A novel method of chiral ligand-exchange CE was developed with either L- or D-lysine (Lys) as a chiral ligand and zinc(II) as a central ion. This type of chiral complexes was explored for the first time to efficiently separate either individual pairs of or mixed aromatic amino acid enantiomers. Using a running buffer of 5 mM ammonium acetate, 100 mM boric acid, 3 mM ZnSO(4) x 7H(2)O and 6 mM L-Lys at pH 7.6, unlabeled D,L-tryptophan, D,L-phenylalanine, and D,L-tyrosine were well separated, giving a chiral resolution of up to 7.09. The best separation was obtained at a Lys-to-zinc ratio of 2:1, zinc concentration of 2-4 mM and running buffer pH 7.6. The buffer pH was determined to have a strong influence on resolution, while buffer composition and concentration impacted on both the resolution and peak shape. Boric acid with some ammonium acetate was an adoptable buffer system, and some additives like ethylene diamine tetraacetic acid capable of destroying the complex should be avoided. Fine-tuning of the chiral resolution and elution order was achieved by regulating the ratio of L-Lys to D-Lys; i.e. the resolution increased from zero to its highest value as the ratio ascended from 1:0 to 1:infinitive, and L-isomers eluted before or after D-isomers in excessive D- or L-Lys, respectively.
An acid barrage stacking (ABS) method has been shown to be feasible for online anti-salt injection in CE of 9-fluorenylmethyl chloroformate (FMOC)-labeled amino acids (AAs) detected by common UV absorption. The operation was performed on normal polar CE by sucking in an extra plug of acid following a sample zone, serving as a selective acid barrage to block the backward migration of weak anionic analytes due to a sudden mobility reduction via acid-base reaction which does not affect strong co-ions such as Cl(-) to penetrate the barrage freely. By CE-UV of FMOC-AAs in various NaCl solutions, the effectiveness of ABS was firmly validated, able to stand up to 500 mM NaCl and to stack analytes by 10(3)-fold calculated from the UV detection limits, that is 0.01 microM for ABS and 10 microM for non-stacking injection. The method was also validated by determining trace Glu and Asp in real samples of rat brain microdialysate, rat serum and human saliva. The intraday RSDs were 0.33-4.9% for migration time and 1.8-9.6% for peak area. The recoveries measured by spiking technique were 82-115% for Glu and 86-116% for Asp. Working equations were obtained by plotting peak height vs. concentration at 0.1-50 microM, with correlation coefficients of >0.999. The contents of Glu and Asp were thus found at 0.26-0.83 microM and 0.24-0.64 microM respectively, in rat brain microdialyste; 37-40 microM and 8.4-10 microM, respectively, in rat serum; and 3.5-5.8 microM and 1.0-4.1 microM, respectively in human saliva. They were consistent with the data from other methods.
A novel method has been developed for the on-column labeling of amino acid enantiomers with 9-fluoroenylmethyl chloroformate (FMOC), followed by chiral CE with a binary chiral selector system and UV detection. Efficient labeling was achieved by sequential injection of amino acids, borate buffer, and FMOC labeling solution at 0.2 psi for 6 s. After injection, the sandwich sections were electrically mixed at 250 V/cm for 6 s and allowed to react (electric field-free) at room temperature for 2 min. With this procedure, successful online-labeling and chiral CE separation of 19 pairs of amino acids (AA) have been conducted, giving 17 pairs fully enantioresolved (R(s) = 1.73-5.79) and two pairs partially resolved (Ala, R(s) = 0.39 and Arg, R(s) = 1.15) using a running buffer of 150 mM borate containing 30 mM beta-CD, 30 mM sodium taurodeoxycholate (STDC), and 15% isopropanol (IPA) at pH 9.0. Chiral CE of some mixed pairs was also demonstrated, much the same as using precolumn labeling. Surprisingly, Met, Asp, Asn, Gln, and His gained even higher enantioresolution (up to 2.5%) compared with the case of precolumn labeling. As validated by both artificially prepared solutions and serum samples, the method was applicable to the quantitative determination of AA, with LODs down to 4.0 microM. The method allowed the determination of D-AA at the ratio of 1:100 (D:L).
