Development and optimization of an integrated PDMS based‐microdialysis microchip electrophoresis device with on‐chip derivatization for continuous monitoring of primary amines

An all‐PDMS on‐line microdialysis‐microchip electrophoresis with on‐chip derivatization and electrophoretic separation for near real‐time monitoring of primary amine‐containing analytes is described. Each part of the chip was optimized separately, and the effect of each of the components on temporal resolution, lag time, and separation efficiency of the device was determined. Aspartate and glutamate were employed as test analytes. Derivatization was accomplished with naphthalene‐2,3,‐dicarboxyaldehyde/cyanide (NDA/CN^?), and the separation was performed using a 15‐cm serpentine channel. The analytes were detected using LIF detection.     

Efficient capillary electrophoresis separation and determination of free amino acids in beer samples

Simultaneous detection of various o‐phthalaldehyde (OPA)‐labeled amino acids (AAs) in food samples was reported based on CE separation. Ionic liquid was used for the first time for CE analysis of AAs with in‐capillary derivatization. Several other additives, including SDS, α/β‐CD, and ACN, as well as key parameters for CE separation (buffer pH value, separation voltage), were also investigated. Our results show that the multiple additive strategy exhibits good stable and repeatable character for CE analysis of OPA‐labeled AAs, for either in‐capillary derivatization or CE separation, and allows simultaneous quantification of different OPA‐labeled AAs in a large concentration range of 50 μM to 3.0 mM with LOD down to 10 μM. Seventeen OPA‐labeled AAs, except for two pairs of AAs (His/Gln and Phe/Leu), which were separated with resolutions of 1.1 and 1.2, respectively, were baseline separated and identified within 23 min using the present multiple additive strategy. The method was successfully applied for simultaneous analysis of AAs in seven beer samples and as many as eleven trace‐amount AAs were detected and quantified, indicating the valuable potential application of the present method for food analysis.     

Intracellular FITC-derivatization with PEG

In order to investigate the amino acids (AAs) in plant cells, we explore an avenue for intracellular derivatization with FITC. In this method, FITC was used to mark AAs in living protoplasts derived from embryogenic calli of common wheat (Triticum aestivum L. c.v. Jinan 177) mediated by PEG. After FITC-derivatization, the AAs in the lysate were determined by CE. The result reveals that this PEG method can be used to transfer FITC into plant cells efficiently, which provides a good method for AA analysis in plant cells.     

Determination of <Emphasis Type="SmallCaps">D</Emphasis>- and <Emphasis Type="SmallCaps">L</Emphasis>-amino acids produced by cyanobacteria using gas chromatography on Chirasil-Val after derivatization with pentafluoropropyl chloroformate

A rapid and simple method was developed for the determination of free amino acids (AAs) released from cyanobacteria. The procedure involves trapping of AAs from the centrifuged cyanobacterial culture fluid on a cation-exchange resin, their release together with the resin by direct treatment with the reaction medium, followed by immediate derivatization with a corresponding chloroformate. The extractive alkylation transfers the analytes into an organic phase, an aliquot of which is subjected to GC analysis. Identification and quantification of AAs was performed by GC/MS and GC/FID, respectively, using propyl chloroformate (PCF) as the derivatization reagent. For chiral analysis, the cyanobacteria extracts were treated with 2,2,3,3,3-pentafluoropropyl chloroformate (PFPCF) to create more volatile analytes. Separation of the AA enantiomers was accomplished on a Chirasil-Val capillary column and the D/L enantiomeric ratios were determined. AAs of cyanobacteria are considered to be important for the assessment of energy flow in an aquatic food web, nutrition value of cyanobacteria in a food web and for cell–cell communication within cyanobacteria. The highest levels of AAs were found in the summer period at the beginning of the season (July). In the September and October samples, the amount of AAs was lower, the number of D-AAs decreased and the D/L ratio was higher than in the July sample. Based on the obtained results it can be assumed that young populations excrete AAs in higher concentrations and a different composition compared to actively growing populations. Figure PFPCF derivatization scheme     

Simultaneous Determination of Safingol and d-erythro-Sphinganine in Human Plasma by LC with Fluorescence Detection

l-threo-Sphinganine (safingol) is a putative synthetic sphingosine kinase inhibitor currently being tested in clinical trials as an anticancer agent. To enable defining the pharmacokinetic properties of safingol in humans, we developed a sensitive analytical method to simultaneously quantitate safingol and its naturally-occurring diastereomer, d-erythro-sphinganine in human plasma. Of the two different fluorogenic derivatization agents (NDA and OPA) and several pH conditions compared for the derivatization, we found that NDA derivatization achieved more than 20 times greater sensitivity compared with OPA derivatization, and pH 9.0 showed the highest sensitivity for both compounds. An analytical method for liquid chromatography (LC) with a fluorescence detector (FLD) was developed and validated with calibration curve ranges of 20–1,000 ng mL⁻¹ for safingol and d-erythro-sphinganine. Our LC-FLD method using NDA-derivatization enabled simultaneous quantification of safingol and its naturally-occurring diastereomer, d-erythro-sphinganine with satisfactory sensitivity in human plasma.

