Simultaneous determination of ammonia and urea with an asymmetric merging zones/flow-injection configuration

A method is proposed for the simultaneous determination of urea and ammonia using a reagent-injection configuration that includes a dual injection valve (for insertion of Nessler's reagent and for accommodating the enzyme reactor). The resolution of the two peaks obtained on each injection allows the determination of both analytes in mixtures. The determination range is 1–5 μg ml^?1 for ammonia and 1–6 μg ml^?1 for urea, with relative standard deviations of 1.13% and 2.31% for ammonia (first and second peaks) and 1.86% for urea.     

Determination of urea by ion chromatography with an immobilized urease reactor

An immobilized urease reactor can be used with ion chromatography for the simultaneous determination of urea, and sodium, potassium and ammonium ions. The conversion of urea to ammonium ion was found to be 76.5%. The calibration graph for urea was linear over the range 1 × 10^?5?1 × 10^?3 M (RSD 3%). The method was applied to human urine and a chemical fertilizer.     

Photometric Detection Inside the Stream of Sample Sheath Fluid

Abstract

Photometric detection with continuous feed of reagent into the centre of sample flow is described. Performance characteristics of this technique were tested at models without and with chemical reaction. Linear calibration curves were obtained for methylorange (5 x 10^?6 - 1 x 10^?4 M) and for ammonia reaction with the Nessler's reagent (6 x 10^?6 6 x 10^?4 M). The technique was applied for the determination of ammonia in drinking water. In this case, the preconcentration step was necessary.     

An enzyme reactor electrode for urea determinations.

An enzyme reactor electrode system for the determination of urea is described. A buffer is pumped through an enzyme reactor (0.4 ml) containing urease immobilized with glutaraldehyde to glass. The effluent is mixed with sodium hydroxide pumped through a second channel and fed through an ammonia gas electrode. Samples are introduced via a third flow channel and mixed with the buffer. The conversion of urea to ammonia is quantitative for sample concentrations of less than 0.03 M for a flow rate of 40 ml h^-1. The reactor electrode shows a Nernstian slope of 57 mV/decade for 5·10^-5–3·10^-2 M urea. The response is independent of variations in the flow rate, enzyme activity or temperature of the reactor.     

Optosensing at active surfaces — a new detection principle in flow injection analysis

Reflectance spectrophotometry is applied to flow-injection measurements of pH and the assays of ammonia and urea with the aim of demonstrating the principle and testing the performance of optosensors integrated into microconduits. A novel injection approach, the split-loop technique, is applied. For pH measurements, detection is based on commercial non-bleeding acid-base indicator papers situated in the flow stream at the tip of the fibre optic. Measurements of pH in the range 4–10 are possible at a rate of 120 h^?1. Special attention is given to the physiological pH range; the standard deviation is 0.004 at pH 7.2. For the determinations of ammonia and urea (via urease), a bromothymol blue stream is used with a miniature gas-diffusion device.     

Catalytic systems based on the organic nickel(ii) complexes in chronoamperometric determination of urea and creatinine

The organic nickel(ii) complexes with catalytic activity in the electrochemical oxidation of creatinine and urea were synthesized and studied. The signals of electrocatalytic oxidation of the studied carbonyl-containing amines in model solutions were obtained. The detection limit (by the 3σ-criterion) is 8.7·10^?6 and 2.7·10^?5 mol L^?1 for urea and creatinine, respectively.     

Preparation and Application of Urea Electrochemical Sensor Based on Chitosan Molecularly Imprinted Films

A novel urea electrochemical sensor was constructed based on chitosan molecularly imprinted films which were prepared by potentiostatic electrodeposition of chitosan in the presence of urea followed by eluting with 0.1 M KCl. Various techniques were carried out to investigate the formation of molecularly imprinted polymer (MIP) films and the performance of the sensor. According to our expectation, the urea MIP electrochemical sensor showed excellent selectivity to urea among the structural similarities and co‐existences, high linear sensitivity to urea in the range from 1.0×10^?8 to 4.0×10^?5 M with a detection limit of 5.0×10^?9 M. Furthermore, the recovery ranged from 96.3 % to 103.3 % and therefore offered great potential for clinical diagnosis applications.     

Decomposition of 8 mol·L<Superscript>−1</Superscript> Urea Solution at 298.15 K

Degradation of urea in 8 mol·L^?1 aqueous solution (20% w/w N) has been studied at 298.15?±?0.01 K over a time period of 150 days. The data were obtained by periodicaly measuring the electric conductivity, acidity, and concentrations of the main species of the solution, such as cyanate, ammonim carbonate and ammonium hydrogencarbonate. The concentration of un-ionized ammonia was calculated on the basis of the data for the total ammonia content in the solution.     

