The amperometric titration of plasma chloride and urine chloride

It has been shown that the method of Laitinen, Jennings, and Parks for the amperometric titration of chloride can be easily adapted to analyses of plasma (serum) and urine chlorides. For the procedure 1.0-ml. samples are diluted so that the mixture being titrated is 50% in acetone and 0.8 N in nitric acid. Silver nitrate, 0.0100 N, is used as the titrant, and the rotating platinum electrode is used as the indicator electrode. The method is simple, rapid, and as accurate as existing methods.When 0.1-ml. samples are analyzed, the accuracy is decreased a little over that obtained when 1.0-ml. samples are used.The method is not satisfactory for the analysis of chloride in the presence of whole blood or muscle tissue.     

Colorimetric determination of chloride in biological samples by using mercuric nitrate and diphenylcarbazone

A colorimetic method is outlined for the determination of the chloride ion in biological samples (blood serum, plasma, and urine). The present method is based on the quantitative reduction of free mercuric ions by chloride ions. Chloride ions form an indissociable complex with mercuric ions. The remaining free mercuric ions form a purple complex with diphenylcarbazone with an absorption maximum at 550 nm. The reduction of color intensity at 550 nm is directly proportional to chloride concentration in the sample. The linear concentration range in the final reaction mixture was 0–100 μM with a correlation coefficient of −0.9997. The coefficient of variation for the 50 μM chloride ion in the final reaction mixture was 0.9% (n=6). The analyzed value of chloride concentration in the human control serum Accutrol™ Normal (Sigma) was 101±4 mM (mean±SD, n=12). The certified value of chloride in Accutrol Normal by Sigma is 102 mM, with a mean in the range 91–113 mM. This method was applied to the measurement of urinary chloride excretion in experimental rats. During 16-h urine collection, no food was given and rats had free access to purified water. The urinary excretion rate of chloride was 23.6±9.3 μmol/h (mean±SD, n=8) and 126.2±28.0 μmol/h (n=8) for rats fed a normal diet (2.6 g NaCl/kg diet) and a high-salt diet (82.6 g NaCl/kg diet) for 70 d prior to urine collection, respectively. This method is appropriate for low concentrations of chloride in samples or when sample volume is limiting, as in many animal studies such as metabolic urine collection from rats. The U.S. Department of Agriculture, Agricultural Research Service, Northern Plains Area, is an equal opportunity/affirmative action employer and all agency services are available without discrimination. Mention of a trademark or proprietary product does not constitute a guarantee or warranty of the product by the U.S. Department of Agriculture and does not imply its approval to the exclusion of the products that may also be suitable.     

Determination of benzethonium chloride in anthrax vaccine adsorbed by HPLC

A novel and sensitive HPLC method for the determination of benzethonium chloride (BZC) in anthrax vaccine was developed. Adjuvant Alhydrogel was removed by syringe filter after a simple sample pretreatment - acidification prior to injection. Chromatography was performed by isocratic reverse phase separation with methanol/262 mM ammonium acetate (80/20, v/v) on an endcapped C18 column with diode array detector (DAD). The method showed excellent recovery (100+/-1.5%). The results indicated that this method could accurately determine BZC at the limit of detection (LOD) of 0.5 ppm and the limit of quantitation (LOQ) of 1.5 ppm with dynamic range up to 100 ppm. The comparison of analysis between new HPLC and old titrimetric methods is also reported. The HPLC method is proven to be more accurate and precise with much less vaccine sample and human labor required.     

High-sensitivity capillary electrophoresis determination of inorganic anions in serum and urine using on-line preconcentration by transient isotachophoresis