This investigation aimed at improving the performance of Taylor's dispersion analysis for the fast and accurate measurement of diffusion coefficient of a minute solute in various solvents. The investigation was carried out on a capillary electrophoresis instrument by monitoring the UV absorption peak of a solute pulse and calculating the diffusion coefficient by peak efficiency. With L-phenylalanine as a main testing solute, some key factors were afterward disclosed including especially the capillary size, carrier flow velocity, injection volume and capillary conditioning. Peak tailing, large volume of sample injection and slow migration were found to underestimate the diffusion coefficient while very fast migration and high sample concentration caused overestimation. At a moderate flow velocity of 0.1-1 cm/s with a capillary of 72.44 µm I.D.×60 cm (50 cm effective) maintained at 25℃, the diffusion coefficient of aqueous L-phenylalanine was determined, giving a value of 7.02×10 −6 cm 2 /s with error <2% and relative standard deviation <0.2% (n=3). The method was shown to be applicable to the measurement of various samples such as aqueous phenylalanine, acetone, phenol, toluene and benzene, and nonaqueous benzene (in ethanol or 1-butanol).diffusion coefficient, aqueous and nonaqueous samples, Taylor's dispersion analysis, capillary electrophoresis, fast and accurate measurement Diffusion coefficient (D m 2 /s) is an important physicochemical constant useful in the investigation of biological molecules [1,2] , and is able to provide us valuable information about molecular size, topology, conformation [1,[3][4][5] and so forth. The diffusion of a protein through gels and solutions is critical in drug delivery [6][7][8] . Environmental pollution, chemical reaction, and chromatographic or electrophoretic separations also largely depend on molecular diffusing speed [9,10] . In an extreme case like heterogeneous reactions occurring on surfaces or being catalyzed by surfaces, their reaction rates are often restricted by the diffusions of reactants and products to and from the reactive surfaces [11] .The determination of D has hence been studied for a long time, resulting in an exploration of various methods such as diaphragm-cell [12][13][14] and membrane-based [15] techniques, interferometers [16] , light scattering measurements [17][18][19] , nuclear magnetic resonance (NMR) [20][21][22][23][24] , and dispersing approaches based on Taylor's theory [25][26][27][28][29][30] . Among them, the dispersing approaches have inherently advantages worthy of further exploration.Taylor was the first to treat the dispersion of a solute "plug" flowing through a uniform circular tube, building up a relationship between D and the dispersion of the solute plug. After Taylor's treatment, Aris [27] derived a quantitative equation between D and the so-called dispersion coefficient δ for a circular transporting column
Melamine as an important chemical raw material and a harmful additive in foods has attracted many people's attention. In the present paper, The graphite-epoxy composited solid phase electrode was modified with bismuth layer by cyclic voltammetric deposition of bismuth from Bi(NO 3 ) 3 aqueous solution including 0.10 M HNO 3 , and hydrolyzed into micro bismuthyl chloride on-sites. Melamine in fresh milk was extracted with solid phase micro-extraction on the bismuthyl chloride modified graphite-epoxy composited solid electrode. The adsorption of melamine on bismuthyl chloride particle surfaces follows a Freundlich adsorption model, and results in the decrease of the reduction peak current of bismuth in bismuthyl chloride, and determined by differential pulse voltammetry from fresh milk in a larger concentration range of 10 -4 10 -12 M with detection limit of 2.5 10 -12 M and relative standard deviation of 2.7%. The method is sensitive, convenient and was applied in the detection of melamine in fresh milk with relative deviation of 4.2% in content of 0.45 mg/kg melamine in the fresh milk.
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