Enhanced-Fluidity Liquid Chromatography-Mass Spectrometry for Intact Protein Separation and Characterization.

Recent advances in the analysis of proteins have increased the demand for more efficient techniques to separate intact proteins. Enhanced-fluidity liquid chromatography (EFLC) involves the addition of liquefied CO2 to conventional liquid mobile phases. The addition of liquefied CO2 increases diffusivity and decreases viscosity, which inherently leads to a more efficient separation. Herein, EFLC is applied to hydrophobic interaction chromatography (HIC) stationary phases for the first time to study the impact of liquefied CO2 to the chromatographic behavior of proteins. The effects of liquefied CO2 on chromatographic properties, charge state distributions (CSDs), and ionization efficiencies were evaluated. EFLC offered improved chromatographic performance compared to conventional liquid chromatography (LC) methods including a shorter analysis time, better peak shapes, and higher plate numbers. The addition of liquefied CO2 to the mobile phase provided an electrospray ionization (ESI)-friendly and "supercharging" reagent without sacrificing chromatographic performance, which can be used to improve peptide and protein identification in large-scale application.

Control of the adsorption properties of alginate - guar gum matrix functionalized with epichlorohydrin through the addition of different flexible chain polymers as toll for the chymotrypsinogen isolation.

This work addresses the obtaining and characterization of alginate-guar gum matrix, cross-linked with epichlorohydrin in the presence of different flexible chain polymers: polyvinyl alcohol, polyvinyl pyrrolidine and Pluronic® F68. These matrixes were used for the adsorption of chymotrypsinogen and showed an increasing uptake in presence of the flexible chain polymer in the sense: none < Pluronic 68 < polyvinyl pyrrolidine < polyvinyl alcohol. The adsorption process was found to follow a first order kinetics model and was not influenced by the polymer type. It was found that Freundlich model was more suitable for our data. Polyvinyl alcohol and polyvinyl pyrrolidine addition increase the adsorption capacity of the original bed due to an increment in the rigidity of the gel caused by the formation of hydrogen bound between the polysaccharides and synthetics polymers.

A molecular modeling based method to predict elution behavior and binding patches of proteins in multimodal chromatography.

Multimodal (MM) chromatography provides a powerful means to enhance the selectivity of protein separations by taking advantage of multiple weak interactions that include electrostatic, hydrophobic and van der Waals interactions. In order to increase our understanding of such phenomena, a computationally efficient approach was developed that combines short molecular dynamics simulations and continuum solvent based coarse-grained free energy calculations in order to study the binding of proteins to Self Assembled Monolayers (SAM) presenting MM ligands. Using this method, the free energies of protein-MM SAM binding over a range of incident orientations of the protein can be determined. The resulting free energies were then examined to identify the more "strongly bound" orientations of different proteins with two multimodal surfaces. The overall free energy of protein-MM surface binding was then determined and correlated to retention factors from isocratic chromatography. This correlation, combined with analytical expressions from the literature, was then employed to predict protein gradient elution salt concentrations as well as selectivity reversals with different MM resin systems. Patches on protein surfaces that interacted strongly with MM surfaces were also identified by determining the frequency of heavy atom contacts with the atoms of the MM SAMs. A comparison of these patches to Electrostatic Potential and hydrophobicity maps indicated that while all of these patches contained significant positive charge, only the highest frequency sites also possessed hydrophobicity. The ability to identify key binding patches on proteins may have significant impact on process development for the separation of bioproduct related impurities.

Strong cation-exchange chromatography of proteins on a sulfoalkylated monolithic cryogel.

A new strong cation exchanger (SCX) monolithic column was synthesized by at-line surface modification of a cryogel prepared by copolymerization of 2-hydroxyethylmethacrylate (HEMA) and glycidylmethacrylate (GMA). Sodium salt of 3-Mercaptopropane sulfonic acid (3-MPS) was used as the ligand to transform the surface of the monolith into a strong cation exchanger. The obtained material was characterized in terms of elemental analysis, infrared spectroscopy (FTIR), Scanning Electron Microscopy (SEM), Brunauer-Emmett-Teller (BET) N2 adsorption, and used as a stationary phase for strong-cation exchange chromatography of some proteins, such as α-chymotrypsinogen, cytochrome c and lysozyme. Water permeability of the column was calculated according to Darcy's law (2.66×10(-13)m(2)). The performance of the monolithic cryogel column was evaluated on the basis of Height Equivalent to a Theoretical Plate (HETP). Retention behavior of the studied proteins was modeled on the basis of Yamamoto model to understand the role of the ion-exchange mechanism in retention behaviors. The considered proteins were successfully separated, and the obtained chromatogram was compared with that obtained with a non-functionalized cryogel column.

