Quantitation of phenylbutyrate metabolites by UPLC-MS/MS demonstrates inverse correlation of phenylacetate:phenylacetylglutamine ratio with plasma glutamine levels.

Urea cycle disorders (UCDs) are genetic conditions characterized by nitrogen accumulation in the form of ammonia and caused by defects in the enzymes required to convert ammonia to urea for excretion. UCDs include a spectrum of enzyme deficiencies, namely n-acetylglutamate synthase deficiency (NAGS), carbamoyl phosphate synthetase I deficiency (CPS1), ornithine transcarbamylase deficiency (OTC), argininosuccinate lyase deficiency (ASL), citrullinemia type I (ASS1), and argininemia (ARG). Currently, sodium phenylbutyrate and glycerol phenylbutyrate are primary medications used to treat patients with UCDs, and long-term monitoring of these compounds is critical for preventing drug toxic levels. Therefore, a fast and simple ultra-performance liquid chromatography (UPLC-MS/MS) method was developed and validated for quantification of phenylbutyrate (PB), phenylacetate (PA), and phenylacetylglutamine (PAG) in plasma and urine. The separation of all three analytes was achieved in 2min, and the limits of detection were <0.04µg/ml. Intra-precision and inter-precision were <8.5% and 4% at two quality control concentrations, respectively. Average recoveries for all compounds ranged from 100% to 106%. With the developed assay, a strong correlation between PA and the PA/PAG ratio and an inverse correlation between PA/PAG ratio and plasma glutamine were observed in 35 patients with confirmed UCDs. Moreover, all individuals with a ratio ≥0.6 had plasma glutamine levels<1000µmol/l. Our data suggest that a PA/PAG ratio in the range of 0.6-1.5 will result in a plasma glutamine level<1000µmol/l without reaching toxic levels of PA.

Fabrication of aluminum terephthalate metal-organic framework incorporated polymer monolith for the microextraction of non-steroidal anti-inflammatory drugs in water and urine samples.

Polymer monolith microextraction (PMME) based on capillary monolithic column is an effective and useful technique to preconcentrate trace analytes from environmental and biological samples. Here, we report the fabrication of a novel aluminum terephthalate metal-organic framework (MIL-53(Al)) incorporated capillary monolithic column via in situ polymerization for the PMME of non-steroidal anti-inflammatory drugs (NSAIDs) (ketoprofen, fenbufen and ibuprofen) in water and urine samples. The fabricated MIL-53(Al) incorporated monolith was characterized by X-ray powder diffractometry, scanning electron microscopy, Fourier transform infrared spectrometry, and nitrogen adsorption experiment. The MIL-53(Al) incorporated monolith gave larger surface area than the neat polymer monolith. A 2-cm long MIL-53(Al) incorporated capillary monolith was applied for PMME coupled with high-performance liquid chromatography for the determination of the NSAIDs. Potential factors affecting the PMME were studied in detail. Under the optimized conditions, the developed method gave the enhancement factors of 46-51, the linear range of 0.40-200µgL(-1), the detection limits (S/N=3) of 0.12-0.24µgL(-1), and the quantification limits (S/N=10) of 0.40-0.85µgL(-1). The recoveries for spiked NSAIDs (20µgL(-1)) in water and urine samples were in the range of 77.3-104%. Besides, the MIL-53(Al) incorporated monolith was stable enough for 120 extraction cycles without significant loss of extraction efficiency. The developed method was successfully applied to the determination of NSAIDs in water and urine samples.

Urinary phenylacetylglutamine as dosing biomarker for patients with urea cycle disorders.

