Preparation and recognition performance of creatinine-imprinted material prepared with novel surface-imprinting technique

By adopting the novel surface molecular imprinting technique put forward by us not long ago, a creatinine molecule-imprinted material with high performance was prepared. The functional macromolecule polymethacrylic acid (PMAA) was first grafted on the surfaces of micron-sized silica gel particles in the manner of “grafting from” using 3-methacryloxypropyltrimethoxysilane (MPS) as intermedia, resulting in the grafted particles PMAA/SiO₂. Subsequently, the molecular imprinting was carried out towards the grafted macromolecule PMAA using creatinine as template and with ethylene glycol diglycidyl ether (EGGE) as crosslinker by right of the intermolecular hydrogen bonding and electrostatic interaction between the grafted PMAA and creatinine molecules. Finally, the creatinine-imprinted material MIP-PMAA/SiO₂ was obtained. The binding character of MIP-PMAA/SiO₂ for creatinine was investigated in depth with both batch and column methods and using N-hydroxysuccinimide and creatine as two contrast substances, whose chemical structures are similar to creatinine to a certain degree. The experimental results show that the surface-imprinted material MIP-PMAA/SiO₂ has excellent binding affinity and high recognition selectivity for creatinine. Before imprinting, PMAA/SiO₂ particles nearly has not recognition selectivity for creatinine, and the selectivity coefficients of PMAA/SiO₂ for creatinine relative to N-hydroxysuccinimide and creatine are only 1.23 and 1.30, respectively. However, after imprinting, the selectivity coefficients of MIP-PMAA/SiO₂ for creatinine in respect to N-hydroxysuccinimide and creatine are remarkably enhanced to 11.64 and 12.87, respectively, displaying the excellent recognition selectivity and binding affinity towards creatinine molecules.     

Measurement of serum creatinine--current status and future goals

The first methods for the measurement of creatinine in serum and plasma were published over a century ago. Today, the Jaffe reaction using alkaline picrate remains the cornerstone of most current routine methods, after continuous refinements attempting to overcome inherent analytical interferences and limitations. With the recent introduction of the reporting of estimated glomerular filtration rate (eGFR), inter-laboratory agreement of serum creatinine results has become an important international priority. Expert professional bodies have recommended that all creatinine methods should become traceable to a reference method based on isotope dilution-mass spectrometry (IDMS).It is important that clinical biochemists have a good understanding of the relative performance of routine creatinine methods. Using a new commutable IDMS-traceable reference material (SRM 967), and a validated tandem IDMS assay developed in our laboratory, we assessed the accuracy of nine routine creatinine methods with assistance from other laboratories in our region. Three methods appeared to have patient sample bias that exceeded 5% in the range of creatinine concentrations where eGFR estimations are most important.Companies are currently recalibrating their creatinine assays. This task should be complete in 2007, and then creatinine results for eGFR calculations will require the use of a modified eGFR equation. Laboratories considering calibration changes before this time can seek advice from the Australasian Creatinine Working Group.     

Evaluation of two alternative metabolic pathways for creatinine degradation in microorganisms

The microbial decomposition of creatinine was found to proceed mainly via N-methylhydantoin or creatine as the first degradation product. Either N-methylhydantoin or urea or both were detected as metabolites derived from creatinine in various microorganisms, and creatinine deiminase and creatinine amidohydrolase activities were detected concomitantly. N-Methylhydantoin hydrolase and N-carbamoylsarcosine amidohydrolase were found to be formed inducibly in the presence of creatinine or N-methylhydantoin. Three microorganisms which decompose creatinine in different ways were screened from soil. Pseudomonas putida 77 rapidly metabolized creatinine solely via N-methylhydantoin. Degradation of creatinine proceeded with both creatine and N-methylhydantoin as the first degradation products at the same time in Pseudomonas sp. H21. Pseudomonas sp. 0114 was found to metabolize creatinine mainly via creatine and to also metabolize N-methylhydantoin. Changes in the metabolites of creatinine during a cultivation or enzyme reaction were found to be closely related to the enzyme activities of interest which are regulated by creatinine or N-methylhydantoin in different ways depending on the microbial strain.     

