High-throughput sequential injection method for simultaneous determination of plutonium and neptunium in environmental solids using macroporous anion-exchange chromatography, followed by inductively coupled plasma mass spectrometric detection

This paper reports an automated analytical method for rapid and simultaneous determination of plutonium and neptunium in soil, sediment, and seaweed, with detection via inductively coupled plasma mass spectrometry (ICP-MS). A chromatographic column packed with a macroporous anion exchanger (AG MP-1 M) was incorporated in a sequential injection (SI) system for the efficient retrieval of plutonium, along with neptunium, from matrix elements and potential interfering nuclides. The sorption and elution behavior of plutonium and neptunium onto AG MP-1 M resin was compared with a commonly utilized AG 1-gel-type anion exchanger. Experimental results reveal that the pore structure of the anion exchanger plays a pivotal role in ensuring similar separation behavior of plutonium and neptunium along the separation protocol. It is proven that plutonium-242 ((242)Pu) performs well as a tracer for monitoring the chemical yield of neptunium when using AG MP-1 M resin, whereby the difficulties in obtaining a reliable and practicable isotopic neptunium tracer are overcome. An important asset of the SI setup is the feasibility of processing up to 100 g of solid substrates using a small-sized (ca. 2 mL) column with chemical yields of neptunium and plutonium being ≥79%. Analytical results of three certified/standard reference materials and two solid samples from intercomparison exercises are in good agreement with the reference values at the 0.05 significance level. The overall on-column separation can be completed within 3.5 h for 10 g of soil samples. Most importantly, the anion-exchange mini-column suffices to be reused up to 10-fold with satisfactory chemical yields (>70%), as demanded in environmental monitoring and emergency scenarios, making the proposed automated assembly well-suited for unattended and high-throughput analysis.     

A high-efficiency cross-flow micronebulizer interface for capillary electrophoresis and inductively coupled plasma mass spectrometry.

A pneumatic nebulizer interface for capillary electrophoresis (CE) and inductively coupled plasma mass spectrometry (ICPMS) is reported. The interface is constructed using a high-efficiency cross-flow micronebulizer (HECFMN) and has the following features. (1) Makeup solutions can be fed to the interface by nebulizer self-aspiration and liquid gravity pressurization. (2) The liquid dead volume of the interface is approximately 65 nL, much smaller than those (200-2500 nL) reported for other interfaces. (3) The interface can be stably operated at a liquid flow rate down to 5 microL/min with a high analyte transport efficiency up to 95% to the plasma and (4) does not induce noticeable laminar flow in the CE capillary at typical nebulizer gas flow rates of 0.8-1.2 L/min. Because of these features, baseline resolution of 10 lanthanides with a CE-ICPMS system using the HECFMN interface is achieved, and detection limits and peak asymmetry are 0.05-1 microg/L and 0.93-1.23, respectively, improved significantly over those reported previously for a CE-ICPMS system using a high-efficiency nebulizer interface. Peak precision for the 10 lanthanides is in the range of 6.2-12.3% RSD (N = 5). Peak widths are from 9.1 s for 139La to 17.9 s for 175Lu. The effects of nebulizer gas flow rate, makeup solution flow rate, and spray chamber volume on CE-ICPMS signal intensity and separation are also evaluated for the HECFMN interface by the separation of Cr3+ and Cr2O7(2-).     