     

Simultaneous Determination of Safingol and d-erythro-Sphinganine in Human Plasma by LC with Fluorescence Detection

l-threo-Sphinganine (safingol) is a putative synthetic sphingosine kinase inhibitor currently being tested in clinical trials as an anticancer agent. To enable defining the pharmacokinetic properties of safingol in humans, we developed a sensitive analytical method to simultaneously quantitate safingol and its naturally-occurring diastereomer, d-erythro-sphinganine in human plasma. Of the two different fluorogenic derivatization agents (NDA and OPA) and several pH conditions compared for the derivatization, we found that NDA derivatization achieved more than 20 times greater sensitivity compared with OPA derivatization, and pH 9.0 showed the highest sensitivity for both compounds. An analytical method for liquid chromatography (LC) with a fluorescence detector (FLD) was developed and validated with calibration curve ranges of 20–1,000 ng mL^?1 for safingol and d-erythro-sphinganine. Our LC-FLD method using NDA-derivatization enabled simultaneous quantification of safingol and its naturally-occurring diastereomer, d-erythro-sphinganine with satisfactory sensitivity in human plasma.     

Method of intracellular naphthalene-2,3-dicarboxaldehyde derivatization for analysis of amino acids in a single erythrocyte by capillary zone electrophoresis with electrochemical detection

A novel method of intracellular derivatization was developed. In this method, the derivatization reagents [naphthalene-2,3-dicarboxaldehyde (NDA) and CN-] were introduced into living cells by electroporation for the derivatization reaction. After completion of derivatization reaction in cells, a single cell was drawn into the capillary tip by electroosmotic flow. Then the lysing solution was introduced into the capillary by diffusion. Once the individual cell was lysed, the derivatized amino acids in the individual cell were separated by capillary zone electrophoresis and detected by end-column amperometric detection at the outlet of the capillary. This method of intracellular NDA derivatization confined the analytes and the derivatization reagents to the volume of a single cell expanded. For an 8-microm erythrocyte, the contents were diluted by a factor of only ca. 1.6. The method was used to determination of amino acids in single erythrocytes. Six amino acids were identified and quantified.     

Optical fiber light-emitting diode-induced fluorescence detection for capillary electrophoresis

A highly sensitive optical fiber light-emitting diode (LED)-induced fluorescence detector for CE has been constructed and evaluated. In this detector, a violet or blue LED was used as the excitation source and an optical fiber with 40 microm OD was used to transmit the excitation light. The upper end of the fiber was inserted into the separation capillary and was situated right at the detection window. Fluorescence emission was collected by a 40 x microscope objective, focused on a spatial filter, and passed through a cutoff filter before reaching the photomultiplier tube. Output signals were recorded and processed with a computer using in-house written software. The present CE/fluorescence detector deploys a simple and inexpensive optical system that requires only an LED as the light source. Its utility was successfully demonstrated by the separation and determination of amino acids (AAs) labeled with naphthalene-2,3-dicarboxaldehyde (NDA) and FITC. Low detection limits were obtained ranging from 17 to 23 nM for NDA-tagged AAs and 8 to 12 nM for FITC-labeled AAs (S/N=3). By virtue of such valuable features as low cost, convenience, and miniaturization, the presented detection scheme was proven to be attractive for sensitive fluorescence detection in CE.     

Analysis of Amino Acids in a Single Human Red Blood Cell by Capillary Zone Electrophoresis with Intracellular NDA—derivatization and Electrochemical Detection

A novel method for determination of amino acids in individual red blood cells has been developed. In this method, the derivatization reagents (NDA and CN^-) are introduced into living cells by electroporation. After completion of derivatization,the amino acids in a single cell is determined by capillary zone electrophoresis with end-column amperometric detection.     

LC Determination of Amino Acids in Rat Plasma with Fluorescence Detection: Application to Exercise Physiology

An LC method for the determination of 20 amino acids (AAs), using 1,2-Benzo-3,4-dihydrocarbazole-9-ethyl chloroformate (BCEOC) as fluorescent labeling reagent, has been validated and applied for the analysis of AAs in rat plasma at three different states concerning exercise physiology. Identification of AA derivatives was carried out by LC-MS with electrospray ion (ESI), and the MS-MS cleavage mode of the representative tyrosine (Tyr) derivative was analyzed. Gradient elution on a Hypersil BDS C₁₈ column gave good separation of the derivatives. Excellent linear responses were observed and good compositional data could be obtained from as little as 50–200 μL of plasma samples. The contents of 20 AAs in rat plasma of three groups (24 rats, group A: quiet state, group B: at exercising exhaust, group C: 12 h after exercising exhaust) exhibited evident difference corresponding to the physiological states. Facile BCEOC derivatization coupled with LC-FLD-ESI-MS analysis allowed the development of a highly sensitive method for the quantitative analysis of trace level of AAs from plasma or other biochemical samples.     

