Determination of the naturally occurring monoacetyl derivatives of di- and polyamines

A method is described for the determination of pmol quantities of monoacetylputrescine, N¹-acetylspermidine, N⁸-acetylspermidine and related compounds. The method is based on the derivatization of these compounds with 5-dimethylaminonaphthalene-1-sulphonyl-chloride, followed by thin-layer chromatographic separation. Cleanup steps allow the application of the method to urine analyses. From the repeated determination of acetylated polyamines in the urine of healthy individuals it can be concluded that these conjugates are the major excretory form of di- and polyamines.The cleanup steps used in this procedure and the method described for the stabilization of 5-dimethylaminonaphthalene-1-sulphonyl derivatives on thin-layer plates are advantageous also for the analyses of total polyamines in urine hydrolysates, and in related applications of the dansylation method.     

The determination of N1-acetylspermine in mouse liver

N¹-Acetylspermine has been postulated to be an intermediate in the conversion of spermine to spermidine. This compound, together with N¹-acetylspermidine has now been detected in the liver of mice which were pretreated with tetrachloromethane. The following methods were used for the identification of N¹-acetylspermine: (a) High-pressure liquid-chromatography of the non-derivatized amines on a reversed-phase column, using octane sulfonate for ion-pairing. (b) Thin-layer chromatography of the dansyl derivatives. (c) Mass spectrometry of the dansyl derivatives. Both chromatographic methods allowed the quantitative estimation of N¹-acetylspermine and N¹-acetylspermidine in the liver of tetrachloromethane-treated animals.     

Gas chromatographic method for the determination of urinary acetylpolyamines

A gas chromatographic method was developed for the determination of monoacetylputrescine, monoacetylcadaverine, N¹-acetylspermidine and N⁵-acetylspermidine in human urine. The amines were isolated from urine by silica gel column chromatography. 1, 10-Diaminodecane was used as internal standard. The amines were reacted with ethyl chloroformate in aqueous medium to four ethyloxycarbonyl derivatives prior to application to gas chromatography using a flame ionization detector. Separation and determination of the derivatives were carried out on a Uniport HP column (1.0 m) impregnated with 0.5% SP-1000 under temperature-programmed conditions. The monoacetylpolyamines could be measured accurately at the nanomole level. The method was used for the determination of the monoacetylpolyamines in urine of healthy volunteers. The values obtained were in the range of the published data.     

Analysis of polyamines and acetyl derivatives by a single automated amino acid analyzer technique

In a single, rapid and precise analysis, monoacetylputrescine, N⁸-acetylspermidine, N¹acetylspermidine, putrescine, spermidine, and spermine can be separated using a five-buffer system on an automatic amino acid analyzer. This method allows, for the first time, the separation of all the known acetyl derivatives of putrescine and spermidine as well as the parent compounds in urine and tissues with a single automated procedure. The method has been applied to the analysis of biological samples from normal volunteers, cancer patients and a rat liver supernatant. Mass spectral confirmation was obtained for each compound.     

High-performance liquid chromatographic determination of α-keto acids in human urine and plasma

A high-performance liquid chromatographic method has been developed for the determination of α-keto acids in human urine and plasma. These acids were prepurified using a column of hydrazide gel and derivatized with o-phenylenediamine into 2-quinoxalinol derivatives, which were extracted into ethyl acetate. The 2-quinoxialinol derivatives were separated by reversed-phase paired-ion chromatography using a 250 × 4 mm-i.d. column packed with LiChrosorb RP-8 (5 μm). This method is sensitive, selective, and reproducible. The α-keto acids in urine and plasma from normal individuals were determined.     

Identification and determination of urinary acetylpolyamines in cancer patients by electrospray ionization and time-of-flight mass spectrometry

A method for the quantification of acetylpolyamines, N¹,N¹²-diacetylspermine (DiAcSpm), monoacetylspermidine (AcSpd), and N¹,N⁸-diacetylspermidine (DiAcSpd), identifying each compound simultaneously, was developed with the goal of evaluating these acetylpolyamines as potential biomarkers of cancer. The method consists of prepurification of acetylpolyamines in urine with commercially available cartridges and derivatization with heptafluorobutyric (HFB) anhydride. HFB derivatives of acetylpolyamines were determined simultaneously using ¹⁵N-labeled acetylpolyamines as internal standards by electrospray ionization and time-of-flight mass spectrometry (ESI-TOF MS). After the method was validated, the urinary acetylpolyamines of 38 cancer patients were quantified with this method. A comparison of the concentrations of DiAcSpm with those measured by a colloidal gold aggregation method demonstrated a correlation coefficient of 0.996, showing that the two methods were equally satisfactory. Analysis of the correlation between DiAcSpd or AcSpd and DiAcSpm, performed for the first time, indicated the usefulness of DiAcSpm as a urinary biomarker of cancer. During the course of this work, two simple methods for the preparation of α,ω-diacetylpolyamines were developed, and a possibility to separate and determine the concentrations of the two isomers, N¹-acetylspermidine and N⁸-acetylspermidine in AcSpd, was shown by tandem mass spectrometry (MS/MS).     