Polymerization of methyl methacrylate by a charge transfer mechanism with urea and iron (III) complex

Methyl methacrylate (MMA) can be polymerized by a charge transfer complex formed by the interaction of urea, methyl methacrylate, and carbon tetrachloride (CCl₄) in a nonaqueous solvent like dimethylsulfoxide (DMSO). The rate of polymerization can be accelerated by Lewis acids like Fe³⁺. This article reports the polymerization of MMA initiated by urea and CCl₄ and accelerated with hexakisdimethylsulfoxide iron (III) perchlorate, [Fe(DMSO)₆](ClO₄)₃, and A at 60°C. Definite induction periods were observed for the polymerization reaction initiated by urea and CCl₄ alone, but the induction period completely vanished when the molar ratio of urea to A reached 6:1. The molecular weights of the polymers with 6:1 molar ratio of urea to A were higher than with urea alone. The rate constant for the polymerization of MMA in the presence of [Fe(urea)₆]³⁺ was 1.03 × 10^?5 1 mol^?1 s^?1 at 60°C. The transfer constant for CCl₄ for polymerization with urea alone is 2.43 × 10^?3 at 60°C.     

Capillary Electrophoresis as A Diagnostic Tool: Determination of Biological Constituents Present in Urine of Normal and Pathological Individuals

Abstract

A quantitative ultraviolet detection method for the determination of urinary metabolites is described using capillary zone electrophoresis. The determination of these metabolites is simple, fast. reproducible and utilizes very small amounts of sample. This method is linear between 1.0 × 10^?4 and 1.0 × 10^?2 M for creatinine and between 1.0 × 10^?1 and 1.0 M for urea. The ultraviolet method shows detection limits for creatinine in the picogram (femtomol) range, and for urea in the nanogram (picomol) range.     

Flow injection analysis for glucose and urea with enzyme reactors and on-line dialysis

A flow injection system for glucose and urea determination is described. The glucose determination uses immobilized glucose oxidase in a reactor designed to give 100% substrate conversion. The hydrogen peroxide formed is converted to a coloured complex with 4-aminophenazone and N,N-dimethylaniline. The coupling is catalysed by a reactor containing immobilized peroxidase. The coloured complex is measured in a flow-through spectrophotometric cell. Urea is converted to ammonia in a reactor with immobilized urease and detected with an ammonia gas membrane electrode. Proteins and other interfering species from serum samples are removed in an on-line dialyzer. Calibration curves are linear for glucose in the range 1.6 × 10^-4–1.6 × 10^-2 M and for urea in the range 10^-4–10^-1 M. The samples are 25 μl for glucose determination and 100 μl for urea determination. Linear ranges can be changed by varying the sample sizes. The effects of the dialyser, enzyme reactors and detectors on dispersion are evaluated.     

Acute kidney injury caused by the intraperitoneal injection of Bothrops jararaca venom in rats

Abstract

We examined the ability of Bothrops jararaca venom (12.5?mg/kg) injected intraperitoneally (i.p.) to cause acute kidney injury (AKI) in rats. Blood urea and creatinine (AKI biomarkers, in g dL^?1) were elevated after 2?h in venom-treated rats (urea: from 0.41?±?0.1 to 0.7?±?0.03; creatinine from 46.7?±?3.1 to 85?±?6.7; p?<?0.05; n?=?3 each), with no change in circulating reduced glutathione. Venom-treated rats survived for ～6?h, at which point platelets were reduced (×10³ µL^?1; from 763.8?±?30.2 to 52.5?±?18.2) whereas leukocytes and erythrocytes were slightly increased (from 4.7?±?0.3 to 6.6?±?0.1?×?10³?µL^?1 and from 8.38?±?0.1 to 9.2?±?0.09?×?10⁶?µL^?1, respectively; p?<?0.05); blood protein (5.2?±?0.4?g dL^?1) and albumin (2.7?±?0.1?g dL^?1) were normal, whereas blood and urinary urea and creatinine were increased. All parameters returned to normal with antivenom given 2?h post-envenomation. The i.p. injection of venom caused AKI similar to that seen with other routes of administration.     