Field-amplified sample injection and in-capillary derivatization for sensitivity improvement of the electrophoretic determination of histamine

The feasibility of the combination of field-amplified sample injection (FASI) and in-capillary derivatization was explored for improving sensitivity of histamine in capillary electrophoresis (CE). Naphthalene-2,3-dicarboxaldehyde (NDA) was used as derivatization reagent. The reagent and sample was introduced by tandem mode. The derivatization was accomplished by at-inlet mode with standing time of 1.5 min. The combination of FASI and in-capillary derivatization was successfully achieved with about 400-fold concentration sensitivity enhancement compared to pre-capillary derivatization at the same set-up. The detection limit of concentration for histamine reached 1.25 x 10(-11) M by CE and fluorescence detection with S/N = 3. Parameters affecting FASI and in-capillary derivatization process including sample matrix, buffer concentration and reagent injection amount, were investigated.     

GC separation of amino acid enantiomers via derivatization with heptafluorobutyl chloroformate and Chirasil‐L‐Val column

Heptafluorobutyl chloroformate (HFBCF), a recently introduced derivatization reagent, was examined in enantioseparation of amino acids (AAs) by GC. Twenty proteinogenic AAs, plus ornithine, cystine and 4‐fluorophenylalanine (internal standard) were treated with the reagent and separation properties of the derivatives were assessed on a Chirasil‐Val capillary column. Nineteen AA enantiomers were efficiently separated in 43 min except proline, arginine and cystine. The HFBCF derivatives of the studied DL ‐AAs show improved separation over other chloroformate‐based derivatives hitherto reported. A combination of the improved and faster separation with a simple derivatization protocol, involving an immediate one‐step reaction–extraction in two‐phase aqueous‐organic medium, and low elution temperatures extend application of HFBCF to chiral AA analysis.     

在线衍生微流控芯片电泳和激光诱导荧光法测定单细胞中谷胱甘肽

微流控分析芯片的网络结构和微米通道尺寸适合于单细胞进样、控制和分离分析^[1~4].在测定细胞内容物时,大多采用柱前细胞内衍生法^[1,2,4],但操作复杂,需多次离心分离,且能透过细胞膜标记胞内组分的荧光试剂较少.     

Determination of histamine and histidine by capillary zone electrophoresis with pre-column naphthalene-2,3-dicarboxaldehyde derivatization and fluorescence detection

A rapid and sensitive method was developed for the simultaneous determination of histamine and histidine by capillary zone electrophoresis with lamp-induced fluorescence detection. A fluoregenic derivatization reagent, naphthalene-2,3-dicarboxaldehyde (NDA) was successfully applied to label the histamine and histidine respectively. The derivatization conditions and separation parameters including pH and concentration of electrolyte and sample injection were optimized in detail. The optimal derivatization reaction was performed with 1.0 mM NDA, 20 mM NaCN, and 20 mM borate buffer, pH 9.1 for 15 min. The separation of NDA-tagged histamine and histidine could be achieved in less than 200 s with 40 mM phosphate buffer (pH 5.8) as the running buffer. The detection limits for histamine and histidine were 5.5 x 10(-9) and 3.8 x 10(-9) M, respectively (S/N = 3). The relative standard derivations for migration time and peak height of derivatives were less than 1.5 and 5.0%, respectively. The method was successfully applied to the analysis of histamine and histidine in the P815 mastocytoma cells and the beer samples.     

In-capillary derivatization and capillary electrophoresis separation of amino acid neurotransmitters from brain microdialysis samples

A new in-capillary derivatization method with naphtalene-2,3-dicarboxyaldehyde (NDA)/CN(-) has been developed for capillary electrophoresis with laser-induced fluorescence detection of brain microdialysate amino acids. Samples are sandwiched between two plugs of reagent mixture at the capillary inlet and subsequently separated. Highest derivatization yields are obtained by using a reagent to sample plug length ratio equal to 4, performing a first electrophoretic mixing followed by a zero potential amplification step before applying the separation voltage and using a NaCN to NDA concentration ratio equal to 1. This new single-step methodology allows the analysis of amino acid neurotransmitters in rat brain microdialysis samples.     

