Electromigration methods for amino acids, biogenic amines and aromatic amines

Methods of electromigration in laboratory apparatus of small-bore size have recently undergone development at a remarkably rapid pace, leading to a variety of new analytical techniques. One such technique is called “capillary electrophoresis” (CE), which is further classified on the basis of electromigration mode, viz., “capillary zone electrophoresis” (CZE), which, in turn, has several variations. This review aims to give a short overview of the various electromigration methods for amino compounds by using CE. Firstly, this review briefly summarizes the detection methods employed for detection of monoamines and polyamines by CE for both native and derivative forms. Next, current CE methods are described, and their applications to detection of amino acids, biogenic amines, aromatic amines, including heteroaromatic amines and their enantiomers, are introduced from representative papers. Finally, new methods for single-cell analysis and microchip CE techniques are focused on.     

An ultramicro method for quantitation of amino acids in biological fluids

A modification of the commercially available SZ-14 reorienting density gradient rotor is described whereby continuous sample flow with density gradient isopycnic banding may be utilized. This permits the fractionation of large volumes of dilute homogenates with excellent recovery and purity. The technique is demonstrated for the isolation of nuclei and particles of mitochondrial size.     

Automated GC-MS analysis of free amino acids in biological fluids

A gas chromatography-mass spectrometry (GC-MS) method was developed for the quantitative analysis of free amino acids as their propyl chloroformate derivatives in biological fluids. Derivatization with propyl chloroformate is carried out directly in the biological samples without prior protein precipitation or solid-phase extraction of the amino acids, thereby allowing automation of the entire procedure, including addition of reagents, extraction and injection into the GC-MS. The total analysis time was 30 min and 30 amino acids could be reliably quantified using 19 stable isotope-labeled amino acids as internal standards. Limits of detection (LOD) and lower limits of quantification (LLOQ) were in the range of 0.03-12 microM and 0.3-30 microM, respectively. The method was validated using a certified amino acid standard and reference plasma, and its applicability to different biological fluids was shown. Intra-day precision for the analysis of human urine, blood plasma, and cell culture medium was 2.0-8.8%, 0.9-8.3%, and 2.0-14.3%, respectively, while the inter-day precision for human urine was 1.5-14.1%.     

Ion conductors derived from biogenic amines,bile acids,and amino acids

A family of conjugates has been synthesized from spermine, putrescine, lysine, gamma-aminobutyric acid, sarcosine, cholic acid, glycocholic acid, 3alpha,7alpha-dihydroxycholic acid, and 3alpha,12alpha-dihydroxycholic acid, based on a design principle previously reported (Bandyopadhyay, P., Janout, V., Zhang, L., Regen, S. L. (2001) J. Am. Chem. Soc. 123, 7691). Each of these conjugates was found to exhibit significant activity in promoting the transport of Na(+) across liposomal membranes derived from 1,2-dimyristoleoyl-sn-glycero-3-phosphocholine, and also from 1,2-dipalmitoleoyl-sn-glycero-3-phosphocholine. In all cases, plots of pseudo first-order rate constants, k(obsd) vs (mol % of ion conductor)(2) were found to be linear, indicating that transport-active dimers are involved and that only a small fraction of the conjugates are in an aggregated form. An operational comparison that has been made within this series of conjugates indicates that Na(+) transport activity and membrane selectivity have a moderate dependency on the composition and the structure of the ion conductor.     

Chiral separation of amino acids in biological fluids by micellar electrokinetic chromatography with laser-induced fluorescence detection

A method is presented for the chiral analysis of amino acids in biological fluids using micellar electrokinetic chromatography (MEKC) and laser-induced fluorescence (LIF). The amino acids are derivatized with the chiral reagent (+/−)-1-(9-anthryl)-2-propyl chloroformate (APOC) and separated using a mixed micellar separation system. No tedious pre-purification of samples is required. The excellent separation efficiency and good detection capabilities of the MEKC-LIF system are exemplified in the analysis of urine and cerebrospinal fluid. This is the first time MEKC has been reported for chiral analysis of amino acids in biological fluids. The amino acids -alanine, -glutamine, and -aspartic acid have been observed in cerebrospinal fluid, and -alanine and -glutamic acid in urine. To the best of our knowledge no measurements of either -alanine in cerebrospinal fluid or -glutamic acid in urine have been presented in the literature before.     