A role for the organic anion transporter OAT3 in renal creatinine secretion in mice

Tubular secretion of the organic cation, creatinine, limits its value as a marker of glomerular filtration rate (GFR) but the molecular determinants of this pathway are unclear. The organic anion transporters, OAT1 and OAT3, are expressed on the basolateral membrane of the proximal tubule and transport organic anions but also neutral compounds and cations. Here, we demonstrate specific uptake of creatinine into mouse mOat1- and mOat3-microinjected Xenopus laevis oocytes at a concentration of 10 μM (i.e., similar to physiological plasma levels), which was inhibited by both probenecid and cimetidine, prototypical competitive inhibitors of organic anion and cation transporters, respectively. Renal creatinine clearance was consistently greater than inulin clearance (as a measure of GFR) in wild-type (WT) mice but not in mice lacking OAT1 (Oat1-/-) and OAT3 (Oat3-/-). WT mice presented renal creatinine net secretion (0.23 ± 0.03 μg/min) which represented 45 ± 6% of total renal creatinine excretion. Mean values for renal creatinine net secretion and renal creatinine secretion fraction were not different from zero in Oat1-/- (-0.03 ± 0.10 μg/min; -3 ± 18%) and Oat3-/- (0.01 ± 0.06 μg/min; -6 ± 19%), with greater variability in Oat1-/-. Expression of OAT3 protein in the renal membranes of Oat1-/- mice was reduced to ～6% of WT levels, and that of OAT1 in Oat3-/- mice to ～60%, possibly as a consequence of the genes for Oat1 and Oat3 having adjacent chromosomal locations. Plasma creatinine concentrations of Oat3-/- were elevated in clearance studies under anesthesia but not following brief isoflurane anesthesia, indicating that the former condition enhanced the quantitative contribution of OAT3 for renal creatinine secretion. The results are consistent with a contribution of OAT3 and possibly OAT1 to renal creatinine secretion in mice.     

Glomerular filtration rate and blood pressure monitoring in awake baboons

Minimally invasive techniques were used to collect urine with an external catheter together with automated intermittent monitoring of arterial blood pressure in awake male baboons. Using endogenous creatinine, 24-hour creatinine clearances were measured for 2 to 3 consecutive days in four intact and in four uninephrectomized baboons. Despite large differences in urinary volume and sodium excretion, reproducibility of 24-hour creatinine clearances was within 15% in 15 of 19 studies obtained from 6 of 8 animals. Arterial blood pressure was monitored intermittently at 30 to 60 minute intervals over 24 hours with a Dinamap monitor and recorder. Mean blood pressure averaged 71 +/- 4.4 to 89 +/- 5.5 mm Hg in different animals. Blood pressure tended to be lower at night than during the day. In separate studies using 15 to 60 minute urine collection periods, inulin clearance was compared in awake and in anesthetized animals with endogenous or exogenous creatinine clearance measured simultaneously. The clearance of creatinine systematically exceeded the clearance of inulin, even in intact animals with a normal serum creatinine. The creatinine-to-inulin clearance ratio averaged 1.16 +/- 0.03 at a serum concentration of 0.7 to 0.8 mg/dl; 1.27 +/- 0.03 at a serum creatinine of 1.0 to 1.1 mg/dl and 1.56 +/- 0.04 at a serum creatinine greater than 10 mg/dl. All values exceed unity significantly (p less than 0.001). Thus, renal function, including inulin clearance, can be measured in awake baboons. Duplicate or triplicate 24-hour urine collections are needed to assess the reliability of creatinine excretion. However, creatinine clearance overestimates glomerular filtration rate, as it does in humans.     

