Amino acids analysis using a monolithic silica column after derivatization with 4-fluoro-7-nitro-2,1,3-benzoxadiazole (NBD-F)

A fast HPLC method using a monolithic silica column was developed for the measurement of amino acids. The amino acids were pre-column derivatized with 4-fluoro-7-nitro-2,1,3-benzoxadiazole (NBD-F) and separated on a monolithic silica column (MonoClad C18-HS, 250 mm × 3 mm I.D.). The separation of 19 NBD-amino acids was achieved within 18 min, which was only one-fifth of the time taken by the methods using a conventional particle-packed column, with the gradient elution of a mobile phase at the flow rate of 1.4 mL/min. The sensitivity was good with a limit of detection for the individual amino acids ranging from 2.94 to 53.4 fmol. The calibration curves for all the amino acids were found to be linear in the range of 200 fmol to 20 pmol with correlation coefficients of 0.997 or better. The analytical method was successfully applied to determine the amino acids in a mouse plasma sample.     

Matrix-assisted laser desorption/ionization time-of-flight mass spectrometry-based amino acid analysis

Amino acid analysis has been an integral part of analytical biochemistry for more than 50 years. However, its experimental design, which includes derivatization of amino acids followed by some kind of chromatographic separation, has not changed over the years. We have developed a matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF)-based method for the quantitative analysis of amino acids. This method does not require any amino acid modification, derivatization, or chromatographic separation. The data acquisition time is decreased to several seconds for a single sample. No significant ion suppression effects were observed with the developed sample deposition technique, and the method was found to be reproducible. Linear responses between the amino acid concentration and the peak intensities ratio of corresponding amino acid to internal standard were observed for all amino acids analyzed in the range of concentrations from 20 to 300 microM, and correlation coefficients were between 0.983 (for arginine) and 0.999 (for phenylalanine). Limits of quantitation were between 0.03 microM (for arginine) and 3.7 microM (for histidine and homocysteine). This method was applicable to the mixtures of free amino acids as well as to HCl hydrolysates of proteins. Furthermore, we have shown that this method can be applied to other biologically important low-molecular weight compounds such as glucose.     

Problems in the search for amino acids in lunar fines

In the search for amino acids in lunar fines, a major problem is the prevention of contamination from terrestrial sources, and the recognition of terrestrial contamination when it has occurred. Synthesis of amino acids conceivably could take place in the lunar module rocket exhaust, a possibility that has not been adequately ruled out. Amino acids could be shed from the astronauts suits, a possibility which has not been studied at all. Amino acids could also be introduced, at many stages of terrestrial manipulation, and during the analytical procedures employed. Hand contamination has qualitative and quantitative features that are characteristic and can be assessed. Precautions for elimination of hand and microbial contamination from glassware, reagents and water are proposed.A second major problem is the efficiency of recovery of amino acids added to lunar material, which is then subject to the complete analytical scheme. This necessitates the availability of lunar material to develop proper procedures.Besides the amino acids present in excess of blank values, it is necessary for the correct interpretation of any positive findings to know whether the amino acids are free or bound and optically inactive or active.The ion exchange chromatography and gas chromatography-mass spectrometry are procedures that complement each other. Both should be applied not only to the same sample but to the same preparations. To pit one method against the other is to risk losing the best analytical data.     

A simple method to detect contaminating peptides and amino acids in large-scale ganglioside preparations

A reverse-phase liquid chromatography method was developed to analyse the presence of contaminating peptides and amino acids in large-scale monosialoganglioside preparations. Samples were hydrolysed under controlled conditions and derivatized with phenylisothiocyanate. PTC-amino acids were then separated and identified by HPLC. The sensitivity of the method allowed detection of a least 50 pmoles of amino acid per mg of ganglioside with excellent reproducibility and little or no interference of by-products derived from hydrolysis of the glycosphingolipid. The response was consistently linear for each amino acid within the examined analytical range. The ease and speed of performance make this method a useful tool for rapidly monitoring large-scale extraction and purification processes of biologicals obtained from natural sources.     

Automated rapid method for microbioassay of amino acids

An automated rapid method for microbioassay of amino acids was investigated by taking advantages of the rapid manual method. The Pye Unicam automatic analytical apparatus was adopted for the automation of assay culture in the rapid microbioassay. The advantages of the present method are that amino acids can be automatically determined on 3.5-hr assay culture, and that an aseptic technique can be omitted. These advantages were confirmed in several amino acid assays. The assay values were the same as those obtained by the conventional method. Application of the automated rapid method to the serine assay showed a linear standard curve without a lag section, leading to more expanded assay range and smaller drift in values.     