A chemical method for the quantitative determination of 2-hydroxyestrone in human urine

A highly specific chemical procedure for the quantitative determination of 2-hydroxyestrone in the urine of pregnant women is described. The assay consists of the following steps: 1) Hot acid hydrolysis of 20 ml of urine, 2) purification of 2-hydroxyestrone by “reducing chromatography” on paper and silica gel column, 3) conversion of 2-hydroxyestrone to the phenazine compound, 4) purification of the phenazine derivative by alumina column chromatography, and 5) spectroscopic quantitation of the phenazine. For internal yield correction [4-¹⁴C]2-hydroxyestrone is added after urine hydrolysis. High specificity of the method is especially guaranteed by the specific transformation of 2-hydroxyestrone to a stable phenazine derivative and by rigorous chromatographic purification of the estrogen as well as of the phenazine. The method can be used for the determination of amounts of less than 1 μg of 2-hydroxyestrone/20 ml of urine. From the data obtained the coefficient of variation is calculated to be ±3.7%. The urinary excretion of 2-hydroxyestrone in late pregnancy was found to vary within a wide range of 30–800 μg of 2-hydroxyestrone/24 hours.It seems possible to extend this method to the determination of other 2-substituted estrogens present in urine.     

Derivatization and high-performance liquid chromatographic analysis of pentaazapentacosane pentahydrochloride

A rapid high-performance liquid chromatographic method for determination of the dansyl derivative of pentaazapentacosane (PAPC) pentahydrochloride has been developed. The chromatographic system uses a reversed-phase C₈ column, a mobile phase of acetic acid buffer and acetonitrile and UV detection. The dansylation conditions were optimized with a pH of 11.0 and a 20-fold dansyl chloride excess. The yield of dansyl PAPC increased 10-fold as the reaction pH was changed from 9.5 to 10.5. Under derivatization conditions of pH 8.5–11.0 and 1–30-fold excess dansyl chloride only perdansyl PAPC was found.     

Acetylated polyamines as substrates for human pregnancy serum diamine oxidase

Human pregnancy serum diamine oxidase was purified 50 fold and tested for activity with a variety of substrates. Putrescine, spermidine, spermine, N-acetylputrescine, N⁸-acetylspermidine, and N¹-acetylspermidine were acceptable substrates for the enzyme, which exhibited greatest activity against N¹-acetylspermidine.     

Amines in unicellular green algae: 2. Amines in Scenedesmus acutus

Scenedesmus acutus contains about 10 major amines and at least 20 other amines which are present in very small quantities. The following amines were identified by mass spectrometry after separation of the trifluoroacetyl derivatives by gas-liquid chromatography and of the dansyl ² derivatives by thin-layer chromatography: methylamine, dimethylamine, ethylamine, ethanolamine, putrescine, cadaverine, spermidine, N-(3-aminopropyl)-1,3-diaminopropane, N-(4-aminobutyl)-1,4-diaminobutane, 2-phenylethylamine, tyramine, piperazine, adenine, and γ-butyrolactam. The methods applied for the analyses of these amines are described and discussed.     

Acetylputrescine deacetylase from Micrococcus luteus K-11

An acetylputrescine deacetylase was induced in Micrococcus luteus K-11, and was partially purified and characterized briefly. The enzyme was most active toward acetylputrescine, followed by N⁸-acetylspermidine and acetylcadaverine, but was inactive toward N¹-acetylspermidine and N¹-acetylspermine. The K_m value for acetylputrescine was 0.321 mM. It was almost unaffected by -SH blocking agents but was inhibited by metal ions such as Cu²⁺ and Ni²⁺. Its molecular weight estimated by Sephacryl S-200 column chromatography was 115000.     

Gaschromatographische analyse von sauren urinmetaboliten nach trennung auf kieselgelfertigsäulen

Gas chromatographic estimation of acidic urinary metabolites after separation on prepacked silica gel columnsThe acidic ethylacetate extracts of 24-h urine specimens are evaporated and redissolved in chloroform—methanol—acetic acid. The resulting solution is transferred to a prepacked silica gel column. Elution takes 160 min using a specially designed chloroform—methanol—acetic acid gradient. The eluate is divided into fractions (16 min each) which are evaporated to dryness. The residues are silylated and determined quantitatively by gas chromatography. The capacity of the silica gel column allows analysis of 30% of a 24-h urine specimen. In consequence, metabolites can be quantitated at concentrations less than 1 mg per 24 h. The method is suitable to obtain more detailed metabolic profiles of the carboxylic acids in urine.     