微流控芯片NDA在线衍生测定单细胞中谷胱甘肽

单细胞分析对研究细胞内信号传递和重大疾病的早期诊断等具有重要意义,荧光标记是检测细胞内物质的常用技术,为防止衍生时的过度稀释,大多采用柱前细胞内衍生法,衍生后再用微流控芯片分析,此法操作复杂,需多次离心分离,且能透过细胞膜标记胞内组分的荧光试剂较少。     

Improved determination of the bisphosphonate alendronate in human plasma and urine by automated precolumn derivatization and high-performance liquid chromatography with fluorescence and electrochemical detection.

An improved method for the determination of 4-amino-1-hydroxybutane-1,1-bisphosphonic acid (alendronate) in human urine and an assay in human plasma are described. The methods are based on co-precipitation of the bisphosphonate with calcium phosphates, automated pre-column derivatization of the primary amino group of the bisphosphonic acid with 2,3-naphthalene dicarboxyaldehyde (NDA)-N-acetyl-D-penicillamine (NAP) or cyanide (CN-) reagents, and high-performance liquid chromatography (HPLC) with electrochemical (ED) or fluorescence detection (FD). The feasibility of ED of the NDA-CN- derivative of aldendronate has been demonstrated, and a HPLC-ED assay in human urine has been validated in the concentration range 2.5-50.0 ng/ml. In order to eliminate the cyanide ion from the assay procedure, several other nucleophiles in the NDA derivatization reaction were evaluated. An NDA-NAP reagent was found to produce highly fluorescent derivatives of alendronate. The assay in urine based on NDA-NAP derivatization and HPLC-FD has been developed and fully validated in the concentration range 1-25 ng/ml. Based on the same NDA-NAP derivatization, an assay in human plasma with a limit of quantification of 5 ng/ml has also been developed. Both HPLC-FD assays were utilized to support various human pharmacokinetic studies with alendronate.     

The use of naphthalene-2,3-dicarboxaldehyde for the analysis of primary amines using high-performance liquid chromatography and capillary electrophoresis

This paper reviews analytical methods, instrumental developments and applications for derivatization of primary amines with naphthalene-2,3-dicarboxaldehyde using fluorescence and chemiluminescence detection with capillary electrophoresis (CE) and high performance liquid chromatography (HPLC). The use of lasers as well as lamps as the excitation source for fluorescence detection is discussed. The detection limit observed with naphthalene-2,3-dicarboxaldehyde derivatization is often lower and better than those obtained with other analytical separations and other fluorescent dyes. In addition, this paper describes the crucial points that influence the stability of NDA primary amine derivatives, and summarize the separation, derivatization and migration conditions of the different techniques, with their advantages and drawbacks.     

An evaluation of GC-MS and HPLC-FD methods for analysis of protein binders in paintings

Two chromatographic methods have been compared for analysis of protein-binding media used in paintings, namely, HPLC with fluorescence detection and GC-MS. The proteins were hydrolyzed to the corresponding amino acids (AAs) by gaseous HCl and the AAs were derivatized with methyl chloroformate, followed by GC-MS or by HPLC after derivatization with the AccQ fluorescence reagent. The hydrolysis, derivatization reactions and the chromatographic procedures have been optimized and applied to standard binding media, model and real samples of paintings. The methods have been compared and critically evaluated.     

CE with sequential light-emitting diode-induced fluorescence and electro-chemiluminescence detections for the determination of amino acids and alkaloids

This paper describes the determination of alkaloids and amino acids (AAs) using CE in conjunction with sequential light-emitting diode-induced fluorescence (LEDIF) and electrochemiluminescence (ECL) detections. In the CE-LEDIF-ECL system, the ECL detector was located in the outlet of the capillary, while the LEDIF detector was positioned 12 cm from the outlet. Naphthalene-2,3-dicarboxaldehyde (NDA) was used to form fluorescent AA-NDA derivatives from AAs possessing primary amino groups, while Ru(bpy)(3) (2+) was used to obtain ECL signals for analytes having secondary and tertiary amino groups. In the presence of poly(ethylene oxide), we accomplished the CE-LEDIF-ECL separation of a mixture of 12 AA-NDA derivatives, anabasine, nicotine, and proline within 11 min. This low-cost CE-LEDIF-ECL system allows the analysis of these AA-NDA derivatives and alkaloids at concentrations in the ranges of 49 nM-0.2 microM and 0.66-4.7 microM, respectively. We applied our CE-LEDIF-ECL system to the analysis of a urine sample and also to tobacco extracts. We obtained good qualitative and quantitative results when using this method with these analytes: the RSDs were below 3.0 and 2.8%, respectively. This CE-LEDIF-ECL system provides the advantages of high efficiency, speed, and sensitivity for the analysis of analytes possessing amino groups.