Hydride generation interface for speciation analysis coupling capillary electrophoresis to inductively coupled plasma mass spectrometry

A novel hydride generation (HG) interface for coupling capillary electrophoresis (CE) with inductively coupled plasma mass spectrometry (ICPMS) is presented in this work. The CE-HG-ICPMS interface was applied to the separation and quantitation of common arsenic species. Lack of a commercially available HG interface for CE-ICPMS led to a three concentric tube design allowing alleviation of back pressure commonly observed in CE-HG-ICPMS. Due to the high sensitivity and element-specific detection of ICPMS, quantitative analysis of As(III), As(V), monomethylarsonic acid, and dimethylarsinic acid was achieved. Optimization of CE separation conditions resulted in the use of 20 mmol L(-1) sodium borate with 2% osmotic flow modifier (pH 9.0) and -20 kV applied potential for baseline resolution of each arsenic species in the shortest time. Hydride generation conditions were optimized through multiple electrophoretic separation analyses with 5% HCl and 3% NaBH(4) (in 0.2% NaOH) determined to be the optimum conditions. After completion of system optimization, detection limits obtained for the arsenic species were less than 40 ng L(-1) with electromigration time precision less than 1% within a total analysis time of 9.0 min. Finally, the interface was used for speciation analysis of arsenic in river and tap water samples.     

Isolation of Actinides from Irradiated Neptunium and Uranium Targets and Purification with TRU Resin

Within the framework of nuclear-physical experiments on determination of the yields of plutonium and americium isotopes in nuclear reactions ²³⁷Np(³He,xnyp), and also of neptunium and plutonium isotopes in nuclear reactions ²³⁶U(³He,xnyp), a procedure was developed for preparing samples containing americium, plutonium, neptunium, and uranium with a high degree of separation from each other and from the fission and activation products. A new resin for extraction chromatography, TRU-Spec (Eichrom Industries, the United States) was used for isolation of americium, plutonium, neptunium, and uranium from irradiated targets. New data were obtained on the behavior of some fission products in the course of chemical purification with TRU-Spec resin. A procedure was suggested for separation of americium from cerium-group lanthanides.     

Interface for coupling capillary electrophoresis to inductively coupled plasma and on-column concentration technique

A new interface for coupling capillary electrophoresis (CE) to inductively coupled plasma (ICP) was developed. The interface was built outside and independent of the nebulizer and could be easily connected with a microconcentric nebulizer (MCN) as well as conventional pneumatic nebulizers. An on-column concentration technique was used to increase the sensitivity and to enhance the resolution of the system of capillary electrophoresis-inductively coupled plasma atomic emission spectrometry (CE-ICP-AES). By doing this, it was possible to analyze 1 μg/mL of total chromium (prepared with K(2)Cr(2)O(7) and CrCl(3)) and 1 μg/mL of copper consisting of Cu(2+) and Cu(EDTA)(2-) with good spectroscopic intensity and efficient separation. Detection limits of 18 elements for MCN-ICP-AES coupled with CE were assessed by continuous sample introduction without applying high voltage and were found to be 1-4 times higher than those typically obtained by using MCN-ICP-AES for elemental analysis (without connection to the CE interface). When the on-column concentration technique was used, the sensitivities and separations were further improved by increasing the amount of sample. A simple electrolyte (0.05 M HNO(3)) and a large inner diameter capillary (150 μm) could also be used to attain efficient separation.     

Redox Kinetics of U,Pu, and Np in TBP Solutions: VI. Reactions of Neptunium and Plutonium with Organic Reducing Agents: Determination of the Final Oxidation States and Reaction Rates

Reactions of Pu(IV) and Np(VI) with organic reducing agents of various types (substituted hydroxylamines, oximes, aldehydes, etc.) in tributyl phosphate solutions containing nitric acid were studied spectrophotometrically. The molar extinction coefficients of neptunium and plutonium in various oxidation states [Np(IV,V,VI), Pu(III,IV,VI)] in TBP solutions were determined as influenced by HNO₃ and H₂O concentrations and temperature. It was found that organic reducing agents at low HNO₃ concentration convert plutonium and neptunium to Pu(III) and Np(V), respectively. With increasing HNO₃ concentration Pu(III) and Np(V) are partly oxidized back to Pu(IV) and Np(VI), respectively, by reaction with nitrous acid. The rate constants of Pu(VI) and Np(VI) reduction and Np(V) oxidation as influenced by concentration of organic reducing agents and HNO₃ were evaluted from the kinetic data.     