Femtomole level of analysis of biogenic amines and amino acids using functional group mass spectrometry

A general method for the determination of compounds possessing either the primary amine structure, R-CH₂-NH₂ (I), or the α-amino acid structure, RCHNH₂COOH (II), has been devised using gas chromatography and mass spectrometry. Trimethylsilyl derivatives of the biogenic amines (phenylethylamines, indoleethylamines, or Ω-amino acids) produce an intense ion at $\text{m}\text{e}$ 174 upon fragmentation; TMS derivatives of α-amino acids produce an ion at $\text{m}\text{e}$ 218. For maximum sensitivity, chromatograms were obtained with the mass spectrometer tuned to detect a single ion fragment characteristic of a group of structurally related compounds (i.e., functional group GC-MS). At $\text{m}\text{e}$ 174 up to 14 compounds of Type I, including glycine, γ-aminobutyric acid, dopamine, and 5-hydroxytryptamine, could be determined in a single analysis. Detection limits range from 10–100 femtomoles (10^?15 moles). At $\text{m}\text{e}$ 218, eight compounds of Type II, including isoleucine, phenylalanine, tyrosine, and DOPA could be determined. This technique has been applied to the assay of these compounds in extracts containing 0.1 mg mouse brain or abdominal ganglia of the marine molluse, Aplysia californica.     

Recommended method for the analysis of amino acids in biological materials

Fifty-five ninhydrin-positive compounds in physiological fluids were determined with a Hitachi Model KLA-5 amino acid analyzer by a two-column chromatographic procedure. Both columns were packed with Hitachi Custom 2618 ion-exchange resin. The total analysis time was 9.5 h.In this procedure, particularly glucosamine, mannosamine and galactosamine were separated completely from normal “protein” amino acids, and N^G-monomethylarginine, N^G,N^G-dimethylarginine and N^G,N′^G-dimethylarginine, which were present in the myelin basic protein of several species and excreted in human urine, were separated from other basic amino acids. The method is useful for various applications with biological materials.     

Determination of amino acids in human biological fluids by high-performance liquid chromatography: critical review

The quantitation and qualification of amino acids are most commonly used in clinical and epidemiological studies, and provide an excellent way of monitoring compounds in human fluids which have not been monitored previously, to prevent some diseases. Because of this, it is not surprising that scientific interest in evaluating these compounds has resurfaced in recent years and has precipitated the development of a multitude of new analytical techniques. This review considers recent developments in HPLC analytics on the basis of publications from the last few years. It helps to update and systematize knowledge in this area. Particular attention is paid to the progress of analytical methods, pointing out the advantages and drawbacks of the various techniques used for the preparation, separation and determination of amino acids. Depending on the type of sample, the preparation conditions for HPLC analysis change. For this reason, the review has focused on three types of samples, namely urine, blood and cerebrospinal fluid. Despite time-consuming sample preparation before HPLC analysis, an additional derivatization technique should be used, depending on the detection technique used. There are proposals for columns that are specially modified for amino acid separation without derivatization, but the limit of detection of the substance is less beneficial. In view of the fact that amino acid analyses have been performed for years and new solutions may generate increased costs, it may turn out that older proposals are much more advantageous.

     

A method for determining amino acid concentrations and specific activities of amino acids and some other compounds in biological fluids

A method is described for obtaining plasma ultrafiltrates from which the concentrations of all amino acids, including tryptophan and ammonia, are obtained. A split-stream methodology is described for obtaining, in addition to the concentrations, the radioactivities of amino acids, glucose, and plasma water.     