Displacement chromatography of proteins using a retained pH front in a hydrophobic charge induction chromatography column.

The chromatographic separation of two proteins into a displacement train of two adjoined rectangular bands was accomplished using a novel method for hydrophobic charge induction chromatography (HCIC) which employs a self-sharpening pH front as the displacer. This method exploits the fact that protein elution in HCIC is promoted by a pH change, but is relatively independent of salt effects, so that a retained pH front can be used in place of a traditional displacer in displacement chromatography. The retained pH front was produced using the two adsorbed buffering species tricine and acetic acid. The separation of lysozyme and α-chymotrypsinogen A into adjoined, rectangular bands was accomplished with overall recoveries based on the total mass injected greater than 90 and 70%, respectively. The addition of urea to the buffer system increased the sharpness of the pH front by 36% while the yields of lysozyme and α-chymotrypsinogen A based on the total mass eluted increased from 76% to 99% and from 37% to 85%, respectively, when the purities of both proteins in their product fractions were fixed at 85%. The results demonstrate that the method developed in this study is a useful variant of HCIC and is also a useful alternative to other displacement chromatography methods.

Critical differences in chromatographic properties of silica- and polymer-based monoliths.

Chromatographic analytical columns containing porous monolithic beds based on cross-linked polymers and derivatized silica have now been commercially available for several years and, despite some apparent conceptual similarities, are marketed and utilized for quite different chromatographic applications. While this distinction is well-accepted by users, the fundamental differences in chromatographic behavior of these materials that lead to this clear distinction in their primary application areas have not yet been systematically studied. To this end, the present experimental study investigates differences in the apparent chromatographic characteristics when using small molecules with commercially available monolithic reversed-phase analytical columns based on poly(styrene-co-divinyl benzene) and C18-derivatized silica. Relevant practical information is obtained from measurements made by "arrested elution" of non-retained and retained solutes and chromatographic elution performance across a wide range of retention factors with a set of structurally similar small molecules. Observations of apparent diffusion probed with "arrested elution" experiments and mass transport inferred from the observed efficiency at increased flow velocity in the monolithic structures (both under retained and non-retained conditions) lead to the conclusion that fundamentally different solute transport behavior is operative. The silica-based monolithic materials are used to establish a "reference" for comparison to observations with cross-linked porous polymeric monolithic materials. Despite the differences in morphology, chromatographic properties have their origin in the underlying physical structure of pore space. The derivatized surfaces in silica-based materials have their counterpart in pore-fluid gel interfaces in polymeric monoliths. The pore-fluid gel interfaces have their origin in varying solvation of polymer by eluent components. Consequently, they allow varying permeation of small molecules into the solvated polymer via partition. The traversing of small molecules through the polymer monolith's complex nanoscale physical structure plays a key factor when rationalizing any chromatographic performance as seen in the slopes of plate height curves which vary dramatically with mobile phase composition and solute identity.

Hybrid phospholipid bilayer coatings for separations of cationic proteins in capillary zone electrophoresis.

