Measurement of serum nitrite/nitrate concentrations using high-performance liquid chromatography

Previous studies have reported increased serum concentrations of nitrite/nitrate – the degradation products of nitric oxide – in Plasmodium vivax malaria and uncomplicated Plasmodium falciparum malaria. In all these studies, however, nitrite/nitrate has been measured spectrometrically using Griess reagent which carries major disadvantages in the determination of serum nitrite/nitrate. The method does not allow an exact differentiation of nitrite and biogenic amines that are physiologically present in plasma. In the present study we introduce high-performance liquid chromatography as a new, accurate and cost effective method for determination of serum nitrite/nitrate levels. Significantly increased nitrate concentrations were found in malaria patients and serum values remained above normal levels for at least 21 days. It could be shown that our HPLC method is a sensitive and cost-effective method for direct determination of nitrite/nitrate in serum samples, which is not influenced by the presence of biogenic amines.     

Analysis of nitrite and nitrate in biological fluids by assays based on the Griess reaction: appraisal of the Griess reaction in the L-arginine/nitric oxide area of research

In the Griess reaction, first reported by Johann Peter Griess in 1879 as a method of analysis of nitrite (NO(2)(-)), nitrite reacts under acidic conditions with sulfanilic acid (HO(3)SC(6)H(4)NH(2)) to form a diazonium cation (HO(3)SC(6)H(4)-N[triple bond]N(+)) which subsequently couples to the aromatic amine 1-naphthylamine (C(10)H(7)NH(2)) to produce a red-violet coloured (lambda(max) approximately 540 nm), water-soluble azo dye (HO(3)SC(6)H(4)-NN-C(10)H(6)NH(2)). The identification of nitrite in saliva has been the first analytical application of this diazotization reaction in 1879. For a century, the Griess reaction has been exclusively used to identify analytically bacterial infection in the urogenital tract, i.e. to identify nitrite produced by bacterial reduction of nitrate (NO(3)(-)), the major nitrogen oxide anion in human urine. Since the discovery of the l-arginine/nitric oxide (l-Arg/NO) pathway in 1987, however, the Griess reaction is the most frequently used analytical approach to quantitate the major metabolites of NO, i.e. nitrite and nitrate, in a variety of biological fluids, notably blood and urine. The Griess reaction is specific for nitrite. Analysis of nitrate by this reaction requires chemical or enzymatic reduction of nitrate to nitrite prior to the diazotization reaction. The simplicity of the Griess reaction and its easy and inexpensive analytical feasibility has attracted the attention of scientists from wide a spectrum of disciplines dedicated to the complex and challenging L-Arg/NO pathway. Today, we know dozens of assays based on the Griess reaction. In principle, every laboratory in this area uses its own Griess assay. The simplest Griess assay is performed in batch commonly as originally reported by Griess. Because of the recognition of numerous interferences in the analysis of nitrite and nitrate in biological fluids and of the desire to analyze these anions simultaneously, the Griess reaction has been repeatedly modified and automated. In recent years, the Griess reaction has been coupled to HPLC, i.e. is used for post-column derivatization of chromatographically separated nitrite and nitrate. Such a HPLC-Griess system is even commercially available. The present article gives an overview of the currently available assays of nitrite and nitrate in biological fluids based on the Griess reaction. Special emphasis is given to human plasma and urine, to quantitative aspects, as well as to particular analytical and pre-analytical factors and problems that may be associated with and affect the quantitative analysis of nitrite and nitrate in these matrices by assays based on the Griess reaction. The significance of the Griess reaction in the L-Arg/NO pathway is appraised.     