Effective and reproducible capillary electrophoretic separation of thiols under conditions where exceptionally high current is generated

There is an escalating interest in the role of endogenous nitric oxide (NO) in biological systems and how this chemical regulates physiology in normal and disease states. In biological systems, the cellular concentration can be estimated, in the simplest form, by accounting for NO and its common metabolites, nitrate and nitrite. However, since NO is also known to interact with other chemical entities, such as thiols, it would be valuable to have a rapid qualitative assay that could account for thiol binding and S-N bond cleavage in the presence of different reducing agents. A separation buffer consisting of 10 mM phosphate, 10 mM HCl, and 250 mM KCl is shown to be adequate for the separation of glutathione, nitrosylated glutathione, and glutathione disulfide solubilized in 2 M HCl. The current observed under these separation conditions (249 microA at 11 kV) is extremely high by capillary electrophoresis (CE) standards, with a total power (current x voltage/capillary length) calculated to be in excess of 7 W/m. While this exceeds the approximately 1.0 W/m recommended by previous studies as a maximum for CE-based separations, we demonstrate that effective CE separation of thiols can, in fact, be accomplished under these conditions with acceptable reproducibility, provided that buffer depletion issues are addressed.     

High-resolution separation of graphene oxide by capillary electrophoresis

Separation and purification of graphene oxide (GO) prepared from chemical oxidation of flake graphite and ultrasonication by capillary electrophoresis (CE) was demonstrated. CE showed the ability to provide high-resolution separations of GO fractionations with baseline separation. The GO fractionations after CE were collected for Raman spectroscopy, atomic force microscopy, and transmission electron microscopy characterizations. GO nanoparticles (unexfoliated GO) or stacked GO sheets migrated toward the anode, while the thin-layer GO sheets migrated toward the cathode. Therefore, CE has to be performed twice with a reversed electric field to achieve a full separation of GO. This separation method was suggested to be based on the surface charge of the GO sheets, and a separation model was proposed. This study might be valuable for fabrication of GO or graphene micro- or nanodevices with controlled thickness.     

Flow injection analysis of an ultratrace amount of arsenite using a Prussian blue-modified screen-printed electrode

We report here a new electrochemical method for the selective detection of ultratrace amount of arsenite (AsO(2)(-), As(3+)) using a Prussian blue-modified screen-printed electrode (designated as PBSPE) by flow injection analysis (FIA) in 0.1 M, pH 4 KCl/HCl carrier solution. The Prussian yellow/Prussian blue redox couple of the PBSPE was found to mediate the As(3+) oxidation. Various factors influencing the determination of As(3+) were thoroughly investigated in this study. Under the optimized FIA conditions, a linear calibration plot in the range of 50 nM-300 microM with a detection limit (S/N = 3) of 25 nM (i.e., 64.9 pg in 20-microL loop) was observed at an operation potential of +0.6 V vs Ag/AgCl. The sensitivity was good enough to detect arsenite at levels lower than the current EPA standard. This modified electrode showed good resistance to interference from common ions, especially Cl(-), which is generally considered as a major interference in the determination of As(3+) by ICPMS. The practical utility of the PBSPE to detect As(3+) was demonstrated in "blackfoot" disease endemic village groundwater from the southwestern coast area of Taiwan (Pei-Men).     