UNLABELLED: We have analyzed pharmacokinetic data for glycerol phenylbutyrate (also GT4P or HPN-100) and sodium phenylbutyrate with respect to possible dosing biomarkers in patients with urea cycle disorders (UCD). STUDY DESIGN: These analyses are based on over 3000 urine and plasma data points from 54 adult and 11 pediatric UCD patients (ages 6-17) who participated in three clinical studies comparing ammonia control and pharmacokinetics during steady state treatment with glycerol phenylbutyrate or sodium phenylbutyrate. All patients received phenylbutyric acid equivalent doses of glycerol phenylbutyrate or sodium phenylbutyrate in a cross over fashion and underwent 24-hour blood samples and urine sampling for phenylbutyric acid, phenylacetic acid and phenylacetylglutamine. RESULTS: Patients received phenylbutyric acid equivalent doses of glycerol phenylbutyrate ranging from 1.5 to 31.8 g/day and of sodium phenylbutyrate ranging from 1.3 to 31.7 g/day. Plasma metabolite levels varied widely, with average fluctuation indices ranging from 1979% to 5690% for phenylbutyric acid, 843% to 3931% for phenylacetic acid, and 881% to 1434% for phenylacetylglutamine. Mean percent recovery of phenylbutyric acid as urinary phenylacetylglutamine was 66.4 and 69.0 for pediatric patients and 68.7 and 71.4 for adult patients on glycerol phenylbutyrate and sodium phenylbutyrate, respectively. The correlation with dose was strongest for urinary phenylacetylglutamine excretion, either as morning spot urine (r = 0.730, p < 0.001) or as total 24-hour excretion (r = 0.791 p<0.001), followed by plasma phenylacetylglutamine AUC(24-hour), plasma phenylacetic acid AUC(24-hour) and phenylbutyric acid AUC(24-hour). Plasma phenylacetic acid levels in adult and pediatric patients did not show a consistent relationship with either urinary phenylacetylglutamine or ammonia control. CONCLUSION: The findings are collectively consistent with substantial yet variable pre-systemic (1st pass) conversion of phenylbutyric acid to phenylacetic acid and/or phenylacetylglutamine. The variability of blood metabolite levels during the day, their weaker correlation with dose, the need for multiple blood samples to capture trough and peak, and the inconsistency between phenylacetic acid and urinary phenylacetylglutamine as a marker of waste nitrogen scavenging limit the utility of plasma levels for therapeutic monitoring. By contrast, 24-hour urinary phenylacetylglutamine and morning spot urine phenylacetylglutamine correlate strongly with dose and appear to be clinically useful non-invasive biomarkers for compliance and therapeutic monitoring.

Simultaneous LC-MS/MS determination of phenylbutyrate, phenylacetate benzoate and their corresponding metabolites phenylacetylglutamine and hippurate in blood and urine.

Inborn errors of urea metabolism result in hyperammonemia. Treatment of urea cycle disorders can effectively lower plasma ammonium levels and results in survival in the majority of patients. Available medications for treating urea cycle disorders include sodium benzoate (BA), sodium phenylacetate (PAA), and sodium phenylbutyrate (PBA) and are given to provide alternate routes for disposition of waste nitrogen excretion. In this study, we develop and validate a liquid chromatography tandem mass spectrometry (LC-MS/MS) method for simultaneous determination of benzoic acid, phenylacetic acid, phenylbutyric acid, phenylacetylglutamine, and hippuric acid in plasma and urine from children with inborn errors of urea synthesis. Plasma extracts and diluted urine samples were injected on a reverse-phase column and identified and quantified by selected reaction monitoring (SRM) in negative ion mode. Deuterated analogues served as internal standards. Analysis time was 7 min. Assay precision, accuracy, and linearity and sample stability were determined using enriched samples. Quantification limits of the method were 100 ng/ml (0.3-0.8 µmol/L) for all analytes, and recoveries were >90%. Inter- and intraday relative standard deviations were <10%. Our newly developed LC-MS/MS represents a robust, sensitive, and rapid method that allows simultaneous determination of the five compounds in plasma and urine.

Identification of phenylbutyrate-generated metabolites in Huntington disease patients using parallel liquid chromatography/electrochemical array/mass spectrometry and off-line tandem mass spectrometry.