Spectrophotometric determination of serum nitrite and nitrate by copper-cadmium alloy

A macro and micro assay for the spectrophotometric determination of serum nitrite and nitrate was developed. Nitrite/nitrate in biological samples can be estimated in a single step by this method. The principle of the assay is the reduction of nitrate by copper-cadmium alloy, followed by color development with Griess reagent (sulfanilamide and N-naphthylethylenediamine) in acidic medium. This assay is sensitive to 1 microM nitrate and is suitable for different biological fluids, including sera with a high lipid concentration. The copper-cadmium alloy used in the present method is easy to prepare and can completely reduce nitrate to nitrite in an hour. The present method provides a simple, cost-effective assay for the estimation of stable oxidation products of nitric oxide in biological samples.     

Enzymatic microtiter plate-based nitrate detection in environmental and medical analysis

Our microtiter plate assay is based on the enzymatic reduction of nitrate by dissimilatory nitrate reductase from Pseudomonas stutzeri [EC 1.7.99.4]. Exogenous redox mediators like methyl viologen, methylene blue, and cibachron blue were applied to reduce nitrate reductase. Concentrations of 0.02-0.9 mM nitrate can be detected with +/-6% standard deviation, by using a photometric Griess reaction for the formed nitrite. Nitrate reductase is stable in the pH range 6.5-9.0 and works in the temperature range 4-76 degrees C. The assay shows no interferences with salt content up to 1 M chloride or 11 mM chlorate, and serum albumin content up to 50 mg/ml. The time demand of our two-step procedure is 20 min/100 samples. Nitrate reductase could be conserved on site of the wells of microtiter plates for at least 6 months at room temperature. The nitrate assay was applied in environmental and consumer goods analysis, and for medical diagnostics in human plasma samples.     

Analysis of nitrite/nitrate in biological fluids: denitrification of 2-nitropropane in F344 rats

2-Nitropropane (2-NP), a rat hepatocarcinogen, is denitrified to nitrite and acetone by rat liver microsomes; the denitrification rate is increased using microsomes from phenobarbital (PB)-pretreated rats. To obtain evidence that denitrification of 2-NP also occurs in vivo, we attempted to determine nitrite and nitrate levels in blood sera and urines of 2-NP-treated (1.5 mmol/kg, ip, once) rats with and without PB pretreatment (80 mg/kg, ip, once daily, 3 days), using enzymatic reduction followed by the standard Griess reaction. However, due to various interfering factors, including pigment from methemoglobinemia, we found the assay had to be modified as follows: (a) reduction of nitrate to nitrite was accomplished using NADPH and nitrate reductase, (b) excess NADPH, proteins, and interfering pigments were precipitated using zinc acetate and Na(2)CO(3), and (c) the Griess reagents were prepared in 3 N HCl rather than 5% H(3)PO(4). With these modifications it became possible to show that 2-NP is indeed metabolized to nitrite in vivo and that the metabolism is increased by PB pretreatment. Two hours after 2-NP administration, rat blood serum nitrate plus nitrite levels were approximately 1600 microM (PB-pretreated) and 940 microM (vehicle-pretreated controls). The PB-pretreated and control rats, respectively, excreted 250 and 120 micromol nitrate/nitrite in the 24-h urine post 2-NP treatment. The modifications described make the method more specific, reproducible, and more widely applicable.     

A rapid, simple spectrophotometric method for simultaneous detection of nitrate and nitrite.

Numerous methods are available for measurement of nitrate (NO(-)(3)). However, these assays can either be time consuming or require specialized equipment (e.g., nitrate reductase, chemiluminescent detector). We have developed a method for simultaneous evaluation of nitrate and nitrite concentrations in a microtiter plate format. The principle of this assay is reduction of nitrate by vanadium(III) combined with detection by the acidic Griess reaction. This assay is sensitive to 0.5 microM NO(-)(3) and is useful in a variety of fluids including cell culture media, serum, and plasma. S-Nitrosothiols and L-arginine derivatives were found to be potential interfering agents. However, these compounds are generally minor constituents of biological fluids relative to the concentration of nitrate/nitrite. This report introduces a new, convenient assay for the stable oxidation products of nitrogen oxide chemistry in biological samples.     