Concentrations of inorganic anions, both as individual species and biotransformation products, in physiological fluids are of strong concern in clinical studies. To date, analytical methodologies have either required different analytical procedures to determine these analytes in plasma and urine, or extensive sample preparation, or unconventional and often expensive detection schemes, or both. A simple and sensitive capillary electrophoresis (CE) method with direct UV detection was developed for the simultaneous determination of iodide, bromide and nitrate in human plasma and urine, with a special focus on reliable quantification of the trace serum iodide. With the latter objective, the method incorporates a transient isotachophoresis (tITP) procedure enabling an efficient on-line preconcentration of iodide (limit of detection, 1.4 microg l(-1)) as well as other moderately mobile analytes that fall into the tITP range. The analyses of both types of biofluids were performed using an acidic electrolyte system composed of 0.25 mol l(-1) sodium chloride and 7.5 mmol l(-1) cetyltrimethylammonium chloride at pH 2.2 and 0.5 mol l(-1) 2-(N-morpholino)ethanesulfonate (pH 6.0) as terminating electrolyte. Relative standard deviations (R.S.D.) below 3.0% and 9.2% were obtained for within-day and between-day precision, respectively. Resolution and quantification of oxalic acid was also feasible under optimized tITP-CE conditions. Sample preparation required only ultrafiltration (serum) and dilution (urine). A number of plasma and urine samples were evaluated with this assay and the iodide, bromide and nitrate concentrations were in the expected clinical concentration ranges.     

Urinary organic acid screening by solid-phase microextraction of the methyl esters

We developed a new sample preparation method for profiling organic acids in urine by GC or GC–MS. The method includes derivatisation of the organic acids directly in the aqueous urine using trimethyloxonium tetrafluoroborate as a methylating agent, extraction of the organic acid methyl esters from the urine by solid-phase microextraction, using a polyacrylate fiber with a thickness of 85 μm and transfer of the methyl esters into the GC or the GC–MS instrument. Desorption of the analytes takes place in the heated injection port. The proposed sample preparation is very simple. There is no need for any evaporation step and for the use of an organic solvent. The risk of contamination and the loss of analytes are minimized. The total sample preparation time prior to GC or GC–MS analysis is about 40 min, and therefore more rapid than other sample preparation procedures. The urinary organic acids are well separated by GC and 29 substances are identified by GC–MS.     

Determination of iodide in serum and urine by ion-pair reversed-phase high-performance liquid chromatography with coulometric detection

An HPLC method is described for the determination of iodide in serum and urine using ion-pair chromatography with coulometric detection. After adding hexadecyltrimethylammonium chloride, the ions pairs formed with the iodide in the sample are extracted using an organic solvent. The solvent is then evaporated and the dry residue obtained is mixed with an appropriate volume of mobile phase so as to concentrate the sample prior to injection into the chromatograph. For a sample of 0.5 ml of serum, the method features a limit of detection (signal-to-noise ratio of 3) of 0.2 μgl⁻¹, sufficient to be applied in paediatric assays for the diagnosis of both iodide deficiency and excess.     

Measurement of iodide in urine using the iodide-selective ion electrode

A simple and rapid way to measure the concentration of iodide in urine with an iodide-selective ion electrode was described. Potentiometric equilibrium was attained in less than 5 min, and a linear calibration curve was obtained over the potassium iodide (KI) concentration range of 10(-2) to 10(-6) M. The coefficients of variation ranged from 6.2 to 10.0% within assay, and 5.4 to 14.4% between assays. The serial dilution of 3 urine samples with different concentration of iodide showed good linear correlations passing through zero. In practice, the chloride ions in urine did not cause serious errors in the measurement of iodide at molar ratios of chloride ion to iodide up to 2 X 10(4). A good linear correlation was obtained between iodide concentrations in urine determined by the electrode method and by the conventional chemical method (r = 0.92). A linear correlation was also observed between the iodide concentrations of 24 h collected urine and those of single morning urine (r = 0.91). The normal iodide content in single morning urine specimens from 127 Japanese people was 5.3 to 62.0 X 10(-6) moles/g creatinine.     

Capillary electrophoresis analysis of biofluids with a focus on less commonly analyzed matrices

The analysis by capillary electrophoresis of less commonly analyzed biofluids is reviewed. The sample matrices considered include airway surface fluid, sputum, synovial fluid, amniotic fluid, saliva, cerebrospinal fluid, aqueous humor, vitreous humor, and sweat. Many of the techniques used in the analysis of abundant and commonly tested biofluids such as plasma or urine can be applied to these other matrices, e.g. sample extraction prior to analysis. However, for some of these alternative biofluids the available sample amounts are only in the nanoliter or low microliter range, which places constraints on the sample preparation options which are available. For such samples, direct sample injection may be necessary, possibly coupled with on-capillary concentration or derivatization approaches. Particular attention is paid in this review to analyses where the sample is directly injected onto the separation capillary or where minimal sample preparation is performed.     