Improved multiplex-PCR method for the simultaneous detection of food bacteria producing biogenic amines

This study describes a simple and rapid multiplex-PCR method to determine the ability to produce histamine, tyramine and putrescine by bacteria. The assay is an improved method based on an assay designed for lactic acid bacteria. This improved method includes a pair of primers based on sequences from histidine decarboxylases from Gram-negative bacteria. Under the optimised conditions, the assay yielded a 367-bp DNA fragment from histidine decarboxylases of Gram-positive bacteria, 534-bp fragment from histidine decarboxylases of Gram-negative bacteria, 924-bp from bacterial tyrosine decarboxylases, and 1446-bp fragment from bacterial ornithine decarboxylases. The method was successfully applied to several biogenic amine-producing bacterial strains, even when DNAs of several target organisms were included in the same reaction. This simple method could be easily incorporated in food control laboratories to detect potentially biogenic amine-producing bacteria in foods.     

A sensitive, fast, durable, highly selective method for the determination of amino acids and biogenic amines in the cerebrospinal fluid and other body fluids and tissues

A sensitive, fast, durable HPLC method with high resolution for the determination of amino acids and some biogenic amines is described. It allows the simultaneous determination of more than 40 substances in the cerebrospinal fluid or other body fluids or tissues. The method allows to measure both, the free and the conjugated amino acids. It detects 5 X 10(-13) g of most amino acids and measures the relevant substances in their physiological concentrations with less than 0.1 ml cerebrospinal fluid. The precision is 1-2%.     

A simple method for concentration of biogenic amines and their metabolites from biological samples for analysis by HPLC-EC

This report describes a new rapid, convenient and inexpensive method of concentrating biogenic amines and their metabolites from biological samples for analysis by HPLC-EC. Recovery of standard monoamines and metabolites from artificial cerebrospinal fluid (CSF) solution following lyophilization in the presence of glutathione (1.2 mg/ml, final concentration) and EGTA (1.8 mg/ml, final concentration) was greater than 89%; the coefficient of variation was 0.6-3.7%, depending on the specific amine or metabolite concentrated. Lyophilization as a one step procedure is suitable for concentrating biogenic amines and metabolites from biological fluids such as CSF that contain low concentrations of protein and other interfering substances. When concentrating compounds from plasma, which contains large quantities of protein and other electrochemically active materials, it is necessary to add an extraction step, such as alumina extraction. By substituting 0.05 M HCl for the conventional eluent, 0.1 M HClO4, we were able to increase recoveries of catecholamines from plasma by approximately 20%. Recovery of endogenous catecholamines from plasma following the combined alumina extraction - lyophilization procedure was 81 +/- 1%.     

Simple method for analysis of diquat in biological fluids and tissues by high-performance liquid chromatography

A simple HPLC method has been described to quantify diquat in biological fluids and tissues. This method permits separation and quantification of diquat from blood, bile, urine, liver and kidney. It does not require special pretreatment of the samples prior to analysis, nor a specially prepared analytical column. Various concentrations of diquat were added (10–300 nmol/ml or g) to fluids or tissues. Analysis of blank samples revealed no substrates that interfere with diquat elution. Excellent recovery (95–105%) was obtained. Diquat (120 μmol/kg, i.v.) was injected to rats and quantified in bile, blood and liver. Concentration of diquat was higher in blood and bile than liver. Therefore, this method is applicable for quantification of diquat in toxicological samples, and may be used to determine structurally similar compounds such as paraquat.     

