesired process that leads to bubble formation and production of OH – and H + ions at the cathodic and anodic electrodes, respectively, consequently altering the pH of the donor and acceptor phases. ,, As the pH value governs analyte ionization, , even minor changes in the pH of the acceptor phase may lead to back-extraction through passive diffusion . Although the enrichment factor can be increased by using a small volume of the acceptor phase (e.g., microliter level), the ER is extremely susceptible to electrolytic byproducts. , Furthermore, the higher conductivity of salt-, acid-, or base-containing aqueous phases and the lower partial voltage in the circuit cause slow analyte transmission .…”

Section: Introductionmentioning

confidence: 99%

“…For example, electrolysis 8,10 of the aqueous phase is a common and undesired process that leads to bubble formation and production of OH − and H + ions at the cathodic and anodic electrodes, respectively, consequently altering the pH of the donor and acceptor phases. 8,24,25 As the pH value governs analyte ionization, 14,26 even minor changes in the pH of the acceptor phase may lead to back-extraction through passive diffusion. 10 Although the enrichment factor can be increased by using a small volume of the acceptor phase (e.g., microliter level), the ER is extremely susceptible to electrolytic byproducts.…”

Section: ■ Introductionmentioning

confidence: 99%

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Nonaqueous Miscible Liquid–Liquid Electroextraction for Fast Exhaustive Enrichment of Ultratrace Analytes by an Exponential Transfer and Deceleration Mechanism

Yuan

Cao

et al. 2020

Anal. Chem.

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Conventional electrical-field-assisted sample preparation (EFASP) methods rely on analyte transfer between immiscible phases and require at least one aqueous phase in contact with the electrode. In this paper, we report a novel nonaqueous miscible liquid–liquid electroextraction (NMLEE) technique that enables fast exhaustive enrichment of ultratrace analytes from a milliliter-level donor in a vial to a microliter-level acceptor in a tube. Miscible nonaqueous solvents are used for the donor and acceptor to overcome common EFASP problems such as high charge or mass transfer resistance, loss of analytes in the membrane phase, water electrolysis, back-extraction, bubble generation, and difficulties in the application of high voltage for fast migration. According to theoretical derivation and experimental verification results, the concentrations of analytes in the donor and their migration velocity in the acceptor both decrease exponentially with time, and the extraction recovery correlates linearly with the current variation. These mechanisms result in efficient enrichment by forming an analyte-enriched zone and allow the extraction progress and recovery to be monitored and estimated based on the current variation. NMLEE was coupled with liquid chromatography–mass spectrometry to analyze 10 amphetamine-type drugs, atropine, nortriptyline, and methadone in blood and urine samples. This method provided low limits of detection (0.003–0.1 ng·mL–1), satisfactory extraction recoveries (89.6–104.1%), and RSDs (<12.3% for intraday and <8.8% for interday), which met the requirements of the ICH guidelines. This study may contribute to the further development of EFASP methods for effective ultratrace analyses in forensic science.

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“…24,25 In a typical LPME process, the analyte is first extracted from a sample into a supported liquid membrane (SLM) and further into an acceptor solution. 26 In this process, the low-level target in biological samples can be preconcentrated in the simple acceptor solution, making it a promising technique for future integration with FABs. So far, several miniaturized membranebased LPME setups including in-vial LPME, 27 solvent bar LPME, 28 hollow-fiber LPME, 29 and flat membrane-based LPME (FM-LPME) 30 have been developed.…”

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confidence: 99%

Versatile Integration of Liquid-Phase Microextraction and Fluorescent Aptamer Beacons: A Synergistic Effect for Bioanalysis

et al. 2021

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Fluorescent aptamer beacons (FABs) are a major category of biosensors widely used in environmental analysis. However, due to their low compatibility, it is difficult to use the common FABs for biological samples. To overcome this challenge, construction of FABs with complex structures to adapt the nature of biological samples is currently in progress in this field. Unlike previous works, we moved our range of vision from the FAB itself to the biological sample. Inspired by this idea, in this work, flat membrane-based liquid-phase microextraction (FM-LPME) with sufficient sample cleanup and preconcentration capacities was integrated with FABs. With the merits of both FM-LPME and FABs, the integrated LPME-FAB system displayed a clear synergistic enhancement for target analysis. Specifically, LPME in the LPME-FAB system provided purified and enriched Hg 2+ for the FAB recognition, while the FAB recognition event promoted the extraction efficiency of LPME. Due to superior performances, the LPME-FAB system achieved highly sensitive analysis of Hg 2+ in urine samples with a detection limit of 27 nM and accuracies in the range of 98−113%. To the best of our knowledge, this is the first time that an integrated LPME-FAB system was constructed for target analysis in biological samples. We believe that this study will provide a new insight into the next generation of biosensors, where the integration of sample preparation with detection probes is as important as the design of complex probes in the field of bioanalysis.

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Liquid-Phase Microextraction or Electromembrane Extraction?

Cited by 41 publications

References 55 publications

Fully Automated Electric-Field-Driven Liquid Phase Microextraction System with Renewable Organic Membrane As a Front End to High Performance Liquid Chromatography

Fully Automated Electric-Field-Driven Liquid Phase Microextraction System with Renewable Organic Membrane As a Front End to High Performance Liquid Chromatography

Nonaqueous Miscible Liquid–Liquid Electroextraction for Fast Exhaustive Enrichment of Ultratrace Analytes by an Exponential Transfer and Deceleration Mechanism

Versatile Integration of Liquid-Phase Microextraction and Fluorescent Aptamer Beacons: A Synergistic Effect for Bioanalysis

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