Cytokinins: A Rapid Extraction and Purification Method

A method is described for the isolation, purification and quantitation of free cytokinin bases and ribosides using ethyl acetate at pH 7.7 for the extraction. The extraction is almost complete (97.7%) as determined by using N⁶-(Δ²-isopentenyl)adenine-8-¹⁴C. The subsequent fast purification by chromatography on a standardized silica gel column in chloroform-methanol (7:3 v/v) is followed by thin layer chromatography (silica gel 60 F²⁵⁴) in chloroform-acetic acid (8:2 v/v). The recovery of N⁶-(Δ²-isopentenyl)adenine-8-¹⁴C after this two step purification was 78–82%. The efficiency of the method was determined by applying this procedure to N⁶-(Δ²-isopentenyl)adenine and N⁶(Δ²-isopentenyl)adenosine. Using gas liquid chromatography the recovery for N⁶-(Δ²-isopentenyl)adenosine was determined to be 61% and compared to 43% for N⁶-(Δ²-isopentenyl)adenosine, showing the suitability of the described method for gas liquid chromatography.     

Acetylation of spermidine in polyamine catabolism

Treatment with thioacetamide (150 mg/kg)_ was used to enhance polyamine metabolism in rat liver. The increased uptake and catabolism of [¹⁴C]spermine and the changes of putrescine, spermidine and spermine concentrations indicated enhanced polyamine turnover rates. The increase of hepatic putrescine concentration was accompanied by an increase of monoacetylputrescine and N¹-monoacetylspermidine concentration. In control animals, the latter compound was below detection levels. Thioacetamide treatment also enhanced putrescine excretion, which again was concomitant with an increased excretion of N¹-acetylspermidine.The close time-dependent correlation between induced putrescine formation and enhanced formation of N¹-acetylsperimidine at a time when liver spermidine and spermine concentrations are not changed, favors the notion that acetylation is an essential step in polyamine degradation and elimination. The increase of polyamine oxidase and decrease of acetylpolyamine deacetylase activities in the liver of thioacetamide-treated rats is in line with an increased polyamine turnover, but these enzymes. although essential, are not rate-limiting in the catabolic reactions.     

An Improved Isolation Procedure for the Gas Chromatographic Analysis of Urinary Polyamines

The isolation of polyamines from urinary hydrolysates in a sufficiently pure state for subsequent analysis by gas chromatography has proved to be difficult. However, by using columns of Porapak-Q and ion-exchange resins, urinary hydrolysates are readily purified and formation of trifluoroacetyl derivatives of polyamines proceeds in high yield without carryover of artifacts in the gas chromatographic elution profile. Good yields from the trifluoroacetylation reaction are not achieved if large quantities of salts or urinary pigments are present. By obtaining the polyamine carbonates in the final stages of the method described, the trifluoroacetylation reaction yields excellent derivatives of nanogram or microgram amounts, particularly after standing over-night at room temperature. The procedure described in detail should permit routine urinary polyamine analysis where rapidity, ease of handling many samples, freedom from complications and artifacts are a consideration. The recent reports by Russell^{1, 2} that the urinary excretion of polyamines are greatly elevated in cancer patients has stimulated interest in these compounds as possible biological “markers” for the diagnosis of cancer. The polyamines usually considered are: putrescine, 1, 4-diaminobutane; cadaverine, 1, 5-diaminopentane; spermidine, and spermine. An extensive literature has developed over the last 50 years concerning the isolation and determination of polyamines including many excellent reviews. ^3–5 However, the isolation and determination of small quantities of polyamines from biological sources has proven to be difficult. This has led to conflicting conclusions among investigators as to which polyamine is the major excretion product in the urine of cancer patients. ^{2, 6, 7, 8} The following report presents in detail a new procedure of isolation of urinary polyamines in high yield and pure state that facilitates quantitation of these amines by gas chromatography.     

High-performance liquid chromatographic determination of α-keto acids

A high-performance liquid chromatographic method has been developed for the determination of eight kinds of α-keto acids. These acids were derivatized with o-phenylenediamine into 2-quinoxalinol derivatives, which were extracted into chloroform. The quinoxalinol derivatives were separated by reversed-phase high-performance liquid chromatography using a 250 mm × 2.1 mm I.D. column packed with LiChrosorb RP-8 (5 μm). This method could be satisfactorily applied to urine samples without any prepurification.     