Certified reference materials (GBW09170 and 09171) of creatinine in human serum

Creatinine is the most widely used clinical marker for assessing renal function. Concentrations of creatinine in human serum need to be carefully checked in order to ensure accurate diagnosis of renal function. Therefore, development of certified reference materials (CRMs) of creatinine in serum is of increasing importance. In this study, two new CRMs (Nos. GBW09170 and 09171) for creatinine in human serum have been developed. They were prepared with mixtures of several dozens of healthy people's and kidney disease patient's serum, respectively. The certified values of 8.10, 34.1 mg/kg for these two CRMs have been assigned by liquid chromatography-isotope dilution mass spectrometry (LC-IDMS) method which was validated by using standard reference material (SRM) of SRM909b (a reference material obtained from National Institute of Standards and Technology, NIST). The expanded uncertainties of certified values for low and high concentrations were estimated to be 1.2 and 1.1%, respectively. The certified values were further confirmed by an international intercomparison for the determination of creatinine in human serum (Consultative Committee for Amount of Substance, CCQM) of K80 (CCQM-K80). These new CRMs of creatinine in human serum pool are totally native without additional creatinine spiked for enrichment. These new CRMs are capable of validating routine clinical methods for ensuring accuracy, reliability and comparability of analytical results from different clinical laboratories. They can also be used for instrument validation, development of secondary reference materials, and evaluating the accuracy of high order clinical methods for the determination of creatinine in human serum.     

High-performance liquid chromatographic determination of glyoxal and methylglyoxal in urine by prederivatization to lumazinic rings using in serial fast scan fluorimetric and diode array detectors

Glyoxal and methylglyoxal are two important markers of oxidative stress and both are involved in the evaluation of several diseases. A new HPLC method for determining glyoxal and methylglyoxal in urine was developed. The method is based on the reaction of alpha-dialdehydes, glyoxal and methylglyoxal, with 5,6-diamino-2,4-hydroxypyrimidine sulfate in basic medium to form highly fluorescent lumazine derivatives. Creatinine was also included in the method even though it does not react with the reagent. The derivatives and creatinine are separated on a C(18) reversed-phase column with a mobile phase consisting of acetonitrile:citrate buffer, pH 6.0 (3:97 v/v). The flow rate was 1.0mLmin(-1) and the effluent was monitored photometrically at 250 nm for determination of creatinine and fluorimetrically at 500 nm (exciting at 330 nm) for determination of glyoxal and methylglyoxal derivatives. Recording time of the separation is less than 10 min. Determination of the analytes is performed in urine after incubation of the sample, with the reagent in alkaline medium, for 30 min at 60 degrees C. Urinary levels of glyoxal and methylglyoxal, expressed as glyoxal/creatinine and methylglyoxal/creatinine ratios, in healthy young women and men were determined. For women, values of 0.80+/-0.37 and 0.60+/-0.22 microg/mg of creatinine were found for glyoxal and methylglyoxal, respectively. For men, values of 0.63+/-0.15 and 0.49+/-0.05 microg/mg of creatinine were found for glyoxal and methylglyoxal, respectively. These results were also related to the body mass index of each individual.     

CREATININE CLEARANCE IN CLINICAL MEDICINE

Clearance of endogenous creatinine offers a reliable clinical means of determining quantitative renal damage. The rate of clearance (Ccr) is obtained by relating the amount of creatinine filtered by the glomerulus per unit of time to the concentration of creatinine in the serum. The technic is simple and practical for routine use.Since 1948, the creatinine clearance determination has been used extensively at the University of California Medical Center for the evaluation of renal function. The present report reviews our selected experience with this procedure during the past 14 years. Clinical examples are used to show that the Ccr is a more accurate index of glomerular filtration than the concentration of any of the nonprotein nitrogen components of the blood.     