Determination of nitrate and nitrite by high-performance liquid chromatography in human plasma

A new, accurate, fast and simple method has been implemented by which nitrite and nitrate ions, as stable forms of nitric oxide production were studied. A study of these two ions was carried out by a sensitive and accurate HPLC method with two detectors. The most important advantages of the reported method are: short time of analysis, minimal sample pre-treatment, long life of the analytical column and stable eluent solution. The photodiode array UV-Vis detector detected nitrite and nitrate ions at an absorbance of 212 nm. Much more sensitive electrochemical detection with a WE (glassy carbon) electrode was used for the detection of nitrite ions. An analytical chromatographic column was formed by a sorbent, containing strong base anion-exchange groups bound in Cl(-) form in the hydrophilic hydroxyethyl methacrylate matrix. The anions were analysed in human plasma without deproteinization using 0.02 M sodium perchlorate monohydrate as eluent solution at pH 3.9. At this pH organic substances do not affect the analysis. The retention times for nitrite and nitrate were 3.62 and 3.72 min (by electrochemical detection) and 4.44 min, respectively. The method was linear (r=0.9992, 0.9998, 0.996) within a 1-100 (nitrate), 1-20 micro mol/l (nitrite) concentration range.     

Adaptation of the Griess reaction for detection of nitrite in human plasma

The determination of nitrite in human plasma or serum has been most frequently used as a marker of nitric oxide (NO) production. In addition, it has recently been suggested that nitrite could act as a vasodilating agent at physiological concentrations by NO delivery. Therefore, nitrite determination in biological fluids is becoming increasingly important. The most frequently used method to measure nitrite is based on the spectrophotometric analysis of the azo dye obtained after reaction with the Griess reagent. This method has some limitations regarding detection limit and sensitivity, thus resulting unsuitable for nitrite detection in plasma. We have identified some drawbacks and modified the original procedure to overcome these problems. By the use of the newly developed method, we measured 221±72 nM nitrite in human plasma from healthy donors.     

Analysis of nitrite and nitrate in biological samples using high-performance liquid chromatography

Various analytical techniques have been developed to determine nitrite and nitrate, oxidation metabolites of nitric oxide (NO), in biological samples. HPLC is a widely used method to quantify these two anions in plasma, serum, urine, saliva, cerebrospinal fluid, tissue extracts, and fetal fluids, as well as meats and cell culture medium. The detection principles include UV and VIS absorbance, electrochemistry, chemiluminescence, and fluorescence. UV or VIS absorbance and electrochemistry allow simultaneous detection of nitrite and nitrate but are vulnerable to the severe interference from chloride present in biological samples. Chemiluminescence and fluorescence detection improve the assay sensitivity and are unaffected by chloride but cannot be applied to a simultaneous analysis of nitrite and nitrate. The choice of a detection method largely depends on sample type and facility availability. The recently developed fluorometric HPLC method, which involves pre-column derivatization of nitrite with 2,3-diaminonaphthalene (DAN) and the enzymatic conversion of nitrate into nitrite, offers the advantages of easy sample preparation, simple derivatization, stable fluorescent derivatives, rapid analysis, high sensitivity and specificity, lack of interferences, and easy automation for determining nitrite and nitrate in all biological samples including cell culture medium. To ensure accurate analysis, care should be taken in sample collection, processing, and derivatization as well as preparation of reagent solutions and mobile phases, to prevent environmental contamination. HPLC methods provide a useful research tool for studying NO biochemistry, physiology and pharmacology.     