Protein separations in CZE suffer from nonspecific adsorption of analytes to the capillary surface. Semipermanent phospholipid bilayers have been used to minimize adsorption, but must be regenerated regularly to ensure reproducibility. We investigated the formation, characterization, and use of hybrid phospholipid bilayers (HPBs) as more stable biosurfactant capillary coatings for CZE protein separations. HPBs are formed by covalently modifying a support with a hydrophobic monolayer onto which a self-assembled lipid monolayer is deposited. Monolayers prepared in capillaries using 3-cyanopropyldimethylchlorosilane (CPDCS) or n-octyldimethylchlorosilane (ODCS) yielded hydrophobic surfaces with lowered surface free energies of 6.0 ± 0.3 or 0.2 ± 0.1 mJ m(-2) , respectively, compared to 17 ± 1 mJ m(-2) for bare silica capillaries. HPBs were formed by subsequently fusing vesicles comprised of 1,2-dilauroyl-sn-glycero-3-phosphocholine or 1,2-dioleoyl-sn-glycero-3-phosphocholine to CPDCS- or ODCS-modified capillaries. The resultant HPB coatings shielded the capillary surface and yielded reduced electroosmotic mobility (1.3-1.9 × 10(-4) cm(2) V(-1) s(-1) ) compared to CPDCS- and ODCS-modified or bare capillaries (3.6 ± 0.2 × 10(-4) cm(2) V(-1) s(-1) , 4.8 ± 0.4 × 10(-4) cm(2) V(-1) s(-1) , and 6.0 ± 0.2 × 10(-4) cm(2) V(-1) s(-1) , respectively), with increased stability compared to phospholipid bilayer coatings. HPB-coated capillaries yielded reproducible protein migration times (RSD ≤ 3.6%, n ≥ 6) with separation efficiencies as high as 200 000 plates/m.

Purification, cDNA cloning, and recombinant expression of chymotrypsin C from porcine pancreas.

Chymotrypsin C is a bifunctional secretory-type serine protease in pancreas; besides proteolytical activity, it also exhibits a calcium-decreasing activity in serum. In this study, we purified activated chymotrypsin C from porcine pancreas, and identified its three active forms. Active chymotrypsin C was found to be different in the length of its 13-residue activation peptide due to carboxydipeptidase (present in the pancreas) degradation or autolysis of the activated chymotrypsin C itself, resulting in the removal of several C-terminus residues from the activation peptide. After limited chymotrypsin C cleavage with endopeptidase Lys C, several purified peptides were partially sequenced, and the entire cDNA sequence for porcine chymotrypsin C was cloned. Recombinant chymotrypsinogen C was successfully expressed in Escherichia coli cells as inclusion bodies. After refolding and activation with trypsin, the comparison of the recombinant chymotrypsin C with the natural form showed that their proteolytic and calcium-decreasing activities were at the same level. The successful expression of chymotrypsin C gene paves the way to further mutagenic structure-function studies.

Electrostatic model for protein adsorption in ion-exchange chromatography and application to monoclonal antibodies, lysozyme and chymotrypsinogen A.

A model for the adsorption equilibrium of proteins in ion-exchange chromatography explicitly accounting for the effect of pH and salt concentration in the limit of highly diluted systems was developed. It is based on the use of DLVO theory to estimate the electrostatic interactions between the charged surface of the ion-exchanger and the proteins. The corresponding charge distributions were evaluated as a function of pH and salt concentration using a molecular approach. The model was verified for the adsorption equilibrium of lysozyme, chymotrypsinogen A and four industrial monoclonal antibodies on two strong cation-exchangers. The adsorption equilibrium constants of these proteins were determined experimentally at various pH values and salt concentrations and the model was fitted with a good agreement using three adjustable parameters for each protein in the whole range of experimental conditions. Despite the simplifications of the model regarding the geometry of the protein-ion-exchanger system, the physical meaning of the parameters was retained.

Role of polymer-protein interaction on partitioning pattern of bovine pancreatic trypsinogen and alpha-chymotrypsinogen in polyethyleneglycol/sodium tartrate aqueous two-phase systems.

The partitioning pattern of bovine trypsinogen (TRPz) and alpha-chymotrypsinogen (ChTRPz) was investigated in a low impact aqueous two-phase system formed by polyethyleneglycol (PEG) and sodium tartrate (NaTart) pH 5.00. ChTRPz exhibited higher partition coefficients than TRPz did in all the assayed systems. The decrease in PEG molecular weight and the increase in tie line length were observed to displace the partitioning equilibrium of both proteins to the top phase, while phase volume ratios in the range 0.5-1.5 showed not to affect protein partitioning behaviour. Systems formed by PEG of molecular weight 600 with composition corresponding to a high tie line length (PEG 12.93%, w/w and NaTart 21.20%, w/w) are able to recover most of both zymogens in the polymer-enriched phase. A crucial role of PEG-protein interaction in the partitioning mechanism was evidenced by isothermal calorimetric titrations. The major content of highly exposed tryptophan rests, present in ChTRPz molecule, could be considered to be determinant of its higher partition coefficient due to a selective charge transfer interaction with PEG molecule. A satisfactory correlation between partition coefficient and protein surface hydrophobicity was observed in systems formed with PEGs of molecular weight above 4000, this finding being relevant in the design of an extraction process employing aqueous two-phase systems.