Organics in chimneys and water samples from deep-sea hydrothermal systems: implications for sub-vent biosphere.

Searching for life in extreme terrestrial environments can be a model of that for extraterrestrial life. Submarine hydrothermal system is one of promising sites for the frontier of life on the earth. Here seawater and vent chimnies were collected from deep-sea hydrothermal vents at Suiyo Seamount, Izu-bonin arc, Pacific Ocean as a part of Archaean Park Project. Pure seawater sample of 300 degrees C (purity>97%) could be collected. Dissolved and total hydrolyzable amino acids were determined by ion-exchange HPLC, and their enantiomeric ratio was measured by reversed-phase HPLC for the first time. Glycine and serine were two most abundant amino acids, followed by other proteinous amino acids such as alanine, glutamic acid and aspartic acid. Non-proteinous amino acids were detected as minor constituents. Most of the amino acids detected were of the L-form. Thus amino acids of abiotic origin were quite minor, and most of the amino acids detected were formed biologically. These results, together with analytical results of the vent chimney samples, suggest that there is active microbial activities near the hydrothermal systems.     

Amino acid analysis with o-phthalaldehyde detection: effects of reaction temperature and thiol on fluorescence yields.

Chromatographic separation of amino acids with fluorometric detection of the o-phthalaldehyde-thiol reaction product offers an analytical system of high sensitivity for most amino acids. The fluorescence yield for amino acids having a fully substituted carbon atom in the α-position with respect to the amino group can be substantially improved by increasing the temperature of the reaction with o-phthalaldehyde-thiol and by substituting either ethanethiol or methanethiol for the more commonly used β-mercaptoethanol. The analytical sensitivity for these α-branched amino acids is thus brought into line with that for the other primary amino acids. A comparison of chromatograms obtained at reaction temperatures of 25 and 100°C allows recognition of amino acids of this type in complex mixtures by the substantial increase in fluorescence yield at 100°C.     

Direct extract derivatization for determination of amino acids in human urine by gas chromatography and mass spectrometry

The purpose of this study was to develop a simple and accurate analytical method to determine amino acids in urine samples. The developed method involves the employment of an extract derivatization technique together with gas chromatography-mass spectrometry (GC-MS). Urine samples (300 microl) and an internal standard (10 microl) were placed in a screw tube. Ethylchloroformate (50 microl), methanol-pyridine (500 microl, 4:1, v/v) and chloroform (1 ml) were added to the tube. The organic layer (1 microl) was injected to a GC-MS system. In this proposed method, the amino acids in urine were derivatized during an extraction, and the analytes were then injected to GC-MS without an evaporation of the organic solvent extracted. Sample preparation was only required for ca. 5 min. The 15 amino acids (alanine, aspartic acid, cysteine, glutamic acid, glycine, histidine, isoleucine, leucine, lysine, methionine, phenylalanine, proline, tyrosine, tryptophan, valine) quantitatively determined in this proposed method. However, threonine, serine, asparagine, glutamine, arginine were not derivatized using any tested derivatizing reagent. The calibration curves showed linearity in the range of 1.0-300 microg/ml for each amino acid in urine. The correlation coefficients of the calibration curves of the tested amino acids were from 0.966 to 0.998. The limit of detection in urine was 0.5 microg/ml except for aspartic acid. This proposed method demonstrated substantial accuracy for detection of normal levels. This proposed method was limited for the determination of 15 amino acids in urine. However, the sample preparation was simple and rapid, and this method is suitable for a routine analysis of amino acids in urine.     

Liquid chromatographic method for the quantitative determination of Nepsilon-carboxymethyllysine in human plasma proteins

The modification of the lysine moieties of proteins to Nepsilon-carboxymethyllysine (CML) is supposed to play a major role in the development of long-term complications in patients with diabetes mellitus. This paper presents an analytical method for the quantitative determination of CML in plasma proteins, which could be used for studying the development of diabetic complications. The method is based on isolating proteins from plasma by precipitation with trichloroacetic acid and hydrolysing these under acidic conditions (6M hydrochloric acid at 110 degrees C for 20 h) to the individual amino acids. After hydrolysis, CML is derivatised along with the other amino acids to 9-fluorenylmethoxycarbonyl (FMOC) derivatives, which are subsequently separated by reversed-phase column liquid chromatography using a 150 mm x 4.6 mm C8 column and a mobile phase of 25 mM potassium phosphate buffer (pH 2.0) and acetonitrile (80:20 (v/v)) and detected using fluorescence detection (excitation at 260 nm and emission at 310 nm). Quantification of the protein-bound CML content of a plasma sample is achieved using standard addition. The impact of several aspects of the sample preparation and chromatography on method performance is discussed. Method evaluation results are reported and show that this method is capable of determining CML with good accuracy and precision (below 10%) in the relevant concentration range (1-10 microg/ml), with a limit of detection of 0.2 microg/ml.     