Oral sodium phenylbutyrate (SPB) is currently under investigation as a histone deacetylation (HDAC) inhibitor in Huntington disease (HD). Ongoing studies indicate that symptoms related to HD genetic abnormalities decrease with SPB therapy. In a recently reported safety and tolerability study of SPB in HD, we analyzed overall chromatographic patterns from a method that employs gradient liquid chromatography with series electrochemical array, ultraviolet (UV), and fluorescence (LCECA/UV/F) for measuring SPB and its metabolite phenylacetate (PA). We found that plasma and urine from SPB-treated patients yielded individual-specific patterns of approximately 20 metabolites that may provide a means for the selection of subjects for extended trials of SPB. The structural identification of these metabolites is of critical importance because their characterization will facilitate understanding the mechanisms of drug action and possible side effects. We have now developed an iterative process with LCECA, parallel LCECA/LCMS, and high-performance tandem MS for metabolite characterization. Here we report the details of this method and its use for identification of 10 plasma and urinary metabolites in treated subjects, including indole species in urine that are not themselves metabolites of SPB. Thus, this approach contributes to understanding metabolic pathways that differ among HD patients being treated with SPB.

Contribution of proteolytic and metabolic sources to hepatic glutamine by (2)H NMR analysis of urinary phenylacetylglutamine (2)H-enrichment from (2)H(2)O.

Proteolytic and cataplerotic sources of hepatic glutamine were determined by (2)H NMR analysis of urinary phenylacetylglutamine (PAGN) (2)H-enrichments in eight healthy subjects after (2)H(2)O and phenylbutyric acid ingestion. Body water enrichment was 0.49+/-0.03%. PAGN was enriched to lower levels with significant differences between the various glutamine positions. PAGN position 2 enrichment=0.33+/-0.02%; 3R=0.27+/-0.02%; 3S=0.27+/-0.02% and position 4=0.17+/-0.01%. Position 3R,S enrichments are conditional with the net conversion of citrate to glutamate and are therefore markers of cataplerosis. From the ratio of positions 3R,S to body water enrichment, 55+/-3% of hepatic glutamine was derived from cataplerosis and 45+/-3% from proteolysis. In conclusion, enrichment of PAGN 3R,S hydrogens relative to that of body water reflects the contribution of cataplerotic and proteolytic sources to hepatic glutamine.

Determination of nonsteroidal anti-inflammatory drugs in biological fluids by automatic on-line integration of solid-phase extraction and capillary electrophoresis.

A new, automatic method for the clean-up, preconcentration, separation, and quantitation of nonsteroidal anti-inflammatory drugs (NSAIDs) in biological samples (human urine and serum) using solid-phase extraction coupled on-line to capillary electrophoresis is proposed. Automatic pretreatment is carried out by using a continuous flow system operating simultaneously with the capillary electrophoresis equipment, to which it is linked via a laboratory-made mechanical arm. This integrated system is controlled by an electronic interface governed via a program developed in GWBasic. Capillary electrophoresis is conducted by using a separation buffer consisting of 20 mM NaHPO4, 20 mM beta-cyclodextrin and 50 mM SDS at pH 9.0, an applied potential of 20 kV and a temperature of 20 degrees C. The analysis time is 10 min and the detection limits were between 0.88 and 1.71 microg mL(-1). Automatic clean-up and preconcentration is accomplished by using a C-18 minicolumn and 75% methanol as eluent. The limit of detection of NSAIDs can be up to 400-fold improved when using sample clean-up. The extraction efficiency for these compounds is between 71.1 and 109.7 microg mL(-1) (RSD 2.0-7.7%) for urine samples and from 77.2 to 107.1 microg mL(-1) (RSD 3.5-7.1%) for serum samples.

Disposition of phenylbutyrate and its metabolites, phenylacetate and phenylacetylglutamine.

