Enzyme electrode for urea with amperometric indication: Electrode with diffusional limitation

Urea can be determined amperometrically with an enzyme electrode consisting of urease trapped in a poly(vinyl alcohol) gel and confined by a dialysis membrane. A pH-dependent hydrazine oxidation at a platinum anode is used as the detector reaction. The current is a linear function of the urea sample concentration over the range 1–80 mM with 50-μl samples injected into 2 ml of hydrazine buffer in the cell. With enzyme loadings above 20 U cm^-2, the current became limited by the rate of mass transfer in the membrane arrangement. Forty samples per hour could be analyzed with negligible carry-over when the time derivative was used for quantitation.     

Potentiometric Biosensor System Based on Recombinant Urease and Creatinine Deiminase for Urea and Creatinine Determination in Blood Dialysate and Serum

A biosensor system for simultaneous determination of creatinine and urea in blood serum and dialysate samples was developed. It consisted of creatinine and urea biosensors based on a potentiometric transducers with two identical pH‐sensitive field‐effect transistors. In creatinine biosensor, creatinine deiminase immobilized via photopolymerization in PVA/SbQ polymer on one transistor served as a biorecognition element, while bovine serum albumin in PVA/SbQ polymer placed on the second transistor was used for reference. The urea biosensor was created in the same way but recombinant urease was used instead of creatinine deiminase. The linear ranges of creatinine and urea measurement were 0.02–2 mM and 0.5–15 mM, correspondingly, which allowed simultaneous determination of the metabolites. Response time of the biosensor system was 2–3 min; RSD of responses did not exceeded 5 %. The biosensors demonstrated absence of non‐selective response towards components of blood dialysate and serum. Urea and creatinine concentrations were determined in 20 samples of blood dialysate and serum. The results correlated well with traditional methods of analysis. Creatinine and urea biosensors were stable during five months of storage (during this time the responses decreased by about 10 %). The proposed biosensor system can be effectively used for analysis of serum samples and for hemodialysis control.     

Chronocoulometric determination of urea in human serum using an inkjet printed biosensor

A biosensor for the determination of urea in human serum was fabricated using a combination of inkjet printed polyaniline nanoparticles and inkjet printed urease enzyme deposited sequentially onto screen-printed carbon paste electrodes. Chronocoulometry was used to measure the decomposition of urea via the doping of ammonium at the polyaniline-modified electrode surface at -0.3 V vs. Ag/AgCl. Ammonium could be measured in the range from 0.1 to 100 mM. Urea could be measured by the sensor in the range of 2-12 mM (r(2)=0.98). The enzyme biosensor was correlated against a spectrophotometric assay for urea in 15 normal human serum samples which yielded a correlation coefficient of 0.85. Bland-Altman plots showed that in the range of 5.8-6.6 mM urea, the developed sensor had an average positive experimental bias of 0.12 mM (<2% RSD) over the reference method.     

A specific enzyme electrode for urea

A truly specific, simple enzyme electrode is described for the assay of urea in blood serum. The sensor used is the newly developed air-gap electrode of R??i?ka and Hansen, and has advantages of speed of response and specificity over earlier enzyme electrodes for urea. Potassium, sodium and ammonium ions and other organic and inorganic species present in blood do not interfere. Linear curves are obtained from 2 · 10^-2M to 1 · 10^-4M urea with slopes close to Nernstian (about 0.90 pH/decade). Urea in blood was assayed with an accuracy of 2.2% and a precision of 2.0% with immobilized urease; only 3–5 min is required per assay. The electrode was used for a month and almost 500 assays with excellent results. Since the sensor never touches the sample solution, problems caused by blood components which block membrane pores are avoided.     

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.     

Utilization of adsorption-immobilized urease in gas-diffusion flow injection

A gas-diffusion flow-injection system for the assay of urea is reported. Urea is enzymatically converted to ammonia, which is determined spectrophotometrically by detecting the change in absorbance of a mixed pH indicator. The enzyme is immobilized by addition of perfluoroalkyl chains to the free amine groups of the enzyme and then adsorption of this modified enzyme on a polytetrafluoroethylene gas-diffusion membrane. The method is applicable in the range 0.1–500 mM urea. The procedure was used in comparison assays using blood serum samples.     