Human urinary epidermal growth factor: effects of age, sex and pregnancy

Urinary concentrations of immunoreactive human epidermal growth factor (hEGF) were determined by specific homologous radioimmunoassay in 169 healthy men (aged 20-69 years), 275 healthy women (20-8 years). healthy women (20-68 years) and 413 pregnant women (20-39 years). Relative hEGF concentrations in urine (micrograms/g creatinine) decreased significantly in both sexes between 24 and 64 years of age. The relative concentrations of hEGF in urine were significantly higher in women than in men at ages 20-69 years. The mean values of relative urinary hEGF concentrations in pregnant women in their twenties and thirties (30.0 +/- 0.7 micrograms/g creatinine and 29.6 +/- 1.2 micrograms/g creatinine) were significantly higher than those in age-matched nonpregnant women (27.3 +/- 1.8 micrograms/g creatinine and 22.8 +/- 0.7 micrograms/g creatinine). Among the trimesters, it was highest in the 2nd trimester of women in the twenties and thirties (33.4 +/- 1.3 micrograms/g creatinine and 31.7 +/- 1.9 micrograms/g creatinine). The significance of the increased urinary excretion of hEGF (micrograms/g creatinine) in pregnancy is not known. Further studies are required to find a source of hEGF in urine and a possible relation between increased hEGF excretion and fetoplacental growth and development.     

Long-term follow-up of the tubular secretion of creatinine in renal graft recipients.

The differences in glomerular filtration rate (GFR) based on creatinine clearance (Ccr) or obtained by the more exact methods are caused mainly by tubular creatinine secretion. In this study, we monitored creatinine clearance (Ccr), GFR on the basis of polyfructosan renal clearance (C(PF)) and parameters characterizing tubular creatinine secretion (Ccr/C(PF), Ccr - C(PF), Tcr/C(PF) x 100) in 12 individuals with renal grafts (Group A), 12 kidney graft donors for related transplantation (Group B), and in 27 individuals undergoing nephrectomy for a pathological process in one kidney (Group C). In the monitored groups, C(PF) and Ccr values were within the limits consistent with the normal function of a single kidney in a healthy individual. The values characterizing tubular creatinine secretion in Group A did not differ significantly from those obtained in Groups B and C. However, the parameters showed a wide range in all groups. In seven individuals with a renal graft, all the above functional parameters were monitored at three-month intervals for a period of 24 months. Significant differences in the time courses of Ccr and C(PF) due to marked intra-individual fluctuations were found in tubular creatinine secretion. The findings suggest that the rate of tubular creatinine secretion in the renal graft does not differ significantly from that in individuals with a single native (normally functioning) kidney. However, there are large inter-individual differences. The large intra-individual fluctuations in tubular creatinine secretion in the kidney graft result in significant differences in the time courses of Ccr and C(PF) and a possibility of erroneous evaluation of graft function if based exclusively on Ccr.     

Creatinine hydrolase and creatine amidinohydrolase: I. Presence in cell-free extracts of arthrobacter ureafaciens

Summary WhenA. ureafaciens are grown in a medium containing either creatinine or creatine as the sole source of carbon, an enzyme system capable of catabolizing creatine and creatinine is induced. This enzyme system has been isolated in a cell-free extract and is composed of two separate enzymes. The first, creatinine hydrolase, interconverts creatinine and creatine to form an equilibrium mixture of the two. The second enzyme, creatine amidinohydrolase, splits creatine into equimolar amounts of sarcosine and urea. The former enzyme is heat stable at 55°C for 30 min while the latter enzyme is completely destroyed at this temperature. The two enzymes have different solubilities in ammonium sulfate solutions.Predoctoral Fellow supported by NIH Training Grant GM00052.Submitted in partial fulfillment of the M.S. degree.     