Fast electrophoretic separation optimization using gradient micro free-flow electrophoresis

The continuous nature of micro free-flow electrophoresis (mu-FFE) was used to monitor the effect of a gradient of buffer conditions on the separation. This unique application has great potential for fast optimization of separation conditions and estimation of equilibrium constants. COMSOL was used to model pressure profiles in the development of a new mu-FFE design that allowed even application of a buffer gradient across the separation channel. The new design was fabricated in an all glass device using our previously published multiple-depth etch method (Fonslow, B. R.; Barocas, V. H.; Bowser, M. T. Anal. Chem. 2006, 78, 5369-5374, ref 1). Fluorescein solutions were used to characterize the applied gradients in the separation channel. Linear gradients were observed when buffer conditions were varied over a period of 5-10 min. The effect of a gradient of 0-50 mM hydroxypropyl-beta-cyclodextrin (HP-beta-CD) on the separation of a group of 4-fluoro-7-nitro-2,1,3-benzoxadiazole (NBD-F) labeled primary amines was monitored as a proof of concept experiment. Direct comparisons to capillary electrophoresis (CE) separations performed under the same conditions were made. Gradient mu-FFE recorded 60 separations during a 5 min gradient allowing nearly complete coverage across a range of HP-beta-CD concentrations. In comparison, 4 h were required to assess 15 sets of conditions across the same range of HP-beta-CD concentrations using CE. Qualitatively, mu-FFE separations were predictive of the migration order and spacing of peaks in CE electropherograms measured under the same conditions. Data were fit to equations describing 1:1 analyte-additive binding to allow a more quantitative comparison between gradient mu-FFE and CE.     

A Review of Finnish-Russian Cooperation in Nuclear Chemistry and Radiochemistry during 1988-20001,2

A review of Finnish-Russian cooperation in nuclear chemistry and radiochemistry during 1988-2000 is presented. A summary of cyclotron production methods of 236Pu, (2.851 years), 237Pu (45.1 days), and 235Np (396 days) tracers via nuclear reactions with protons and ³He ions on 236,238U and 237Np targets in wide energy ranges is given. Chemical methods for separation of the tracers from the irradiated uranium and neptunium targets are described. The yields and radionuclide purities of the tracers produced are presented and discussed. The optimal methods for the production of neptunium and plutonium tracers are suggested.     

Off-line coupling of capillary electrophoresis to substrate-assisted laser desorption inductively coupled plasma mass spectrometry

A novel off-line coupling of capillary electrophoresis (CE) and inductively coupled plasma mass spectrometry (ICPMS) is reported here. The coupling interface is based on the connection of a separation capillary to a deposition capillary via a liquid junction maintaining high separation efficiency and sample utilization due to the self-focusing effect and lack of pressure-induced flow in comparison with nebulizer-like interfaces. The separation is recorded in the form of droplets of CE effluent on a suitable substrate--a poly(ethylene terephthalate) glycol (PETG) sample plate placed inside a partially evacuated chamber. Substrate-assisted laser desorption (SALD) is used to vaporize the sample fractions and to enable further transfer to the ICPMS. The mechanism of SALD is examined using model samples deposited on a variety of substrates. The highest response is obtained for a PETG substrate; sample desorption due to ablation of PETG is found to outweigh direct ablation of sample. Detection limits are given for several metal elements. Finally, a rapid (2.5-min), high-resolution separation of Cr(III)/Cr(VI) species injected in subpicomolar quantity is shown.     

High-throughput comprehensive peptide mapping of proteins by multiplexed capillary electrophoresis

A novel multimodal method for peptide mapping of proteins by multiplexed capillary electrophoresis (CE) is presented. By combining charge to size separations in four different channels and micellar electrokinetic chromatography for hydrophobicity-based separations in two different channels in a 96-capillary array, peptide fragments of digested proteins were readily resolved and showed unique fingerprints. Each capillary spanned several diodes in a photodiode array (PDA) for absorption measurement. The 96 capillaries were monitored simultaneously at 214 nm by a single PDA element with 1,024 diodes, and analysis was completed within 45 min. This demonstrates that it is possible to rapidly screen biotechnological products as well as to efficiently optimize separation conditions in CE by a combinatorial approach.     