Noncovalent poly(1-vinylpyrrolidone)-based copolymer coating for the separation of basic proteins and lipoproteins by CE.

A new simple and fast noncovalent coating method based on poly(1-vinylpyrrolidone-co-2-dimethylaminoethyl methacrylate) copolymer was developed for CE. Merely 2 min flushing of the capillary with the poly(1-vinylpyrrolidone-co-2-dimethylaminoethyl methacrylate) copolymer was required. The copolymer is adsorbed onto the fused-silica surface by hydrogen bonding and electrostatic interactions. EOF was almost totally suppressed over a wide pH range. The coating conditions (flushing time, copolymer concentration, and the concentration and pH of background electrolyte solution) and the stability of the coating were optimized, and the coated capillary was successfully applied to the fast separation of four basic proteins: lysozyme, cytochrome c, ribonuclease A, and alpha-chymotrypsinogen A. Separation efficiencies were high, ranging from 386 000 to 738 000 plates/m at 40 mM pH 4.0 acetate buffer being comparable to values obtained on classical covalent PVP-coated capillary. The RSD of migration times of basic proteins for 200 times successive runs were all below 1.0% (n=200, 3 days). A successful capillary performance was demonstrated also to the separation of low- and high-density lipoproteins at acidic pH.

Effects of thermal heterogeneity in hydrophobic interaction chromatography.

Manipulating temperature and salt concentration can have a powerful effect on the separation effectiveness in hydrophobic interaction chromatography (HIC). However, use of temperature as an operating variable in large-scale applications may involve undesirable consequences such as radial heterogeneity of the column temperature. In this study non-ideal effects of heat transfer in HIC columns were analyzed. The radial temperature gradients were measured by thermocouples immersed in a bed packed into a preparative column. The column wall was either thermostatted by a water jacket or left under ambient conditions. The influence of ineffective column thermostatting and of heat losses on the radial temperature profiles was demonstrated and predicted by a model of heat dispersion in a packed bed. To analyze possible positive or negative effects of thermal heterogeneity on band propagation, non-isothermal chromatographic elution of a model protein (alpha-chymotrypsinogen A) was recorded under salt gradient conditions as well as at constant salt concentration. To predict temperature and concentration profiles a model of the column dynamics was used. The model accounted for kinetics of mass and heat transfer. A good agreement between experimental and simulated profiles was achieved. It was shown that by proper selection of the process conditions undesirable temperature effects can be avoided or controlled.

Capillary electrophoresis of intact basic proteins using noncovalently triple-layer coated capillaries.

The usefulness of a noncovalent, positively charged capillary coating for the efficient analysis of intact basic proteins with CE was studied. Capillaries were coated by subsequent flushing with solutions of 10% w/v Polybrene (PB), 3% w/v dextran sulfate (DS), and again 10% w/v PB. Coating characterization studies showed that stable coatings could be produced which exhibited a pH-independent and highly reproducible EOF. The PB-DS-PB coating was evaluated with Tris phosphate BGEs of various pH using the four basic model proteins: alpha-chymotrypsinogen A, ribonuclease A, cytochrome c, and lysozyme. Typical migration time RSDs for the proteins were less than 0.85%, and apparent plate numbers were above 125,000 using a capillary length of 40 cm. The high separation efficiency allowed detection of several minor impurities in the model proteins. Using a BGE of medium pH, the CE system with triple-layer coating appeared to be useful for the repeatable profiling of recombinant humanized mouse monoclonal immunoglobulin G(1) showing a characteristic pattern of glycoforms. The CE system was also applied to the characterization of two llama antibodies, which were produced in Saccharomyces cerevisiae, revealing the presence of a side product in one of the antibodies. The high migration time stability allowed the reliable determination of antibody-antigen binding by monitoring migration time shifts. Finally, the feasibility of using the PB-DS-PB coated capillaries for CE with mass spectrometric detection was shown by the characterization of the impure llama antibody sample.

Evaluation of chemically selective displacer analogues for protein purification.