Rate of hydrolysis of Na4P2O7 and Na5P3O10 at 100°C and the effect of urea

³¹P NMR analysis has been used to measure the rates of hydrolysis of Na₄P₂O₇ and Na₅P₃O₁₀ at 100°; the rate constants are 6.07 x 10^?3 and 2.24 x 10^?1 hr^?1 respectively. The presence of urea has a catalytic effect on the former but an inhibiting effect on the latter. These observations are explained by the hydrogen-bonding capabilities of urea.     

The electron—ion recombination coefficient in CO2 and NH3. Deviations from a linear density dependence at elevated pressures

The rate coefficient for electron—ion recombination at 292 K rises to a value of 7 x 10^?5 cm³ s^?1 in CO₂ at 13 x 10¹⁹ molecule cm^?3, but is non-linear with density above 8 x 10¹⁹ molecule cm^?3. In ammonia it passes through a definite maximum of 7 x 10^?5 cm³ s^?1 at 2.4 x 10¹⁹ molecule cm^?3     

Determination of Ammonia in Water Using Flow Injection Analysis with Automatic Pervaporation Enrichment

Abstract

An automated ammonia monitoring system has been developed by putting a pervaporation unit in an enrichment cycle used in flow injection analysis mode. In the proposed system, an enrichment cycle was equipped to enable the adjustment for the measuring range of ammonium by controlling the duration of the enrichment circulation. Therefore, the system was capable to determine ammonia in both the surface water with low ammonia concentration and the ammonia-rich wastewater with the linear dynamic range of 0.05–15 mg l^?1 and 15–50 mg l^?1, respectively. The relative standard deviations were less than 1.9% and the quantification limit is as low as 0.03 mg l^?1. The sampling frequency is 8–10 h^?1.     

Determination of creatinine with a sensor based on immobilized glutamate dehydrogenase and creatinine deiminase

Glutamate dehydrogenase and creatinine deiminase are immobilized by adsorption on wet poly(vinyl chloride) membranes. Creatinine is determined by a sensor consisting of the two membranes placed over an ammonia-sensing electrode. Endogenous ammonia is removed as it passes through the glutamate dehydrogenase layer. Creatinine (1–50 mg dl^?1) is converted to ammonia in the inner creatinine deiminase layer and is detected by the ammonia electrode. The assay requires 3 min, the minimum detectable concentration is 1 mg dl^?1 at pH 8.5, and the precision is ca. 5%. Endogenous ammonia can be tolerated up to 2 × 10^?4 M.     

Bestimmung kleiner Nitrit- und Nitratkonzentrationen in wässrigen Ammoniaklösungen

The optimum conditions have been established for the spectrophotometric determination of nitrite with procaine and α-naphthylamine, for the range 10^?6–10^?2M, and of nitrate with chromotropic acid in the range 10^?5–10^?2M, both in aqueous solutions of ammonia at concentrations up to 16M. Both methods have been investigated and the results checked by statistical analysis. The procedures for the determinations are described.     

Construction of an immobilized asparaginase sensor and determination of asparagine and asparaginase in human blood serum

The sensor is based on asparaginase held on an ammonia gas sensor. Asparagine in the range 2.0 X 10^?5?2.3 X 10^?3 M gives a linear calibration graph with response times of 5?2 min. Asparagine can be determined in human serum. Asparaginase (0.01?0.2 U in 0.1 ml of sample) is determined in aqueous solution or serum by adding asparagine to the sample, and measuring the ammonia evolved. Results for both methods agree well with those obtained by the combined Conway—Russell method.     

Fluorimetric determination of trace hydrogen peroxide in water with a flow injection system

A fluorimetric flow-injection procedure with a single reagent solution containing p-hydroxyphenylacetic acid, peroxidase and ammonia permits the determination of aqueous hydrogen peroxide in the range 10^?8?10^?4 M; 30–60 samples can be processed per hour. The method exhibits a wide linear range and is insensitive to sample pH within the range 2–6.     

The application of strongly reducing agents in flow injection analysis : Part 3. Vanadium(II)

The application of vanadium(II) as a powerful reducing reagent in flow injection analysis is described. Results are presented for the determination of various organic and inorganic substances. With spectrophotometric detection, based on the absorption by vanadium(II)-EDTA at 350 nm, limits of determination were about 5 X 10^?5 mol 1^?1. Nitrate, nitrite and hydroxylamine were measured with amperometric detection. The limit of determination was about the same as with spectrophotometric detection. In a slightly acidic medium, hydrazine could be determined with the amperometric detector, with a limit of determination of about 10^?4 mol l^?1. By coupling an ammonia detection device to the reduction system, the percentage conversions of nitrate, nitrite and hydroxylamine to ammonia were shown to be 26%, 54% and 47%, respectively.