Routine amino acid capillary column chromatography of microquantities in the picomole range--procedures and modifications of a commercial analyzer

A commercial micro amino acid analyzer using capillary columns (internal diameter 0.7 mm) had to be modified greatly in order to get satisfactory separation and quantitative analysis on the microscale of free amino acids in biological fluids, tissue extracts, and hydrolysates. Furthermore, the usual analytical conditions were changed (i.e., lowering of the buffer pH) and a procedure and apparatus for sample deproteinization is described which allows simple handling of volumes in the range from 20 to 100 μl. The modifications described guarantee better and more reproducible analyses than reported so far. A design of a new “analytical unit” for capillary column chromatography is proposed.     

Quantification of 22 plasma amino acids combining derivatization and ion-pair LC-MS/MS

Time efficient and comprehensive quantification of amino acids continues to be a challenge. We developed a sensitive and precise method for quantitative analysis of amino acids from very small plasma and serum volumes. Ion-pair chromatography of amino acid butyl esters proved to provide an optimal combination of selectivity, sensitivity and robustness. 10 μL of plasma or serum are added to precipitation reagent containing stable isotope standards. After protein precipitation, the supernatants is dried and incubated with 3N butanolic HCl for improving chromatographic separation and ionization efficiency. Amino acid butyl esters are separated using ion-pair (heptafluorobutyric acid) reversed-phase chromatography coupled to triple quadrupole mass spectrometry. The established method enables quantitative analysis of 22 amino acids, all 20 proteinogenic amino acids, ornithine and citrulline. Cysteine is measured as cystine. The combination of precipitation, derivatization and chromatographic separation effectively avoids ion suppression and coelution. Simultaneous with quantification, analyte identity is verified in each sample using qualifier ions. The micro-method is very sensitive and accurate. The intra-assay precision for the analysis of plasma was 2.6-10.1%. Absolute accuracy as determined by comparison of external reference samples was 82-117.7%. Excellent linearity of detection response was demonstrated for all compounds in the range representative for clinical samples from infants and adults. Lower limits of quantification were in the range of 1 μmol/L for all analytes. In conclusion, the method is ideally suited for cost-effective high-throughput analysis of large numbers of samples in clinical studies and metabolomics research.     

An ion-exchange chromatography procedure for the isolation and concentration of basic amino acids and polyamines from complex biological samples prior to high-performance liquid chromatography.

The original objective of this study was to develop a selective and sensitive method for the analysis and quantification of basic amino acids from biological samples via reversed-phase high-performance liquid chromatography. Using various previously described techniques for the separation of amino acids, we were unsuccessful in measuring levels of histidine, arginine, ornithine, and lysine in biological samples due to the presence of interfering compounds. A "cleanup" procedure for the isolation of the basic amino acids using a weakly acidic cation exchange resin, Biorex-70 (Bio-Rad), is described in detail. Upon separation from the bulk of the neutral and acidic amino acids, the basic amino acids were subjected to precolumn fluorescence derivatization using 9-fluorenylmethyl chloroformate (FMOC) and the fluorescent derivatives were separated by RP-HPLC. The advantages of this method over previously described amino acid analysis techniques are (i) isolation and stable recovery (greater than 95%) of the desired basic amino acids, (ii) sensitivity of detection (low pmol range), (iii) complete resolution of derivatized amino acids via HPLC, (iv) limited amount of sample required for analysis, and (v) samples readily concentrated by lyophilization or rotoevaporating. This ion-exchange cleanup procedure was also adapted for the analysis of polyamines in concentrated culture media samples and proved additionally advantageous by eliminating the use of costly C-18 extraction columns required by previously described techniques.     