A library of molecular analogues to the selective displacer, N'1'-(4-methylquinolin-2-yl)ethane-1,2-diamine dinitrate, was employed to study the effects of changes in displacer chemistry on their efficacy for selective separations. High throughput screens were carried out using a robotic liquid handling system to examine the ability of these compounds to selectively displace proteins in batch adsorption systems. Experiments were conducted using the model protein pairs ribonuclease A/alpha-chymotrypsinogen A and cytochrome C/lysozyme on a strong cation exchanger. Selectivity pathway and DC-50 plots were constructed from the analogue screen data, and results indicated that minor changes in the molecular design of the displacer can have a significant impact on the separation behavior. Specifically, charge density and spacing of resin and protein interaction moieties were found to be important. The screen also identified a new displacer, 4-methyl-2-piperazin-1-yl-quinoline, which produced a more selective displacement than previously reported with the original compound. A steric mass action dynamic affinity plot was constructed to validate that this new displacer was acting as a chemically selective, rather than a steric mass action selective displacer. Finally, saturation transfer difference NMR experiments were conducted to examine protein-displacer interactions with these displacers and protein pairs. These results demonstrate how subtle changes in displacer design can be employed to fine-tune the separation performance of chemically selective displacers.

Single cell analysis in full body quartz glass chips with native UV laser-induced fluorescence detection.

In order to investigate the individual and inhomogenous cellular response, e.g. to external stimuli, single cell analysis is mandatory and may provide new cognitions in proteomics as well as in other fields of systems biology in the future. Here, we report on novel chip architectures for single cell analysis based on full body quartz glass microfluidic chips (QG chips) that extend our previous studies in polydimethylsiloxane (PDMS) chips, and enhance the detection sensitivity of native UV laser-induced fluorescence (UV-LIF) detection. Detection of a 10nM tryptophan solution with an S/N ratio of 11.9, which gives a theoretical limit of detection of 2.5 nM (with S/N=3), was possible. With these optimizations the three proteins alpha-chymotrypsinogen A, ovalbumin and catalase each at a concentration of 100 microg/mL (equal to 4 microM, 0.4 microM and 2.2 microM) were injected electrokinetically and could be separated with nearly baseline resolution. Furthermore, fluorescence spectra (excitation wavelength, lambda(ex) = 266 nm) clearly demonstrate the favourable properties like the very high UV transparency and the nearly vanishing background fluorescence of the QG chips as compared to PDMS chips and to PDMS quartz window (PQW) chips. Finally we exploit the improved sensitivity for single cell electropherograms of Spodoptera frugiperda (Sf9) insect cells.

Features of partitioning pattern of two pancreatic enzymatic precursors: trypsinogen and chymotrypsinogen in polyethyleneglycol-sodium citrate aqueous biphasic systems.

The partitioning behaviour of bovine trypsinogen and alpha-chymotrypsinogen, enzymatic precursors with similar physicochemical properties, was investigated in different polyethyleneglycol/sodium citrate aqueous two-phase systems. The effect of different factors such as polyethyleneglycol molecular weight, pH, tie line length and temperature was also examined. The increase of pH and the decrease of polyethyleneglycol molecular weight displaced the partitioning equilibrium of both proteins to the top phase. An enthalpy-entropy compensation pattern was observed, indicating the participation of water molecules in the partitioning mechanism. TRPz phase equilibrium showed to be more displaced to the citrate-rich phase than ChTRPz for most of the assayed systems. From a practical view, the aqueous two-phase system formed by polyethylenglycol of molecular weight 1450 and sodium citrate pH 8.20 showed the best capability for separating both proteins. When a mixture formed by equal quantities of both zymogens was partitioned in this system, significant recoveries (about 60%) were obtained. Purity values were improved significantly (84-89%) by either developing a second extractive step or increasing the top-bottom volume ratio.

Reaction of fluorogenic reagents with proteins II: capillary electrophoresis and laser-induced fluorescence properties of proteins labeled with Chromeo P465.