Enzyme coated glass pH-electrode: Its fabrication and applications in the determination of urea in blood samples

A new enzyme coated electrode for the determination of urea in blood samples has been developed. It is based on the encapsulation of urease enzyme in the porous silicate matrix by the sol-gel technique on a glass electrode for the purpose of sensing urea in blood samples. Various parameters like the effect of pH, selection of a suitable buffer of appropriate concentration and interference of common substances in blood samples have been evaluated to optimize the conditions for the determination of urea. The electrode can be used for the determination of urea in the concentration range 0.03-30.0 mM in a solution. The detection limit of the present enzyme-coated electrode is found to be 52 μg/ml of urea. The relative standard deviation for the electrode-to-electrode reproducibility is found to be 2.4% for the determination of 0.1 mM of urea (six replicate electrodes). Sol-gel matrix containing immobilized enzyme was stable for about 25 days at ∼4 °C with 80% urease activity. Urea content in various clinical blood samples has been estimated using this electrode and the results are found to be in good agreement with the standard clinical methods as reported in the literature.     

Part I. A specific electrode for urea.

A specific simple enzyme stirrer electrode is described for the assay of urea in blood serum. The enzyme is placed directly on a magnetic stirrer and held in place with a nylon net. The enzyme stirrer both stirs the solution and effects an enzymatic transformation, permitting the direct assay of a substrate such as urea. Potassium, Na⁺ , NH₄⁺ and other organic and inorganic species present in blood do not interfere. Linear curves are obtained from 5· 10^-2M to 1· 10^-4M urea with slopes close to Nernstian, 0.95 pH/decade. Urea in blood was assayed with an accuracy of 1.8% and a precision of 2.0% with immobilized urease in the stirrer. The stirrers were used for 15 weeks and over 500 assays with excellent results.     

Array of potentiometric sensors for simultaneous analysis of urea and potassium

Urea biosensors based on urease immobilized by crosslinking with BSA and glutharaldehyde coupled to ammonium ion-selective electrodes were included in arrays together with potassium, sodium and ammonium PVC membrane ion-selective electrodes. Multivariate calibration models based on PCR and PLS2 were built and tested for the simultaneous determination of urea and potassium. The results show that it is possible to obtain PCR and PLS2 calibration models for simultaneous determination of these two species, based on a very small set of calibration samples (nine samples). Coupling of biosensors with ion-selective electrodes in arrays of sensors raises a few problems related to the limited stability of response and unidirectional cross-talk of the biosensors, and this matter was also subjected to investigation in this work. Up to three identical urea biosensors were included in the arrays, and the data analysis procedure allowed the assessment of the relative performance of the sensors. The results show that at least two urea biosensors should be included in the array to improve urea determination. The prediction errors of the concentration of urea and potassium in the blood serum samples analyzed with this array and a PLS2 calibration model, based on nine calibration samples, were lower than 10 and 5%, respectively.     

Analysis of Urea Nitrogen in the Presence of Ammonia Using an Ammonia Gas Sensitive Electrode

Abstract

This report describes a method for the determination of ammonia and urea in raw sewage samples using an Orion Ammonia Gas-Sensing Electrode. Urea is determined by potentiometrically measuring the ammonia produced following exhaustive hydrolysis by urease and subtracting the amount of ammonia present before enzymatic hydrolysis. The recovery of urea from raw sewage samples using the procedure herein described is shown to be nearly Quantitative.     

Enzymatic determination of urea in undiluted whole blood by flow injection analysis using an ammonium ion-selective electrode

A flow-injection system is described for the assay of urea in undiluted whole blood. Urea is quantified by means of an ammonium ion-selective electrode covered with a membrane with covalently immobilized urease. The enzymatically generated ammonium ion is directly related to the urea concentration. Interference from potassium is reduced by adjusting the potassium ion concentration in the carrier stream and in the aqueous calibration solutions to 4.0 mM; it can be eliminated by measuring the potassium ion concentration in the sample separately and applying a mathematical correction for the K⁺ contribution to the signal. The linear measuring range is 1–40 mM urea, with an injection frequency of 40 h^?1 and a standard deviation of 1% for whole blood samples. The result of the measurement is obtained within 25 s from the time of injection. Vatiations in the hematocrit level of the sample have no effect on the measurement. The results obtained by the flow-injection method are in excellent agreement with those found routinely at a local hospital. The sensor is stable for more than 25 days.     