9- and 10-Nitro-oleic acid do not interfere with the GC-MS quantitative determination of nitrite and nitrate in biological fluids when measured as their pentafluorobenzyl derivatives

The nitrated lipids 9-nitro-oleic acid (9-NO(2)-OA) and 10-nitro-oleic acid (10-NO(2)-OA) have been reported to be present in blood of healthy humans. Free and esterified forms of 9-NO(2)-OA and 10-NO(2)-OA have been detected in human plasma at about 600 and 300 nM, respectively. These concentrations are of the same order of magnitude of circulating nitrite. In theory, 9-NO(2)-OA and 10-NO(2)-OA may interfere with the analysis of circulating nitrite and nitrate. In the present study, we investigated a possible interference of 9-NO(2)-OA and 10-NO(2)-OA with the GC-MS method of analysis of nitrite and nitrate involving derivatization by pentafluorobenzyl (PFB) bromide in aqueous acetone at 50 degrees C for 5 min (nitrite) or for 60 min (nitrite and nitrate). Our results show that 9-NO(2)-OA and 10-NO(2)-OA do not interfere with the GC-MS analysis of nitrite and nitrate as PFB derivatives in plasma and phosphate buffered saline when added to these matrices at supraphysiological concentrations of 1-10 microM. Thus, nitrated lipids such as 9-NO(2)-OA and 10-NO(2)-OA can be excluded as potential interfering substances in the GC-MS quantitative determination of nitrite and nitrate as their PFB derivatives.     

Electrochemical assay of the nitrate and nitrite reductase activities of Rhizobium japonicum

This work describes an electrochemical method for the determination of the nitrate and nitrite reductase activities of Rhizobium japonicum. The advantage of the method lies in the use of whole cells for the analysis and we earlier developed this protocol for the assay of NO. The results obtained are comparable to the spectrophotometric Griess assay. As the method is based on electrochemical reduction, the commonly interfering biological components like ascorbic acid, uric acid, dopamine, etc., will not interfere with the analysis. This method can be extended to the fabrication of biosensors for nitrate and nitrite using the same principle.     

Determination of imidapril and imidaprilat in human plasma by high-performance liquid chromatography–electrospray ionization tandem mass spectrometry

A sensitive and specific assay of imidapril and its active metabolite, imidaprilat, in human plasma has been developed. This method is based on rapid isolation and high-performance liquid chromatography (HPLC)–electrospray ionization (ESI)-tandem mass spectrometry (MS–MS). Imidapril and imidaprilat were isolated from human plasma using OASIS HLB (solid-phase extraction cartridge), after deproteinization. The eluent from the cartridge was evaporated to dryness, and the residue was reconstituted in mobile phase and injected into the HPLC–ESI-MS–MS system. Each compound was separated on a semi-micro ODS column in acetonitrile–0.05% (v/v) formic acid (1:3, v/v). The selected ion monitoring using precursor→product ion combinations of m/z 406→234 and 378→206, was used for determination of imidapril and imidaprilat, respectively. The linearity was confirmed in the concentration range of 0.2 to 50 ng/ml in human plasma, and the precision of this assay, expressed as a relative standard deviation, was less than 13.2% over the entire concentration range with adequate assay accuracy. The HPLC–ESI-MS–MS method correlates well with the radioimmunoassay method, therefore, it is useful for the determination of imidapril and imidaprilat with sufficient sensitivity and specificity in clinical studies.     

Rapid non-enzymatic HPLC determination of total MHPG in human plasma

We have previously reported a method for the determination of total 3-methoxy-4-hydroxy phenylethylene glycol (MHPG) in brain, based on a simple acid-catalyzed hydrolysis. Now we extend this procedure to the determination of plasma total MHPG. The method involves the deproteinization of plasma with perchloric acid, followed by 3 minutes of an acid-catalyzed step. The hydrolysates are injected into the HPLC system, using a formic acid/methanol eluent with fluorimetric detection. Sample detection limit is below 1 ng MHPG/mL of plasma. This procedure has been used for the determination of plasma total MHPG from 109 healthy individuals of both sexes. Mean value was: 5.4 + 2.3 ng total MHPG/mL of plasma (means +/- S.D., N = 109). No sex differences were observed, and a slight correlation with age (r = 0.24, p less than 0.02) has been found. Plasma-free MHPG was also determined in a subgroup of 15 randomly chosen individuals (3.0 +/- 1.2 ng free MHPG/mL plasma, means +/- S.D.). A significant correlation was obtained with plasma total MHPG (r = 0.77, p less than 0.001, N = 15). The main advantage of the present method lays in its simplicity, since no enzymatic hydrolysis or extraction procedures are needed, being its reliability fully proven through 109 plasma total MHPG determinations.     