Phenylacetate, an inducer of tumor cytostasis and differentiation, shows promise as a relatively nontoxic antineoplastic agent. Phenylacetate, however, has an unpleasant odor that might limit patient acceptability. Phenylbutyrate, an odorless compound that also has activity in tumor models, is known to undergo rapid conversion to phenylacetate by beta-oxidation in vivo. This phase I study examined the pharmacokinetics of phenylbutyrate and characterized the disposition of the two metabolites, phenylacetate and phenylacetylglutamine. Fourteen patients with cancer (aged 51.8 +/- 13.8 years) received a 30-minute infusion of phenylbutyrate at 3 dose levels (600, 1200, and 2000 mg/m2). Serial blood samples and 24-hour urine collections were obtained. Samples were assayed by high-performance liquid chromatography. A model to simultaneously describe the pharmacokinetics of all three compounds was developed using ADAPT II. Data were modeled as molar equivalents. The model fit the data well as shown by mean (+/- SD) coefficients of determination (r2) for phenylbutyrate, phenylacetate, and phenylacetylglutamine, which were 0.96 +/- 0.07, 0.88 +/- 0.10, and 0.92 +/- 0.06, respectively. The intrapatient coefficient of variation percentage (CV%) around the parameter estimates were small (range 7.2-33.5%). Phenylbutyrate achieved peak concentrations in the range of in vitro tumor activity (500-2000 mumol/L) and exhibited saturable elimination (Km = 34.1 +/- 18.1 micrograms/mL and Vmax = 18.1 +/- 18 mg/h/kg). Metabolism was rapid; the times to maximum concentration for phenylacetate and phenylacetylglutamine were 1 and 2 hours, respectively. The conversion of phenylbutyrate to phenylacetate was extensive (80 +/- 12.6%), but serum concentrations of phenylacetate were low owing to rapid, subsequent conversion to phenylacetylglutamine.(ABSTRACT TRUNCATED AT 250 WORDS)

Excretion balance and urinary metabolites of the S-enantiomer of indobufen in rats and mice.

The excretion balance and urinary metabolites of the S-enantiomer of indobufen, ((S)2-[p-(1-oxo-2-isoindolinyl)-phenyl]butyric acid), a platelet aggregation inhibitor, were studied in rats and mice after oral administration. The urinary metabolic profile exhibited a marked species difference. The major metabolic pathway in the mouse was acyl glucuronidation followed by renal excretion, whereas in rat urine 5-hydroxylation and subsequent sulphation at the introduced hydroxyl group accounted for almost all recovered radioactivity. Indobufen glucuronide was the major biliary metabolite in the rat, while very little indobufen glucuronide was present in the urine of intact or bile duct-cannulated rats. A marked dose-effect on the elimination and metabolism of S-indobufen was demonstrated in the rat. The recovery (% dose) of 5-hydroxyindobufen and its sulphate after the lower dose of the enantiomer (10 mg/kg) was some 2.8-fold higher compared with the higher dose of 20 mg/kg.

Excretion balance and urinary metabolism of indobufen in rats and mice.

The excretion balance and the urinary metabolism of indobufen (+/- 2-[p-(1-oxo-2-isoindolinyl)-phenyl] butyric acid), a platelet aggregation inhibitor, has been studied in rats and mice after oral administration. The urinary metabolic profile of indobufen exhibited a marked species difference. The major metabolic pathway in the mouse was acyl glucuronidation followed by renal excretion, whereas in rats, 5-hydroxylation and subsequent sulphation at the introduced hydroxyl group predominated. Comparison of these results with previous data obtained in humans indicates that the mouse, and not the rat, is the rodent species of choice to be considered in the study of this compound.

The dispositional enantioselectivity of indobufen in man.