Creatinine hydrolase and creatine amidinohydrolase: II. Partial purification and properties

Summary The optimal conditions for growing A. ureafaciens for producing maximum amounts of creatinine hydrolase and creatine amidinohydrolase relative to total protein are described. This required a medium in which either creatinine or creatine was the sole source of carbon.The specific activity of a crude, cell-free sonicate of creatinine hydrolase was increased 110- to 140-fold by a series of purification steps including heat treatment which inactivated creatine amidinohydrolase, precipitation of nucleic acids with streptomycin, ammonium sulfate precipitation of inert proteins, Sephadex Gel-200 filtration and DEAE-cellulose column chromatography. The most highly purified preparation of creatinine hydrolase still contained a number of inert proteins as demonstrated by acrylamide gel electrophoresis but was completely devoid of creatine amidinohydrolase activity.The pH optimum of creatinine hydrolase was 8.3 and the K_m was 0.125 M. The molecular weight of creatinine hydrolase as determined by filtration on a Sephadex Gel-200 column was approximately 240,000 and appeared to be composed of eight subunits. The molecular weight of creatine amidinohydrolase was in the vicinity of 100,000.The inhibitory effects of heavy metals and sulfhydryl compounds on the activities of the enzymes were studied.Predoctoral Fellow supported by NIH Training Grant 5T1-GM00052. Submitted in partial fulfillment of the M.S. degree.     

Creatinine metabolism in Cryptococcus neoformans and Cryptococcus bacillisporus.

The pathogenic species of Cryptococcus, C. neoformans and C. bacillisporus, utilized creatinine as a source of nitrogen but not of carbon. Chromatographic and autoradiographic studies suggest that creatinine metabolism in both species involves a single step resulting in the production of methylhydantoin and ammonia. The enzyme responsible for this step, creatinine deiminase, was produced by the cells only in the presence of creatinine in both species. The synthesis of creatinine deiminase was repressed by ammonia in C. neoformans, but not in C. bacillisporus. A possible explanation for this variation, based on the ecological differences between the two species, is discussed. A novel method for measuring creatinine deiminase activity is also described.     

Kidney injury biomarkers and urinary creatinine variability in nominally healthy adults

Abstract

Environmental exposure diagnostics use creatinine concentrations in urine aliquots as the internal standard for dilution normalization of all other excreted metabolites when urinary excretion rate data are not available. This is a reasonable approach for healthy adults as creatinine is a human metabolite that is continually produced in skeletal muscles and presumably excreted in the urine at a stable rate. However, creatinine also serves as a biomarker for glomerular filtration rate (efficiency) of the kidneys, so undiagnosed kidney function impairment could affect this commonly applied dilution calculation. The United States Environmental Protection Agency (US EPA) has recently conducted a study that collected approximately 2600 urine samples from 50 healthy adults, aged 19–50 years old, in North Carolina in 2009–2011. Urinary ancillary data (creatinine concentration, total void volume, elapsed time between voids), and participant demographic data (race, gender, height, and body weight) were collected. A representative subset of 280 urine samples from 29 participants was assayed using a new kidney injury panel (KIP). In this article, we investigated the relationships of KIP biomarkers within and between subjects and also calculated their interactions with measured creatinine levels. The aims of this work were to document the analytical methods (procedures, sensitivity, stability, etc.), provide summary statistics for the KIP biomarkers in “healthy” adults without diagnosed disease (distribution, fold range, central tendency, variance), and to develop an understanding as to how urinary creatinine level varies with respect to the individual KIP proteins. Results show that new instrumentation and data reduction methods have sufficient sensitivity to measure KIP levels in nominally healthy urine samples, that linear regression between creatinine concentration and urinary excretion explains only about 68% of variability, that KIP markers are poorly correlated with creatinine (r² ～ 0.34), and that statistical outliers of KIP markers are not random, but are clustered within certain subjects. In addition, we interpret these new adverse outcome pathways based in vivo biomarkers for their potential use as intermediary chemicals that may be diagnostic of kidney adverse outcomes to environmental exposure.     