The fluorogenic reagent Chromeo P465 is considered for the analysis of proteins by capillary electrophoresis with laser-induced fluorescence detection. The reagent was first used to label alpha-lactalbumin; the product was analyzed by capillary zone electrophoresis in a sub-micellar sodium dodecyl sulfate (SDS) buffer. The product generated a set of equally spaced but poorly resolved peaks that formed a broad envelope with a net mobility of 4 x 10(-4)cm(2) V(-1) s(-1). The components of the envelope were presumably protein that had reacted with different numbers of labels. The mobility of these components decreased by roughly 1% with the addition of each label. The signal increased linearly from 1.0 nM to 100 nM alpha-lactalbumin (r(2)=0.99), with a 3sigma detection limit of 70 pM. We then considered the separation of a mixture of ovalbumin, alpha-chymotrypsinogen A, and alpha-lactalbumin labeled with Chromeo P465; unfortunately, baseline resolution was not achieved with a borax/SDS buffer. Better resolution was achieved with N-cyclohexyl-2-aminoethanesulfonic acid/Tris/SDS/dextran capillary sieving electrophoresis; however, dye interactions with this buffer system produced a less than ideal blank.

Enhanced stability of surfactant-based semipermanent wall coatings in capillary electrophoresis using oppositely charged surfactant.

Semipermanent surfactant coatings are effective for the prevention of wall adsorption of proteins in CE. However, they often suffer from their unsatisfactory coating stability as they essentially degrade from the capillary walls after the surfactants are removed from the buffer. In this paper, we proposed a facile and universal method to improve the stability of semipermanent surfactant coatings based on addition of an oppositely charged surfactant into the coating. Didodecyldimethylammonium bromide (DDAB) and a gemini surfactant, 18-6-18, were used as the model semipermanent coatings, and sodium dodecyl sulfate (SDS) was chosen as their oppositely charged surfactant. SDS can strongly alter the packing parameter P of the cationic surfactants, and consequently mediates the coating stability. With the increase of SDS concentration in coating, the coating stability first dramatically increases due to the enlarged P, and then decreases due to the weakness of electrostatic interaction between the capillary wall and surfactant coating. At the proper SDS concentration, very stable coatings can be obtained that, even after rinsing under 138 kPa for 60 min, the reversed electroosmotic flow (EOF) only decreases by 3.6%. These SDS-enhanced coatings show excellent stability and reproducibility in protein separation (RSD of migration time <1.1% for run-to-run assay, n=9). Also, the high separation efficiency (>500,000 plates/m) and fine recovery of tested proteins indicate that these coatings are powerful in wall adsorption suppression. Finally, we found that the separation efficiency of protein was a more exact indicator for the coating stability than the traditional EOF magnitude.

Displacement chromatography of proteins on hydrophobic charge induction adsorbent column.

Displacement chromatography of protein mixtures is proposed on hydrophobic charge induction chromatography (HCIC). We have used an HCIC medium, MEP-Hypercel as the stationary phase and a quaternary ammonium salt, benzethonium chloride, as the displacer. It was found that the multiple interactions between proteins/displacer and the HCIC sorbent, i.e. hydrophobic interaction and charge repulsion, enabled a greater flexibility for the design of displacement processes and ease of column regeneration by adjustment of pH. The capacity factors of proteins and displacers were used to predict their performances in column displacement, and the experimental results agreed well with the prediction. An isotachic displacement train of lysozyme and alpha-chymotrypsinogen A was formed with benzethonium chloride as the displacer at pH 5.0 with good yields and purities of the two proteins. Column regeneration was efficiently achieved by charge repulsion between the displacer and the adsorbent at lower pH values (pH 3 and 4). The results indicate that the displacement chromatography on HCIC is a good alternative to traditional hydrophobic displacement chromatography.

Cationic lipid vesicles as coating precursors in capillary electrochromatography: separation of basic proteins and neutral steroids.

1,2-Dioleyl-3-trymethylammoniumpropane (DOTAP) lipid vesicles were employed as coating precursors to obtain a semipermanent cationic lipid bilayer in silica capillary. The coating procedure was relatively fast and simple. Reliable results for the separation of four basic proteins (alpha-chymotrypsinogen A, ribonuclease A, cytochrome C, lysozyme) were obtained by using an acetate buffer under acidic conditions. The RSDs of the migration times were not higher than 0.5% run-to-run and about 1% day-to-day (3 days), while the RSDs of the peak areas were within 7% day-to-day (3 days). The day-to-day RSD of the EOF mobility of about 1%, confirmed that the DOTAP coating was stable for the separation of basic proteins, under acidic buffers. In addition to basic proteins the DOTAP coating was found suitable under acidic conditions for the repeatable separation of neutral steroids. The potential of DOTAP as a carrier in background electrolyte solution was studied.