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.     

Mechanistic studies of ion-selective electrodes

A knowledge of the chemical composition of blood, urine and other body fluids is a daily requirement for departments of biochemistry. Electronic circuitry and computers to process the data are readily available, but satisfactory transducers to convert chemical composition into electrical signals are frequently the weakest link in the chain of measurement. This review is concerned with one group of transducers: ion-selective electrodes.Since the commercial success of the calcium and fluoride ions-selective electrodes in the mid-sixties, a range of other electrodes has become available. Their use has already conferred considerable benefits upon medicine, e.g. rapid, low-cost, multiple assay of major blood components; diagnostic surveys of chloride sweat levels relating to cystic fibrosis; and monitoring blood fluorides during and after halothane administration. Their adoption for indirectly sensing enzymes and associated substrates is particularly noteworthy. Recent advances in electronics, coupled with flow injection schemes based on ion-selective electrodes, have facilitated the management of hundreds of samples daily.However, developments in the mechanistic knowledge of these sensors have not matched the increase in their application, although definite progress can be reported; for example with regard to the origin of the potential signals induced by ion activities in solution. Numerous techniques have been devised to unravel mechanistic problems, among which radioisotope tracer and impedance measurements may be cited as especially valuable.Selectivity performance, particularly in complex biological media, and undesirable features such as protein poisoning, need further research. Organic chemists are now better placed to synthesize new designs of acyclic and cyclic molecules as mobile site, ion-selective, sensor materials which, with appropriate mediator solvents, provide improved sensor cocktails. This design feature is well illustrated by the continuing quest for a lithium ion-selective electrode compatible with the high levels of sodium interference in blood.     

Quantitation of soy-derived phytoestrogens in human breast tissue and biological fluids by high-performance liquid chromatography

A new and reliable HPLC method for the quantitation of daidzein, equol, and genistein in human breast tissue has been developed. The method was applied to biopsies from women undergoing breast reductions, who, prior to surgery, had ingested either a soy isoflavone preparation or a placebo tablet. The results were compared with data collected for urine and serum of the same subjects using standard methods. The limits of detection in the breast tissue homogenate were 24.7 nmol/l for daidzein, 148.0 nmol/l for equol, and 28.4 nmol/l for genistein (S/N of 3). The chromatographic limits of quantitation were 62.5 nmol/l for daidzein and genistein, and 125.0 nmol/l for equol, for which the accuracies were 86.0%, 83.6%, and 81.8%, respectively. The coefficients of variation of these measurements were all below 20% (11.1% for daidzein, 16.4% for genistein, and 13.2% for equol). The sample preparation comprised a concentration step and the absolute limits of quantitation were, therefore, 4.7 nmol/l, 18.8 nmol/l, and 0.94 nmol/l for daidzein and genistein, and 9.4 nmol/l, 37.5 nmol/l, and 1.9 nmol/l for equol in urine, serum, and breast tissue homogenate, respectively. Recoveries were between 70% (+/-5.6%) in breast tissue homogenate and 100% (+/-14.1%) in urine and serum for all three compounds. Equol (less than 1 micromol/l homogenate) was found to be the predominant phytoestrogen in breast tissue and its concentrations exceeded those in serum. The concentrations of phytoestrogens were at least 100-fold higher in urine than in serum and breast tissue.     

The determination of organophosphonate nerve agent metabolites in human urine by hydrophilic interaction liquid chromatography tandem mass spectrometry

A sensitive, robust isotope dilution LC/MS/MS method is presented for the quantitative analysis of human urine for the alkyl methylphosphonic acid metabolites of five organophosphorus nerve agents (VX, rVX or VR, GB or Sarin, GD or Soman, and GF or Cyclosarin). The selective sample preparation method employs non-bonded silica solid-phase extraction and is partially automated. While working with a mobile phase composition that enhances the electrospray ionization process, the hydrophilic interaction chromatography method results in a 5-min injection-to-injection cycle time, excellent peak shapes and adequate retention (k'=3.1). These factors lead to limits of detection for these metabolites as low as 30 pg/mL in a 1-mL sample of human urine. The quality control data (15 and 75 ng/mL) demonstrate accurate (-0.5 to +3.4%) and precise (coefficients of variation of 2.1-3.6%) quantitative results over the clinically relevant urine concentration range of 1-200 ng/mL for a validation set of 20 standard and quality control sets prepared by five analysts over 54 days. The selectivity of the method is demonstrated for a 100-individual reference range study, as well as the analysis of relevant biological samples. The combined sample preparation and analysis portions of this method have a throughput of 288 samples per day.     