Combined processing scheme of WWER-1000 spent nuclear fuel: 2. Experimental trial of extraction processing of fluoride cinder

Several stages of the combined process for WWER-1000 spent fuel reprocessing are experimentally tested, including dissolution of fluoride cinder formed after fluoridation of the fuel and distillation of the essential part of uranium hexafluoride, and also separation and purification of plutonium, neptunium, and residual uranium.     

The use of multidimensional liquid-phase separations and mass spectrometry for the detailed characterization of posttranslational modifications in glycoproteins

The goal of characterization of the proteome, while challenging in itself, is further complicated by the microheterogeneity introduced by posttranslational modifications such as glycosylation. A combination of liquid chromatography (LC), capillary electrophoresis (CE), and mass spectrometry (MS) offers the advantages of unique selectivity and high efficiency of the separation methods combined with the mass specificity and sensitivity of MS. In the current work, the combination of liquid-phase separations and mass spectrometry is demonstrated through the on-line coupling of electrospray ionization mass spectrometry (ESI-MS) and off-line coupling with matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI TOF-MS). LC/ESI-MS yields real-time results while maintaining the separation obtained from the LC analysis. CE/MALDI TOF-MS offers high-mass detection and extremely low detection limits. The unique separation selectivity of CE relative to reversed-phase HPLC separations of the members of a glycopeptide family was used to develop an integrated multidimensional analysis achieved by the off-line coupling of LC, CE, and MALDI TOF-MS. To demonstrate the applicability of these techniques to the characterization of the heterogeneity of posttranslational modifications present in glycoproteins, we will report on the study of the glycoforms present in a N-linked site in a single-chain plasminogen activator (DSPAα1).     

A spectrophotometric study of the reduction of Pu(VIII) and Pu(VII) in alkaline solutions

The reduction of Pu(VIII) with water in ozonized 15 and 6 MNaOH solutions after termination of the ozone bubbling was studied by spectrophotometry. Kinetic curves reflecting the whole set of processes that occur in NaOH solutions of different concentrations were obtained. Calculations performed with the experimental curves made it possible to construct the kinetic curves describing the behavior of plutonium in higher oxidation states in solution and to obtain the individual absorption spectra of Pu(VII) and Pu(VIII). The processes occurring in ozonized solutions of Pu(VI) in 6 and 15 M NaOH after termination of the ozone bubbling were found to occur by different mechanisms, yielding in 4 days Pu(VI) and Pu(V), respectively.     

Capillary electrophoresis separations on a planar chip with the column-coupling configuration of the separation channels

Some basic aspects of capillary electrophoresis (CE) separations on a poly(methyl methacrylate) chip provided with two separation channels in the column-coupling (CC) configuration and on-column conductivity detectors were studied. The CE methods employed in this study included isotachophoresis (ITP), capillary zone electrophoresis (CZE), and CZE with on-line ITP sample pretreatment (ITP-CZE). Hydrodynamic and electroosmotic flows of the solution in the separation compartment of the chip were suppressed, and electrophoresis was a dominant transport process in the separations performed by these methods. Very reproducible migration velocities of the separated constituents were typical under such transport conditions, and consequently, test analytes could be quantified by various ITP techniques with 1-2% RSD. The CC configuration of the separation channels provides means for an effective combination of an enhanced load capacity of the separation system with high detection sensitivities for the analytes in concentration-cascade ITP separations. In this way, for example, succinate, acetate, and benzoate could be separated also in instances when they were present in the loaded sample (1.2 microL) at 1 mmol/L concentrations while their limits of detection ranged from 8 to 12 micromol/L concentrations. A well-defined ITP concentration of the analyte(s) combined with an in-column sample cleanup (via an electrophoretically driven removal of the matrix constituents from the separation compartment) can be integrated into the separations performed on the CC chip. These sample pretreatment capabilities were investigated in ITP-CZE separations of model samples in which nitrite, phosphate, and fluoride (each at a 10 micromol/L concentration) accompanied matrix constituents (sulfate and chloride) at considerably higher concentrations. Here, both the concentration of the analytes and cleanup of the sample were included in the ITP separation in the first separation channel while the second separation channel served for the CZE separation of the ITP pretreated sample and the detection of the analytes.     