Micro sequential injection system as the interfacing device for process analytical applications

It is an important and desirable capability to be able to control the quality and quantity of biological product by maintaining and adjusting bioreactor performance throughout its production duration. Amino acids are the building blocks of proteins. Scientists will need to ensure sufficient supply of amino acids as the substrates in the bioreactors as well as to control the excess level of undesirable free amino acid byproducts to maintain an optimum growth environment for cell culture. We have developed a compact and robust sample preparation platform capable of interfacing with analytical instruments to achieve bioreactor amino acids monitoring. We demonstrated the feasibility of this concept by incorporating an automatic amino acid sample preparation protocol to a micro sequential injection (μSI) system connected to an ultra‐performance liquid chromatography system for real‐time, at‐line amino acid separation, and quantitation. The μSI system was configured into a “platform‐like” sample preparation system that is able to accommodate future wet chemistry‐type sample preparations. Its real‐time amino acid results can be readily available to bioprocess scientists for quick decision making and design of their next experiment. Potential automatic feedback control mechanisms can be established through trigger events based on predetermined analytical signal thresholds so the system can communicate with facility infrastructure to control bioreactors in near real‐time fashion. The proposed μSI system described in this paper can be widely used as an automatic sample preparation system connected to the front‐end of analytical instruments to enable process analytical technology applications. © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 31:607–613, 2015     

Fast mass spectrometry-based enantiomeric excess determination of proteinogenic amino acids

A rapid determination of the enantiomeric excess of proteinogenic amino acids is of great importance in various fields of chemical and biologic research and industries. Owing to their different biologic effects, enantiomers are interesting research subjects in drug development for the design of new and more efficient pharmaceuticals. Usually, the enantiomeric composition of amino acids is determined by conventional analytical methods such as liquid or gas chromatography or capillary electrophoresis. These analytical techniques do not fulfill the requirements of high-throughput screening due to their relative long analysis times. The method presented allows a fast analysis of chiral amino acids without previous time consuming chromatographic separation. The analytical measurements base on parallel kinetic resolution with pseudoenantiomeric mass tagged auxiliaries and were carried out by mass spectrometry with electrospray ionization. All 19 chiral proteinogenic amino acids were tested and Pro, Ser, Trp, His, and Glu were selected as model substrates for verification measurements. The enantiomeric excesses of amino acids with non-polar and aliphatic side chains as well as Trp and Phe (aromatic side chains) were determined with maximum deviations of the expected value less than or equal to 10ee%. Ser, Cys, His, Glu, and Asp were determined with deviations lower or equal to 14ee% and the enantiomeric excess of Tyr were calculated with 17ee% deviation. The total screening process is fully automated from the sample pretreatment to the data processing. The method presented enables fast measurement times about 1.38 min per sample and is applicable in the scope of high-throughput screenings.     

Near infrared spectroscopy, cluster and multivariate analysis hyphenated to thin layer chromatography for the analysis of amino acids

Summary. A method based on near-infrared spectroscopy (NIRS) was developed for the rapid and non-destructive determination and quantification of solid and dissolved amino acids. The statistical results obtained after optimisation of measurement conditions were evaluated on the basis of statistical parameters, Q-value (quality of calibrations), R², standard error of estimation (SEE), standard error of prediction (SEP), BIAS applying cluster and different multivariate analytical procedures. Experimental optimisation comprised the selection of the highest suitable optical thin-layer (0.5, 1.0, 1.5, 2.0, 2.5, 3.0 mm), sample temperature (10–30 °C), measurement option (light fibre, 0.5 mm optical thin-layer; boiling point tube; different types of cuvettes) and sample concentration in the range between 100 and 500 ppm. Applying the optimised conditions and a 115-QS Suprasil^? cuvette (V = 400 μl), the established qualitative model enabled to distinguish between different dissolved amino acids with a Q-value of 0.9555. Solid amino acids were investigated in the transflectance mode, allowing to differentiate them with a Q-value of 0.9155. For the qualitative and quantitative analysis of amino acids in complex matrices NIRS was established as a detection system directly onto the plate after prior separation on cellulose based thin-layer chromatography (TLC) sheets employing n-butanol, acetic acid and distilled water at a ratio of 8:4:2 (v/v/v) as an optimised mobile phase. Due to the prior separation step, the established calibration curve was found to be more stable than the one calculated from the dissolved amino acids. The found lower limit of detection was 0.01 mg/ml. Finally, this optimised TLC-NIRS method was successfully applied for the qualitative and quantitative analysis of L-lysine in apple juice. NIRS is shown not only to offer a fast, non-destructive detection tool but also to provide an easy-to-use alternative to more complicated detection methods such as mass spectrometry (MS) for qualitative and quantitative TLC analysis of amino acids in crude samples.     