A urea-sensing membrane electrode for whole blood measurements

The construction and properties of a new urea-sensing membrane electrode capable of making direct urea measurements in whole blood are described. The electrode has a layered structure in which a small quantity of EDTA-stabilized urease enzyme solution is held between an external dialysis membrane and the gas-permeable membrane of a conventional ammonia selective electrode. It is shown that the electrode functions reliably in whole blood samples, used with minimal pretreatment, as well as in serum or aqueous solutions. The range, dynamic response, lifetime, precision, and accuracy of the electrode system are appropriate for clinical measurements in whole blood or serum, and promise to simplify such analyses with an attendant reduction in costs.     

New Urea Biosensor Based on Urease Enzyme Obtained from Helycobacter pylori

The urease enzyme of Helicobacter pylori was isolated from biopsy sample obtained from antrum big curvature cell extracts. A new urea biosensor was prepared by immobilizing urease enzyme isolated from Helicobacter pylori on poly(vinylchloride) (PVC) ammonium membrane electrode by using nonactine as an ammonium ionophore. The effect of pH, buffer concentration, and temperature for the biosensor prepared with urease from H. pylori were obtained as 6.0, 5 mM, and 25 °C, respectively. We also investigated urease concentration, stirring rate, and enzyme immobilization procedures in response to urea of the enzyme electrode. The linear working range of the biosensor extends from 1 × 10(-5) to 1 × 10(-2) M and they showed an apparent Nernstian response within this range. Urea enzyme electrodes prepared with urease enzymes obtained from H. pylori and Jack bean based on PVC membrane ammonium-selective electrode showed very good analytical parameters: high sensitivity, dynamic stability over 2 months with less decrease of sensitivity, response time 1-2 min. The analytical characteristics were investigated and were compared those of the urea biosensor prepared with urease enzyme isolated from Jack bean prepared at the same conditions. It was observed that rapid determinations of human serum urea amounts were also made possible with both biosensors.     

Enzymatic flow-injection determination of urea in blood serum using potentiometric gas sensor with internal nonactin based ISE

Ion-selective electrode with cellulose triacetate membrane containing nonactin is employed for the potentiometric detection of ammonia produced in biocatalytic reaction in flow-injection system with enzyme reactor. The elimination of interferences occurring in the presence of alkali metal ions was achieved by covering a nonactin membrane with outer hydrophobic gas permeable membrane. The obtained flow-injection response to ammonia indicates a possibility of ammonia determination down to 10 microM ammonia. In the flow-injection system for urea determination 200 microl of 10-fold diluted blood serum sample was injected into carrier stream of distilled water merged with TRIS buffer, passed through the urease flow-through reactor and then after merging with NaOH stream delivered to the detector. It was found in several series of natural blood serum samples, that the correction for endogenous ammonia in such a determination is not indispensable.     

Advances in photolithographically fabricated ENFET membranes

A photolithographically fabricated membrane for enzyme immobilisation based on an Ion Sensitive Field Effect Transistor (ISFET) is described. The preparation of an Enzyme-FET (ENFET) containing urease was successful. The ENFET has been used for the determination of urea and pesticides; this depends on the chosen enzyme level in the membrane and can be employed in a flow-injection system. The urea sensitive sensor (high enzyme load) has a wide linear range (1–500 mmol/l) a fast response (t₉₅=20 s) and a lifetime greater than 30 days. The application of this sensor to the determination of urea in the waste water from a fertilizer plant and in blood serum is discussed. The second sensor (low enzyme level) was able to detect pesticides in water based on the inhibition of urease. The detection limit was found to be 0.1 µg/l for Carbofuran (10 minutes incubation time, without preconcentration).     