Picric acid methods greatly overestimate serum creatinine in mice: more accurate results with high-performance liquid chromatography

The creatinine levels of blood and urine from humans, rats, and mice were measured by high-performance liquid chromatography. These were compared to the alkaline picrate analysis of creatinine performed by standard colorimetric, kinetic, and AutoAnalyzer techniques. For human serum and urine the values obtained using the HPLC technique gave good agreement with four out of five alkaline picrate techniques. For black or white mice, the serum creatinine concentration was 8.7 +/- 0.4 microM by HPLC but 44.9 +/- 1.9 microM by the lowest alkaline picrate method. Mouse urine creatinine concentrations were 3.24 +/- 0.19 mM by HPLC and 4.59 +/- 0.39 mM by the nearest alkaline picrate method. Rat serum creatinine concentrations analyzed by HPLC were about half the values obtained by AutoAnalyzer. Mouse and rat samples seemed to have substances which gave nonspecific color and thus interfered with the analysis of creatinine by the alkaline picrate methods. While the alkaline picrate analysis of creatinine was adequate for human samples, it was necessary to use HPLC to accurately measure rodent creatinine. The fractional excretion of creatinine was determined by measuring creatinine in mouse urine and plasma by both the kinetic and HPLC methods and comparing these values to urine and plasma inulin. Using the kinetic method, creatinine was cleared at 43 +/- 3% of the rate of inulin. Using the HPLC method, creatinine was cleared at 170 +/- 11% of the rate of inulin.     

Automated measurement of urinary creatinine by multichannel kinetic spectrophotometry

Urinary creatinine analysis is required for clinical diagnosis, especially for evaluation of renal function. Creatinine adjustment is also widely used to estimate 24-h excretion from spot samples. Few convenient validated approaches are available for in-house creatinine measurement for small- to medium-scale studies. Here we apply the Jáffe reaction to creatinine determination with zone fluidic multichannel kinetic spectrophotometry. Diluted urine sample and reagent, alkaline picric acid, were mixed by a computer-programmed dispenser and rapidly delivered to a four-channel detection cell. The absorbance change was monitored by a flow-through light-emitting diode-photodiode-based detector. Validation results against high-performance liquid chromatography-ultraviolet (HPLC-UV)/mass spectrometry (MS) are presented. Responses for 10-fold diluted samples were linear within clinically relevant ranges (0-250 mg/L after dilution). The system can analyze 70 samples per hour with a limit of detection of 0.76 mg/L. The relative standard deviation was 1.29% at 100 mg/L creatinine (n=225). Correlation with the HPLC (UV quantitation/MS confirmation) system was excellent (linear, r2=0.9906). The developed system allows rapid, simple, cost-effective, and robust creatinine analysis and is suitable for the analysis of large numbers of urine samples.     

Specific gravity as an alternative to creatinine for estimating urine concentration in captive and wild chimpanzee (Pan troglodytes) Samples

The measurement of hormones in urine has become a widely used technique in primatology. Because urine concentration varies according to fluid intake, concentration must be measured in each sample collected, and hormone values are always expressed per unit of concentration. Traditionally, creatinine has been used as a concentration index, but some studies in humans have shown that creatinine varies among populations and even within and between individuals within a population, and that it begins to degrade after just one freeze-thaw cycle. In addition, creatinine measurement is relatively time-consuming and expensive and creates hazardous waste. In this study, we tested the hypothesis that specific gravity, or the ratio of the density of a sample to that of water, is highly correlated with creatinine measurement in urine samples collected from captive chimpanzees at the New Iberia Research Center in Louisiana and wild chimpanzees at the Ngogo study site in the Kibale National Park, Uganda. We found that specific gravity and creatinine were highly correlated in both captive (N=124) and wild (N=13) chimpanzee samples, and that specific gravity measurement was robust to actual and simulated transport conditions and repeated freeze-thaw cycles. We recommend that researchers consider specific gravity measurement as a preferable alternative to creatinine measurement in their studies of primate endocrinology.     