Gas chromatographic determination of inorganic tin in rat urine after a single oral administration of stannous chloride and mono-, di-, and triphenyltin chloride

A method is described for the determination of inorganic tin by gas chromatography with flame photometric detection. The inorganic tins, stannous and stannic, were extracted with hydrochloric acid and n-hexane—benzene in the presence of 0.05% tropolone, and both inorganic tins were pentylated to tetrapentyltin with a Grignard reagent prior to gas chromatography. The absolute limit of detection for tetrapentyltin was 3 pg as tin. The recovery of stannous chloride added to rat urine samples was 80.2 ± 2.4% (mean ± S.D., n = 8). The application of this method to the study of urinary excretion of inorganic tin and organotin compounds in rats following oral administration of tin compounds is presented. The urinary excretion of tin compounds was observed over a period of 96 h following administration of stannous chloride or phenyltin compounds. Most of the inorganic tin was excreted into urine within 24 h after administration of stannous chloride. In the experiments on organotin administration, the level of the excretion as total tin for monophenyltin reached a maximum ca. 0–24 h after administration, whereas the maxima for di- and triphenyltin were found after 24–48 h and 48–72 h, respectively. The predominant excretion product of these tin compounds found in urine was monophenyltin.     

Determination of grepafloxacin in plasma and urine by a simple and rapid high-performance liquid chromatographic method

A rapid, specific, sensitive and economical method has been developed and validated for the determination of grepafloxacin in human plasma and urine. The assay consisted of reversed-phase HPLC with UV detection. Plasma proteins were removed by a fast and efficient procedure that has eliminated the need for costly extraction and evaporation. For the urine samples, the only required sample preparation was dilution. Separation was achieved on a reversed-phase TSK gel column with an isocratic mobile system. The method had a quantification limit of 0.05 μg/ml in plasma and 0.5 μg/ml in urine. The coefficients of variation (C.V.) were less than 4% for within- and between-day analyses. The method was successfully applied to a pharmacokinetic study, and was proved to be simple, fast and reproducible.     

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.     

Liquid chromatographic–tandem mass spectrometric method for the determination of the neuraminidase inhibitor zanamivir (GG167) in human serum

An LC–MS–MS method for the analysis of the neuraminidase inhibitor, zanamivir, in human serum is described. Zanamivir was extracted from protein precipitated human serum samples using Isolute SCX solid-phase extraction cartridges and analysed using reversed-phase chromatography with TurboIonSpray atmospheric pressure ionisation followed by mass spectrometric detection. The method uses a stable isotope internal standard, is highly specific and sensitive for a compound of this type and has been used for the analysis of human serum and urine samples from clinical studies. The method was extended to the analysis of serum and plasma samples from pre-clinical studies involving the rat, ferret and cell culture media. The method has been shown to be robust and valid over a concentration range of 10–5000 ng/ml using a 0.2-ml sample volume. The main advantages of this method compared to earlier procedures are primarily specificity, sensitivity, ease of sample preparation, small sample volume and short analysis time (ca. 5 min).     

The effect of tubular damage by mercuric chloride on kidney function and some urinary enzymes in the dog

Alkaline and acid phosphatases, β-glucosidase, β-galactosidase, N-acetyl-β-glucosaminidase and lactate dehydrogenase were monitored in the urine and serum of dogs with renal tubular damage induced by a series of increasing doses of mercuric chloride. Isocitrate dehydrogenase, glutamate oxaloacetate transaminase and glutamate pyruvate transaminase were assayed in the serum. The functional capacity of the kidney was determined by creatinine, inulin and p-aminohippurate (PAH) clearances and tubular maxima tests. Serum urea levels, total protein in the urine and the specific gravity of the urine were monitored throughout the study. The extent and location of the kidney damage was determined by histological investigation. Evidence is presented that the assay of urinary alkaline and acid phosphatase is the most sensitive method of detecting renal tubular damage in the dog. The clearance of [¹⁴C]-propranolol was compared before and after the administration of mercuric chloride. In the presence of tubular damage the blood half-life of propranolol and the rate of excretion of metabolites in the urine were increased.     