Spectrophotometric flow-injection determination of urea in body fluids by using an immobilized urease reactor

A flow system involving a packed-bed enzyme reactor (volume 180 μl) with urease immobilized covalently on poly(glycidyl methacrylate)-coated porous glass is used for determining urea in blood serum and urine. Enzymatically produced ammonia is converted to an indophenolate dye (by oxidative coupling with hypochlorite and sodium salicylate), which is detected spectrophotometrically at 700 nm. The calibration graph is rectilinear for 25–500 μM urea when injecting samples (75 μl) diluted 1:50 for serum or 1:1000 for urine at a frequency of 60 h^?1; the relative standard deviation is 1.1% for ten injections of 300 μM urea. The immobilized urease is stabilized by the addition of disodium EDTA, sodium azide and 2-mercaptoethanol to a 0.2 M phosphate buffer (pH 6.9) used as the carrier stream, which serves also as a preservative for longterm storage of the urease reactor packing at 4°C.     

Determination of urea in serum by a fiber-optic fluorescence biosensor

A new fiber-optic biosensor for urea has been developed, based on immobilized urease coupled to a fluorescence ammonia sensor. The enzymatically generated ammonia diffuses through the membrane into a solution of the fluorescent pH indicator trisodium 8-hydroxypyrene-1,3,6-trisulfonate. The sensor has been successfully used for the determination of urea in serum samples, with results in good agreement with those reported by a local hospital. The proposed sensor is reversible and selective to urea. The ease of construction of the sensor tip offers the possibility of designing disposable tips for use in clinical applications.     

Enzymatic analysis by means of the air-gap electrode determination of urea in blood

The newly developed air-gap electrode has been used for enzymatic assay of urea in serum and whole blood; analyses can be done accurately, reliably, simply and quickly. The determination is highly selective because the electrode senses only the ammonium ion, which is selectively released from urea by urease in a preliminary rapid incubation step. The reproducibility of the determination (standard deviation less than 2.4%) is sufficient for clinical purposes; the linear range of the method is 10^-2–lO^-4M urea. Since the electrode actually never touches the sample solution, the problems caused by the presence of proteins, blood cells etc. do not arise.     

Development of a Urea Bioprobe Based on Platinized Boron‐Doped Diamond Electrodes

Urea (CH₆ON₂) is one of the main human nitrogen‐based metabolic wastes. The concentration of urea in blood lies between 2.5–7 mM for healthy individuals, and is commonly used as an indicator for several diseases that may alter this value. Spectrophotometric methods are employed for the determination of blood urea concentration during clinical assays. Although these methods are sensitive, they make use of toxic reagents and complex reaction schemes. Therefore, in this research we present the bioelectrochemical determination of urea by the use of the protein urease (E.C.3.1.1.5) along with a nano‐platinized boron‐doped diamond electrode. This approach has been proven to be efficient and sensitive providing a platform with detection limits of 1.79 mM (S/N=3). The linear range resulted from 1 mM to 25 mM for the determination of urea, and response time of five minutes.     

Use of CdSe/ZnS luminescent quantum dots incorporated within sol-gel matrix for urea detection

In this work, urea detection techniques based on the pH sensitivity of CdSe/ZnS QDs were developed using three types of sol-gel membranes: a QD-entrapped membrane, urease-immobilized membrane and double layer consisting of a QD-entrapped membrane and urease-immobilized membrane. The surface morphology of the sol-gel membranes deposited on the wells in a 24-well microtiter plate was investigated. The linear detection range of urea was in the range of 0-10 mM with the three types of sol-gel membranes. The urea detection technique based on the double layer consisting of the QD-entrapped membrane and urease-immobilized membrane resulted in the highest sensitivity to urea due to the Michaelis-Menten kinetic parameters. That is, the Michaelis-Menten constant (K_m =2.0745 mM) of the free urease in the QD-entrapped membrane was about 4-fold higher than that (K_m =0.549 mM) of the immobilized urease in the urease-immobilized membrane and about 12-fold higher than that (K_m =0.1698 mM) of the immobilized urease in the double layer. The good stability of the three sol-gel membranes for urea sensing over 2 months showed that the use of sol-gel membranes immobilized with QDs or an enzyme is suitable for biomedical and environmental applications.