An elevation of BUN/creatinine ratio in patients with hyperthyroidism

Blood urea nitrogen (BUN/creatinine ratio was abnormally high (24.8 +/- 0.6) in untreated hyperthyroid patients due to both increase in BUN and decrease in creatinine concentration. BUN, creatinine and BUN/creatinine ratio were all completely normalized after restoration of euthyroid status. On the other hand, BUN/creatinine ratio was slightly suppressed in hypothyroidism before treatment and it was reversed by thyroxine treatment (12.6 +/- 4.0 and 16.3 +/- 3.3, before and after treatment, respectively). An age-related increase in BUN/creatinine ratio, which was primarily due to an age-related increase in BUN, was also found in hyperthyroid subjects (21.9 +/- 2.8 vs 27.7 +/- 9.0; first vs fifth decade) and in normal controls (13.7 +/- 2.8 vs 16.0 +/- 2.9; first vs fifth decade). To elucidate reasons for abnormal increase in BUN/creatinine ratio in hyperthyroidism, measurement of cardiac output and kinetic analysis on urea nitrogen (UN) and creatinine were performed. The results indicated a marked increase in cardiac output. Serum creatine concentration was clearly increased in hyperthyroid patients. Thus, serum creatinine concentration was suppressed due to a decrease in creatinine synthesis and an increase in renal creatinine excretion. BUN was high, primarily due to an increase in UN production secondary to excessive protein catabolism together with insufficient excretion of UN.     

Sarcosine Oxidase Involved in Creatinine Degradation in Alcaligenes denitrificans subsp. denitrificans J9 and Arthrobacter spp. J5 and J11

Three microorganisms that degrade creatinine and contain sarcosine oxidase were isolated from soil and identified to be Alcaligenes denitrificans subsp. denitrificans J9 and Arthrobacter spp. J5 and J11. The three soil isolates degraded creatinine only via creatine by inducibly formed creatinine amidohydrolase, creatine amidinohydrolase, and sarcosine oxidase when cultivated with creatinine as the main nitrogen source. Sarcosine dehydrogenase, creatinine deiminase, and N-carbamoylsarcosine amidohydrolase were not induced by creatinine. Other microorganisms that degrade creatinine all contain sarcosine dehydrogenase as the enzyme for sarcosine oxidation, so these isolates seem to be unique in having sarcosine oxidase involved in their processes of creatinine degradation. Sarcosine oxidase was purified from A. denitrificans subsp. denitrificans J9 and partially characterized.     

Determination of dialysate creatinine by micellar electrokinetic chromatography

Micellar electrokinetic chromatography with UV absorbance detection has been applied for fast and selective determination of creatinine in samples of postdialysate fluid. Optimization of the method was performed, with the best results being obtained using a 30 mM borate-100 mM sodium dodecyl sulphate background electrolyte, pH 9, with the detector set at 235 nm and an applied voltage of 17 kV across a fused-silica capillary of 67 cm/75 micro m I.D. The linear range of the technique was over 2 orders of magnitude (5-1000 micro M). The developed analytical procedure is useful for the monitoring of clinical hemodialysis treatment, because creatinine levels in real undiluted samples of postdialysate range from 80 to 350 micro M. The separation system allows the analysis of about six to seven samples of spent dialysate per hour in almost real time. The determinations are not influenced by other components of dialysate fluid nor by other surrogates extracted from patient blood. The results of analysis using the developed procedure and the kinetic spectrophotometric Jaffe method conventionally used in clinical settings for creatinine determination are fully comparable. Successful clinical evaluation of the analytical system was performed. The developed system is useful for bloodless estimation of bioanalytical parameters of hemodialysis sessions such as creatinine-time profiles and total creatinine removal. Both these parameters are important in clinical models of hemodialysis therapy.