Preparation of biological fluids for simultaneous analysis of prostaglandin cyclo-oxygenase synthesized compounds by gas chromatography with electron capture detection

A method for isolating climax products of the arachidonic acid cascade from biological fluids is described which allows simultaneous measurement of PGs (PGE2, PGD2, 6-keto-PGF1 alpha, TXB2, 6-keto-PGE1, 6, 15-diketo-13,14-dihydro-PGF1 alpha) by electron capture detection of pentafluorobenzyloxime methyl ester trimethylsilyl (TMS) ether derivatives. PGs are adsorbed onto Amberlite XAD-2 from acidified solution and nonadhering substances removed by sequential administration of water, then petroleum ether. PGs are extracted into methanol. Following evaporation and reconstitution in water, the PGs are extracted into ethyl acetate at pH 3 and the ethyl acetate extracts are purified by lipidex column chromatography. Derivatization to pentafluorobenzyloxime methyl ester TMS ethers of PGs in the sample is followed by separation on either glass packed-columns or SCOT capillary columns, and detection by an electron capture detector. PGA2, added to the unpurified sample, is used as an internal standard for quantification. The methods have performed well on all biological fluids thus far examined. Examples of chromatographs from urine, Krebs-perfused lung effluents, and blood are shown.     

Bile acids: analysis in biological fluids and tissues

The formation of bile acids/bile alcohols is of major importance for the maintenance of cholesterol homeostasis. Besides their functions in lipid absorption, bile acids/bile alcohols are regulatory molecules for a number of metabolic processes. Their effects are structure-dependent, and numerous metabolic conversions result in a complex mixture of biologically active and inactive forms. Advanced methods are required to characterize and quantify individual bile acids in these mixtures. A combination of such analyses with analyses of the proteome will be required for a better understanding of mechanisms of action and nature of endogenous ligands. Mass spectrometry is the basic detection technique for effluents from chromatographic columns. Capillary liquid chromatography-mass spectrometry with electrospray ionization provides the highest sensitivity in metabolome analysis. Classical gas chromatography-mass spectrometry is less sensitive but offers extensive structure-dependent fragmentation increasing the specificity in analyses of isobaric isomers of unconjugated bile acids. Depending on the nature of the bile acid/bile alcohol mixture and the range of concentration of individuals, different sample preparation sequences, from simple extractions to group separations and derivatizations, are applicable. We review the methods currently available for the analysis of bile acids in biological fluids and tissues, with emphasis on the combination of liquid and gas phase chromatography with mass spectrometry.     

Free amino acids and biogenic amines in red and white muscle of tuna stored in controlled atmospheres

Summary. This paper analyses the presence of and changes in free amino acids and biogenic amines in red and white muscle of bigeye tuna during storage in controlled atmospheres with 2 gas mixes containing different concentrations of CO₂ and O₂. Levels of amines were generally higher in white than in red muscle, with the exception of putrescine and spermidine. Levels of biogenic amines increased (p<0.05) throughout storage, commencing later in red than in white muscle. A correlation between the amino acid histidine and the biogenic amine histamine was observed, but only in white muscle. Only in the case of tryptophan did white and red muscle differ (p<0.05) in terms of essential free amino acid content. They also differed in anserine content. Concentrations of the non-essential FAAs glutamic acid, glycine and alanine were higher in red than in white muscle. The effectiveness of the atmospheres was reflected in the evolution of both biogenic amines and FAAs. Gas mix 1, containing a higher concentration of CO₂, was the more effective.     

High-performance liquid chromatographic analysis of biogenic amines in biological materials as o-phthalaldehyde derivatives

A remarkably sensitive, simple and selective reversed-phase high-performance liquid chromatographic (HPLC) method has been developed, allowing, for the first time, the direct measurement of histamine, norepinephrine, octopamine, normetanephrine, dopamine, serotonin and tyramine in a single sample of plasma (2 ml), tissue (0.2 g), or urine. The biogenic amines were modified by pre-column derivatization with o-phthalaldehyde which stabilizes the molecules, aids in extraction, and improves HPLC detection at the nanogram level. To minimize losses during the sampling procedure a careful collection procedure was designed.