The plasma pharmacokinetics and urinary elimination of the enantiomers of indobufen (2-[p-(1-oxo-2-isoindolinyl)-phenyl]butyric acid), a novel platelet aggregation inhibitor, have been studied in male healthy volunteers given either the racemic compound or the S-enantiomer (200 mg racemate, 100 mg S-enantiomer). Enantiospecific analysis of indobufen in plasma and urine was achieved by HPLC of its L-leucinamide diastereoisomers. After administration of the racemate, the pharmacokinetic behaviour of the R- and S-enantiomers differed, the plasma levels of the S form declining more rapidly [half-lives = 6.2 hr (S), 8.7 hr (R)]. No substantial differences were observed in terms of plasma level profile of S-indobufen when administered alone and in the racemic mixture. A statistically significant difference between the two enantiomers after administration of the racemate was found in the area under the curve (AUC), peak plasma levels (Cmax) and elimination half-life (t1/2 beta) whereas no statistically significant difference was detected in the time of peak (tmax). When the pharmacokinetic parameters Cmax, AUC, t1/2 beta and tmax of S-indobufen administered alone or as racemate were compared, there were no statistically significant differences between treatments as well as between periods and sequences. The urinary excretion of total S-indobufen (free + glucuronide) and of total R-indobufen after administration of the racemate was essentially the same. No difference was observed either in the urinary excretion of total S-indobufen after administration of the racemate or of the S-enantiomer.

The dispositional enantioselectivity of indobufen in rat and mouse.

The plasma pharmacokinetics and urinary elimination of the enantiomers of indobufen, a novel platelet aggregation inhibitor, have been studied in rats and mice given either the racemic compound or the individual enantiomers (rat 8 mg/kg racemate, 4 mg/kg enantiomers; mouse 25 mg/kg racemate, 12.5 mg/kg enantiomers). Enantiospecific analysis of indobufen in plasma and urine was achieved by HPLC of its L-leucinamide diastereoisomers. In rat, the two enantiomers have very different plasma elimination half lives (S, 3.9 hr; R, 12.2 hr), irrespective of the optical form administered. The plasma concentration-time curves of S-indobufen were identical after racemic or S-indobufen, but the plasma levels of R-indobufen were lower after the R-enantiomer than after the racemate. Urinary recovery of free and conjugated indobufen was less than 3% of the dose, independent of the optical form administered. In the mouse, R-indobufen was cleared from plasma more rapidly than its S-antipode (elimination T1/2 R, 2.5 hr; S, 3.8 hr) but differences were smaller than those seen in the rat. The plasma concentration-time curves of the S-enantiomer were the same after racemic or S-indobufen, but levels of its R-antipode were much lower when it was given alone than after administration of the racemate. The urinary recovery of free and conjugated indobufen also exhibited enantioselectivity, with preferential elimination of the S-enantiomer.

Effect of age on the pharmacokinetics of indobufen.

Eighteen patients of both sexes, aging between 54 and 81 years entered a study on the effects of age on the disposition kinetics of indobufen, a potent inhibitor of platelet aggregation. Plasma levels and urinary excretion of the drug were assayed by HPLC after a single oral dose (200 mg) and after the last dose of a repeated oral schedule (200 mg b.i.d. for 5 days). At steady-state, indobufen plasma levels were about double those after the single dose; plasma level profiles were similar. No significant differences were detected between single dose and steady-state as regards pharmacokinetic parameters of the drug which, at steady-state, were (mean +/- SD, n = 16): Cmax = 32.6 +/- 9.3 micrograms/ml, t 1/2 beta = 12.8 +/- 4.4 h, Pl.Cl. = 14.9 +/- 6.1 ml/min, Vd beta = 223 +/- 63 ml/kg. Evidence of reduced efficiency and rate of indobufen elimination was found in elderly patients compared to young healthy subjects. This is probably because of the age-related decrease in renal function. In the patients of the present study, average Cr.Cl. was about 60 ml/min, corresponding to 50-60% of the normal values in young subjects. A statistically significant correlation was found in patients between drug plasma clearance and Cr.Cl. in agreement with the findings of a previous study on the effects of renal insufficiency on indobufen kinetics. The same dose reduction of indobufen as previously suggested for patients with mild to moderate renal insufficiency should, therefore, be adopted in elderly patients.