Analysis and optimization of nonequilibrium capillary electrophoresis of alpha-fetoprotein isoforms

The L3 isoform of alpha-fetoprotein (AFP) is a specific marker for hepatocellular carcinoma. The separation and quantitation of L3 isoform from the L1 isoform is facilitated by Lens culinaris agglutin (LCA) affinity of the L3 isoform. The affinity-based separation is characterized by nonequilibrium conditions since electrophoresis perturbs the species concentrations away from equilibrium. The design of such separations requires careful consideration of the interplay between the reaction, diffusion, and separation time scales. We performed experiments to investigate the effect of separation parameters such as LCA concentration and CE voltage on the L1-L3 separation dynamics. We also describe a comprehensive mathematical model to predict electropherograms for affinity-based separations. The model includes the effects of molecular diffusion, electromigration, nonequilibrium reaction, and detection process. Together, the results demonstrate a process by which to optimize the affinity-based separations of AFP isoforms. We also obtained the kinetic rate constants for LCA affinity (kon=1.6x10(3) mol(-1) s(-1) L, koff=1x10(-3) s(-1)) by comparing the model predictions with experimental data. This study provides insight into the physics of affinity-based separations and can be extended to describe and optimize other nonequilibrium CE systems.     

Fourier transform capillary electrophoresis with laminar-flow gated pressure injection

Fourier transform capillary electrophoresis (FTCE) was developed as a method to improve signal-to-noise ratio (S/N) and resolution in capillary electrophoresis (CE) separation. In FTCE, multiple simultaneous CE separations were performed in the same channel system and interrogated using a single-point detector. To illustrate experimentally the improvement offered by FTCE in S/N ratio and resolution, we carried out a modest number (five) of multiple injections and separations. We show even with this small number of separations, S/N increased by a factor of 2.9, and theoretical plate height improved by a factor of more than 30. We demonstrated this technique with laser-induced fluorescence detection, but a wide variety of detection methods are compatible with FTCE.     

Spectroelectrochemical sensing based on multimode selectivity simultaneously achievable in a single device. 20. Detection of metal ions in different oxidation states

Spectroelectrochemical sensing a metal in two different oxidation states, both of which are weakly absorbing in the visible wavelength range, was demonstrated with ferrous and ferric ion. The sensor consisted of an indium tin oxide optically transparent electrode (ITO OTE) coated with a thin film of Nafion preloaded with the ligand 2,2'-bipyridine (bipy). Fe2+ in the sample partitioned into the film where it reacted with bipy to form Fe(bipy)3(2+), which absorbs strongly at 520 nm. The change in absorbance (DeltaA) at 520 nm associated with the accumulation of Fe(bipy)3(2+) complex in the film was measured by attenuated total reflectance spectroscopy and was proportional to the concentration of Fe2+ in the sample. Iron in the Fe3+ form can also be determined, but it has a more complex coordination chemistry involving formation of [Fe2(bipy)4O(H2O)2]4+ as well as Fe(bipy)3(3+) in the film. Fe3+ was detected indirectly by reducing the nonabsorbing Fe3+-bipy complexes that accumulated in the film to absorbing Fe(bipy)3(2+) and monitoring DeltaA at 520 nm. The effects of film thickness and ligand concentration in the film on sensor sensitivity and response time for Fe2+ were evaluated. Detection limits of 0.6 x 10(-6) M for Fe2+ and 2 x 10(-6) M for Fe3+ were obtained with 300 nm thick films after 30 min of exposure to a quiescent sample. Careful manipulation of the potential applied with simultaneous optical detection enables Fe2+ to be distinguished from Fe3+, which is the first step in developing a sensor for speciating the two oxidation states in a mixture.