Improved method for the measurement of large neutral amino acids in biological matrices

A high-performance liquid chromatographic method for measuring neutral amino acids in rat sera, brain tissues, and perfusates was developed by using o-phthalaldehyde sulfite as a pre-column derivatization reagent. With the present method, it was possible to separate the neutral amino acids within a single run in 25 min, while the acidic amino acids were eluted near or at the solvent front. The recovery was above 88.8% with a relative standard deviation (RSD) below 4.2%. The within- and between-day assay reproducibility for the determination of rat serum amino acids showed RSDs below 1.35 and 7.61%, respectively. In the present study, the neutral amino acids were assayed with high sensitivity, accuracy and good reproducibility in a relatively short time and on a small sample size.     

A kinetic spectrophotometric method for simultaneous determination of glycine and lysine by artificial neural networks

A spectrophotometric method for simultaneous analysis of glycine and lysine is proposed by application of neural networks on the spectral kinetic data. The method is based on the reaction of glycine and lysine with 1,2-naphthoquinone-4-sulfonate (NQS) in slightly basic medium. On the basis of the difference in the rate between the two reactions, these two amino acids can be determined simultaneously in binary mixtures. Feed-forward neural networks have been trained to quantify considered amino acids in mixtures under optimum conditions. In this way, a one-layer network was trained. Sigmoidal and linear transfer functions were used in the hidden and output layers, respectively. Linear calibration graphs were obtained in the concentration range of 1 to 25microgml(-1) for glycine and 1 to 19microgml(-1) for lysine. The analytical performance of this method was characterized by the relative standard error. The proposed method was applied to the determination of considered amino acids in synthetic samples.     

High-sensitivity amino acid analysis by derivatization with O-phthalaldehyde and 9-fluorenylmethyl chloroformate using fluorescence detection: applications in protein structure determination

An amino acid analysis method using a commercially available analyzer that accurately quantitates protein-derived amino acids in the 10-100 pmol range is described. The method utilizes the robotic capability of the analyzer's autosampler to perform precolumn derivatization of both primary and secondary amino acids with o-phthalaldehyde and 9-fluorenylmethyl chloroformate, respectively. The derivatized amino acids are then separated on a C-18 reverse-phase amino acid column and quantitated in a single run by fluorescence detection. The characterization of beta-lactoglobulin and two tryptic peptides from the bacterial enzyme diaminopimelic acid epimerase is used to demonstrate the sensitivity and utility of this method.     

Developmental responses of two substrains of in vitro fertilized C57BL/6J mouse embryos to oxygen and amino acids.

The developmental response of in vitro fertilized embryos to oxygen and amino acids were compared between in-house bred C57BL/6JNrs (Nrs) and commercially available C57BL/6JSlc (Slc) mice. Under 20% oxygen, the percentage of embryos that developed to blastocysts and expanded blastocysts, and nuclear numbers were lower in Slc embryos than in Nrs embryos. Moreover, the nuclear number did not increase in Slc embryos during 72-96 h culture. Effects of amino acids were beneficial on development of Slc embryos under 20% oxygen, but inhibitory on blastocoel formation at 78 h under 5% oxygen. On the other hand effects of amino acids on Nrs embryos were observed in nuclear number at 72 and 78 h culture under 5% oxygen. Because the present study showed differences in sensitivity to culture conditions between the C57BL/6J substrains, care must be taken in embryo manipulation of this inbred strain in studies of embryo development or other studies.     

Second-tier test for quantification of underivatized amino acids in dry blood spot for metabolic diseases in newborn screening

The quantitative analysis of amino acids (AAs) in single dry blood spot (DBS) samples is an important issue for metabolic diseases as a second-tier test in newborn screening. An analytical method for quantifying underivatized AAs in DBS was developed by using liquid chromatography coupled with tandem mass spectrometry (LC–MS/MS). The sample preparation in this method is simple and ion-pairing agent is not used in the mobile phase that could avoid ion suppression, which happens in mass spectrometry and avoids damage to the column. Through chromatographic separation, some isomeric compounds could be identified and quantified, which cannot be solved through only appropriate multiple reactions monitoring transitions by MS/MS. The concentrations of the different AAs were determined using non-deuterated internal standard. All calibration curves showed excellent linearity within test ranges. For most of the amino acids the accuracy of extraction recovery was between 85.3 and 115 %, and the precision of relative standard deviation was <7.0 %. The 35 AAs could be identified in DBS specimens by the developed LC–MS/MS method in 17–19 min, and eventually 24 AAs in DBS were quantified. The results of the present study prove that this method as a second-tier test in newborn screening for metabolic diseases could be performed by the quantification of free AAs in DBS using the LC–MS/MS method. The assay has advantages of high sensitive, specific, and inexpensive merits because non-deuterated internal standard and acetic acid instead of ion-pairing agent in mobile phase are used in this protocol.