Simultaneous determination of histamine and Nτ-methylhistamine in human plasma and urine by gas chromatography-mass spectrometry

A new and sensitive method is described for the determination of histamine and N^τ-methylhistamine in human plasma and urine by gas chromatography-mass spectrometry. ¹⁵N₂-Labeled histamine and N^τ-[methyl-d₃]methylhistamine were used as internal standards. Histamine and N^τ-methylhistamine were converted to the derivatives N^α-heptafluorobutyryl-N^τ-ethoxycarbonylhistamine and N^α-heptafluorobutyryl-N^τ-methylhistamine, respectively. After these derivatives had been purified on a small column packed with CPG-10, the molecular ions were monitored during selected ion monitoring. Linear standard curves were obtained in the range of 0.5–10 ng/ml for both compounds. The reliability of the histamine analysis was demonstrated by using two different ion pairs, while a comparison with results from two different derivatizations on the same urine sample also established the specificity of the N^τ-methylhistamine analysis. An increase of 1 ng of histamine in the plasma could be precisely determined by the present method. The histamine content of plasma from five normal subjects was determined as 0.83 ÷ 0.37 (S.D.) ng/ml and the N^τ-methylhistamine content in most subjects was below the limits of this measurement. High excretion of histamine was noted in the urine collected in the early morning from a patient with nephritis.     

A micromethod for the analysis of free amino acids by gas chromatography and its application to biological systems.

A gas chromatographic procedure was developed for determination of minute amounts of free amino acids in natural waters and laboratory models simulating biological systems. Sample pretreatment included removal of interfering organic substances by chloroform extraction and isolation of amino acids by cation exchange. Amino acids were converted to their N-heptafluorobutyryl isobutyl ester derivatives in glass capillary tubes, permitting considerable concentration of the sample prior to gc injection. The derivatives of 19 amino acids were successfully separated on either a glass column packed with a mixture of OV-101 and OV-17 on Chromosorb W, a glass capillary column coated with OV-101, or a support-coated capillary column supported with SE-30. One to five nanograms of individual amino acids were detected using flame ionization detector. The detection limit was reduced more than 100-fold using the electron capture detector and more than 1000-fold by mass fragmentography. The procedure allowed determination of less than 1 ppb of individual amino acids in lake and river water samples and was used to estimate the exeretion of free amino acids from microbial populations.     

High-performance liquid chromatographic determination of the β2-selective adrenergic agonist fenoterol in human plasma after fluorescence derivatization

A sensitive high-performance liquid chromatographic method has been developed for the determination of the β₂-selective adrenergic agonist fenoterol in human plasma. To improve the sensitivity of the method, fenoterol was derivatized with N-(chloroformyl)-carbazole prior to HPLC analysis yielding highly fluorescent derivatives. The assay involves protein precipitation with acetonitrile, liquid–liquid-extraction of fenoterol from plasma with isobutanol under alkaline conditions followed by derivatization with N-(chloroformyl)-carbazole. Reversed-phase liquid chromatographic determination of the fenoterol derivative was performed using a column-switching system consisting of a LiChrospher^® 100 RP 18 and a LiChrospher^® RP-Select B column with acetonitrile, methanol and water as mobile phase. The limit of quantitation in human plasma was 376 pg fenoterol/ml. The method was successfully applied for the assay of fenoterol in patient plasma.     

Determination of terbutaline enantiomers in human urine by coupled achiral–chiral high-performance liquid chromatography with fluorescence detection

A coupled achiral–chiral high-performance liquid chromatographic system with fluorescence detection at excitation/emission wavelengths of 276/306 nm has been developed for the determination of the enantiomers of terbutaline, (S)-(+)-terbutaline and (R)-(−)-terbutaline in urine. Urine samples were prepared by solid-phase extraction with Sep-pak silica, followed by HPLC. The terbutaline was preseparated from the interfering components in urine on Phenomenex silica column and the terbutaline enantiomers and betaxolol were resolved and determined on a Sumichiral OA-4900 chiral stationary phase. The two columns were connected by a switching valve equipped with silica precolumn. The precolumn was used to concentrate the terbutaline in the eluent from the achiral column before back flushing onto the chiral phase. For each enantiomer the assay was linear between 1 and 250 ng/ml (R²=0.9999) and the detection limit was 0.3 ng/ml. The intra-day variation was between 4.6 and 11.6% in relation to the measured concentration and the inter-day variation was 4.3–11.0%. It has been applied to the determination of (S)-(+)-terbutaline and (R)-(−)-terbutaline in urine from a healthy volunteer dosed with racemic terbutaline sulfate.