Measurement of S-nitrosoalbumin by gas chromatography--mass spectrometry. III. Quantitative determination in human plasma after specific conversion of the S-nitroso group to nitrite by cysteine and Cu(2+) via intermediate formation of S-nitrosocysteine and nitric oxide

Highly contradictory data exist on the normal plasma basal levels in humans of S-nitrosoproteins, in particular of S-nitrosoalbumin (SNALB), the most abundant nitric oxide (.NO) transport form in the human circulation with a range of three orders of magnitude (i.e., 10 nM-10 microM). In previous work we reported on a GC-MS method for the quantitative determination of SNALB in human plasma. This method is based on selective extraction of SNALB and its 15N-labeled SNALB analog (S(15)NALB) used as internal standard on HiTrapBlue Sepharose affinity columns, HgCl(2)-catalysed conversion of the S-nitroso groups to nitrite and [15N]nitrite, respectively, their derivatization to the pentafluorobenzyl derivatives and quantification by GC-MS. By this method we had measured SNALB basal plasma levels of 181 nM in healthy humans. It is generally accepted that HgCl(2)-catalysed conversion of S-nitroso groups into nitrite is specific. In consideration of the highly divergent SNALB plasma levels in humans reported so far, we were interested in an additional method that would allow specific conversion of S-nitroso groups into nitrite. We found that treatment with cysteine plus CuSO(4) is as effective and specific as treatment with HgCl(2). The principle of the cysteine/CuSO(4) procedure is based on the transfer of the S-nitroso group from SNALB to cysteine yielding S-nitrosocysteine, and its subsequent highly Cu(2+)-sensitive conversion into nitrite via intermediate.NO formation. Similar SNALB concentrations in the plasma of 10 healthy humans were measured by GC-MS using HgCl(2) (156+/-64 nM) and cysteine/CuSO(4) (205+/-96 nM). Our results strongly suggest that SNALB is an endogenous constituent in human plasma and that its concentration is of the order of 150-200 nM under physiological conditions.     

Elimination of matrix-based interferences to a fluorescent nitrite/nitrate assay by a simple filtration procedure

Pathophysiological levels of oxygen radical metabolites have been studied as indicators of trauma caused by burn insult. The 2, 3-diaminonaphthalene assay is routinely used in the determination of nitrite/nitrate levels in biological fluids and cellular extracts as one indicator of nitric oxide activity. Several laboratories, including ours, have noted matrix-based interferences resulting in decreased assay sensitivity during nitrite/nitrate analysis. We evaluated filtration using Millipore Ultrafree-MC 10,000 NMWL filters for the ability to eliminate matrix-based interferences from human serum and tissue culture medium, thereby restoring assay sensitivity.     

A spectrophotometric assay for nitrate in an excess of nitrite.

Miranda et al. have developed a method for simultaneous evaluation of nitrate and nitrite concentrations using reduction of nitrate by vanadium(III) combined with detection by the acidic Griess reaction [K.M. Miranda, M.G. Espey, D.A. Wink, A rapid, simple spectrophotometric method for simultaneous detection of nitrate and nitrite, Nitric Oxide 5 (2001) 62-71]. The sensitivity of the nitrate assay decline if the mixture analyzed contains a large excess of nitrite relative to nitrate, for instance, in the case of oxidation products of nitric oxide (NO) in aerated solutions, or in sweat. By this reason nitrite should be removed before the nitrate assay, if [NO2-]>[NO3-]. Here we lay out an improved method allowing the above limitation to be erased, using sulfamic acid for nitrite removal. We also describe some modifications that enhance the reproducibility of the assay.     