Time resolved secretion of chloride from a monolayer of mucin-secreting epithelial cells

Short-circuit current (Isc) measurement is used to quantify transepithelial ion flux. This technique provides a direct measure of net charge transport across a cell monolayer. Isc however, lacks chemical selectivity. Chemically resolved ion fluxes may be much greater than Isc, and differ in different biological processes. This work describes a novel experimental approach and deconvolution method to obtain temporally resolved ion fluxes at epithelial cell monolayers. HT29-Cl.16E cells, a sub clone of the human colonic cancer cell line HT29 was used as a model cell line to validate this approach in the context of epithelial transport studies. This cell line is known to secrete chloride in response to purinergic stimulation. Changes in chloride concentration after stimulation with 1 mM ATP plus 50 nM phorbol-myristate acetate (PMA) are recorded with a chloride ion-selective electrode (ISE) at a short distance (∼50 μm) from the monolayer. The recorded concentrations are transformed to corresponding chloride flux across the monolayer using a deconvolution algorithm for extracellular mass transport based on minimization of the shape error function (Nair and Gratzl in Anal Chem 77:2875–2888, 2005). Simultaneous voltage clamp yields the associated net electrical charge flux (Isc). The dynamics of Cl⁻ flux did correlate with that of the electrical flux, but was found to be greater in amplitude. This suggests that Cl⁻ may not be the only ion secreted. The method of simultaneously assessing ionic and electrical fluxes with a temporal resolution of seconds provides unique information about the dynamics of solute fluxes across the apical membrane. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Serum protein profiling by solid phase extraction and mass spectrometry: A future diagnostics tool?

Serum protein profiling by MS is a promising method for early detection of disease. Important characteristics for serum protein profiling are preanalytical factors, analytical reproducibility and high throughput. Problems related to preanalytical factors can be overcome by using standardized and rigorous sample collection and sample handling protocols. The sensitivity of the MS analysis relies on the quality of the sample; consequently, the blood sample preparation step is crucial to obtain pure and concentrated samples and enrichment of the proteins and peptides of interest. This review focuses on the serum sample preparation step prior to protein profiling by MALDI MS analysis, with particular focus on various SPE methods. The application of SPE techniques with different chromatographic properties such as RP, ion exchange, or affinity binding to isolate specific subsets of molecules (subproteomes) is advantageous for increasing resolution and sensitivity in the subsequent MS analysis. In addition, several of the SPE sample preparation methods are simple and scalable and have proven easy to automate for higher reproducibility and throughput, which is important in a clinical proteomics setting.     

Determination of urinary 5-hydroxyindole-3-acetic acid by high-performance liquid chromatography with electrochemical detection and direct sample injection.

A method for the routine quantitative determination of the major serotonin metabolite 5-hydroxyindole-3-acetic acid (5-HIAA) in urine is described. 5-HIAA was analyzed without prior sample cleanup, using an automated high-performance liquid chromatography system with isocratic elution and electrochemical detection (+0.60 V versus a Ag/AgCl reference electrode). The urine samples were mixed with a solution of the internal standard (5-hydroxyindole-3-propionic acid) and centrifuged. The supernatant was transferred to sealed glass vials, and a 2-microliters aliquot was injected directly onto a C18 reversed-phase analytical column, using an automatic sample injector. Samples of urine could be stored for several months at -80 or at +7 degrees C for 2 days without loss of 5-HIAA. However, a gradual decline with time occurred in crude samples stored at room temperature or above, as well as in urine samples diluted with the mobile phase. The detector response was linear in the range of 0-65 mumol/l 5-HIAA, and the intra- and interassay coefficients of variation were about 5 and 7%, respectively (n = 10).