Quantitative analysis of sinistrin in serum with high-performance liquid chromatography for renal function testing

Sinistrin, as inulin, is widely used as a marker for renal function testing. A reliable and accurate method with a simple sample preparation for the quantitative determination of sinistrin would be of advantage. We developed a high-performance liquid chromatography (HPLC)-based method with electrochemical detection for the quantitative measurement of sinistrin in serum and plasma. Sample preparation is easy and includes enzymatic removal of glucose, deproteinization, acid hydrolysis of sinistrin, and HPLC separation of fructose. The recovery of sinistrin from serum is the same as that from water and is near 100%. The method presented has a linear range up to 500 mg/L. The results from our method are in agreement with a fully enzymatic quantification (regression coefficient 1.01, coefficient of variation 0.97). Sinistrin concentrations in aqueous solutions can be measured down to 2mg/L with a coefficient of variation of 5.7%. Quantification in serum is primarily limited by its physiological fructose content. The sensitivity of the described method is sufficient for its use in renal function testing. We describe a method for quantification of sinistrin which allows accurate measurements especially at low concentrations and low sample volumes. This laboratory method may be used for obtaining sinistrin pharmacokinetics in renal function testing.     

Fluorometric measurement of nitrite/nitrate by 2,3-diaminonaphthalene

We describe a step-by-step protocol for measuring the stable products of the nitric oxide (NO) pathway: nitrite, nitrite plus nitrate and nitrate. This described protocol is easy to apply and is about 50 times more sensitive than the commonly used Griess reaction or commercially available assay kits based on the Griess reaction. It also allows the study of minimal changes in the NO pathway. With this method, it takes about 3 h to analyze the above-mentioned stable products in culture supernatants or in various body fluids, and the method has a sensitive linear range of 0.02-10.0 microM. This restricted linear range suggests that the technique is useful for studying small changes of nitrite and nitrate, rather than for routine diagnostic measurements.     

Rapid and sensitive determination of sertraline in human plasma using gas chromatography-mass spectrometry

A method for the determination of sertraline in human plasma using gas chromatography-mass spectrometry (GC-MS), with the selected ion-monitoring (SIM) mode, was described. The following was used in this study: (1) single liquid-liquid extraction at alkaline pH after deproteinization of plasma protein and (2) perfluoroacylation with HFBA, which has higher sensitivity (about 10-fold) compared with previous reported derivatization. The detection limit for the SIM of sertraline as an N-HFB derivative was 0.1 ng/ml, and its recovery was 80-85%. The linear response was obtained in the range of 0.2-10.0 ng/ml with a correlation coefficient of 0.999. The coefficient of variation (C.V.%) was less than 12.1% in the 1-30 ng/ml, and less than 18.2% at 0.2 ng/ml, and the accuracy was less than 10% at all of the concentration range. These findings indicate that this assay method has adequate precision and accuracy to determine the amount of sertraline in human plasma. After pharmacokinetics was performed with this assay method following oral administration of sertraline hydrochloride in man, moment analysis revealed that pharmacokinetic parameters for sertraline (Cmax, 10.3 ng/ml; Tmax, 8.0 h; T(1/2) 28.6 h) were similar to previously reported results. These results indicate that this simple and sensitive assay method is readily applicable to the pharmacokinetic studies of sertraline.     

Determination of amphetamine in human urine by dansyl derivatization and high-performance liquid chromatography with fluorescence detection

A simple procedure for the determination of amphetamine in urine with minimal sample preparation is described. This method involves direct addition of human urine to an acetone-dansyl chloride solution for simultaneous deproteinization and fluorescence derivatization. The derivatized amphetamine is then measured by HPLC with fluorescence detection. It eliminates the extraction procedures often required by other HPLC or GC methods. The effects of pH, temperature and reaction time on the derivatization reaction were investigated. The stability of amphetamine-dansyl chloride in different storage conditions was examined. The detection limit and linearity associated with this assay are discussed.