Urine mesna excretion after intravenous and oral dosing in ifosfamide-treated children.

PURPOSE: To describe mesna excretion in children. PATIENTS AND METHODS: We studied 14 children (aged 1-18 years) who received 1.8 g/m(2) of ifosfamide per day for 5 days. For uroprotection, the children were given intravenous mesna (equal to 20% of the ifosfamide dose) followed by two oral doses (each equal to 40% of the ifosfamide dose). The concentrations of mesna and the metabolite dimesna were measured in urine samples collected on treatment days 1 and 5. RESULTS: Of 14 patients enrolled, 11 (aged 4-18 years) were evaluable. The profiles of mesna excretion rates were similar on days 1 and 5. Mesna excretion declined rapidly over 1-2 h after intravenous dosing. Increases in mesna excretion after oral dosing lagged by 2-4 h. About 21% of the mesna administered was excreted unchanged over 24 h on both days 1 and 5. The proportion excreted varied by severalfold between patients, but there was no association with age. CONCLUSION: The profile of mesna excretion after intravenous and oral dosing in these children was similar to that in reported studies of ifosfamide-treated adults.

Quantification of BNP7787 (dimesna) and its metabolite mesna in human plasma and urine by high-performance liquid chromatography with electrochemical detection.

A sensitive and accurate assay was developed and validated to determine BNP7787 (dimesna), a new protector against cisplatin-induced toxicities, and its metabolite mesna in plasma and urine of patients. Both analytes were measured as mesna in deproteinized plasma or in urine diluted with mobile phase using high-performance liquid chromatography with an electrochemical detector provided with a wall-jet gold electrode. The assays for BNP7787 and mesna in deproteinized plasma were linear over the range of 1.6-500 microM and 0.63-320 microM, respectively. In plasma, the mean recovery of BNP7787 over the whole concentration range was 100.6% and of mesna 94.6%. The lower limits of quantitation (LLQs) of BNP7787 and mesna in deproteinized plasma were 1.6 microM and 0.63 microM, respectively. For both compounds the within- and between-day accuracy and precision of the assay was better than 12%. The assays for BNP7787 and mesna in urine were linear over the range of 0.8-1200 microM and 0.63-250 microM, respectively. In urine, the mean recovery of BNP7787 over the whole concentration range was 94.1% and of mesna 93.1%. The LLQ of BNP7787 in urine was 0.8 microM and of mesna 1.6 microM. The within- and between-day accuracy and precision of the assay for BNP7787 and mesna was lower than 15%. The stability of mesna in urine increased with an increasing concentration of mesna, lower temperature and addition of EDTA (1 g/l) and hydrochloric acid (0.2 M). BNP7787 in urine was stable for at least 24 h at temperatures in the range of -20 degrees C up to 37 degrees C and independent of the concentration. The developed assays are currently applied for samples of patients with solid tumors participating in a phase I trial of BNP7787 in combination with cisplatin.

In vitro carboplatin-mesna interaction in aqueous solution, human plasma and urine.

The chemotherapeutic benefit of synergistic drug combinations and higher drug dosages has generated interest in the application of these regimens to cancer patients. A major obstacle in the application of these strategies to the treatment of cancer is the dose-limiting toxicities of drug combinations. Sodium 2-mercaptoethane-sulfonate (mesna), a chemoprotective drug, may reduce the nephrotoxicity of carboplatin [CBDCA, paraplatin, JM-8, cis-diammine (1,1-cyclobutane dicarboxylato) platinum II] when administered in combination chemotherapy. The purpose of this study was to evaluate, compare and contrast in vitro the interaction of mesna with carboplatin in aqueous solution, human plasma and urine. Carboplatin and mesna were incubated separately and together at clinically relevant concentrations in plasma and urine. The concentration of carboplatin was assayed by HPLC, and the decay of carboplatin alone and in combination with mesna was compared. The incubation of carboplatin with mesna in human plasma up to 8 days did not result in a statistically significant interaction: the half-life of carboplatin in plasma when it was combined with mesna was 1.62 +/- 0.08 (SE) days compared to 1.85+/- 0.04 (SE) days for carboplatin by itself. The incubation of drugs in fresh human urine up to 15 days gave a half-life of 3.43+/- 0.8 (SE) days for carboplatin alone and 2.78 +/- 0.7 (SE) days for carboplatin when it was combined with mesna. Our results show that carboplatin and mesna do not significantly interact in plasma. Although a statistically significant difference between the half-life of carboplatin and the half-life of the carboplatin/mesna combination is detected in urine, it is not likely to be clinically significant, as there is no significant interaction detected in the first 48 h). It is thus unlikely that mesna would substantially affect the pharmacokinetics of carboplatin when both are given together to patients as part of combination chemotherapy regimens.

Pharmacokinetics of an intravenous-oral versus intravenous-mesna regimen in lung cancer patients receiving ifosfamide.

PURPOSE: To compare the pharmacokinetics of the approved I.V. (intravenous) mesna regimen and an investigational I.V.-oral regimen that could be used in outpatients who receive ifosfamide. PATIENTS AND METHODS: The I.V. regimen consisted of three I.V. mesna doses given at 0, 4, and 8 hours after ifosfamide administration. The investigational regimen included an I.V. mesna dose given concurrently with ifosfamide, followed 2 and 8 hours later by oral administration of mesna tablets. I.V. and oral mesna doses equaled 20% and 40%, respectively, of the ifosfamide dose. The study subjects were 12 lung cancer patients who received ifosfamide 1.2 g/m2 daily for 5 days. The patients were randomized to receive either the I.V.-oral or I.V. mesna regimen on day 1, followed by crossover to the other regimen on days 2 through 5 of ifosfamide treatment. The urinary profiles of mesna and dimesna excretion were determined on days 1, 2, and 5; pharmacokinetic parameters for blood samples were determined only on day 5. RESULTS: During the first 12 hours after ifosfamide administration, the amount of mesna excreted and the profile of urinary mesna excretion was similar for both regimens; however, the I.V.-oral regimen showed less fluctuation in the excretion rate and higher trough values. During hours 12 to 24, about eightfold more mesna was excreted by patients given the I.V.-oral than the I.V. regimen. CONCLUSION: These pharmacokinetic data show that the I.V.-oral regimen should be at least as uroprotective as the I.V. mesna regimen. Patients may also benefit from the I.V.-oral regimen because of the higher trough values during hours 0 through 12 and the sustained urinary mesna excretion during hours 12 through 24.

Pharmacokinetics of mesna and dimesna after simultaneous intravenous bolus and infusion administration in patients undergoing bone marrow transplantation.

This study was undertaken to examine the pharmacokinetics of mesna and its dimer form, dimesna, in the plasma and urine of patients undergoing bone marrow transplantation who received 130 mg/kg of mesna divided intravenously into a 30-mg/kg bolus dose followed immediately by 100 mg/kg infused over 12 hours for uroprotection. The relationship between and urinary excretion of mesna and dimesna also was examined by comparing the data obtained in patients who developed hemorrhagic cystitis versus those who did not. Blood and urine samples were collected at different time intervals after administration, and the plasma or urine was analyzed by liquid chromatography with electrochemical detection. Dimesna was analyzed in these samples after reduction back to mesna with sodium borohydride. The concentration-time data of mesna exhibited the characteristics of the two-compartment model well, and the mean +/-SD values of the distributive phase half-life (t1/2 alpha), postdistributive phase half-life (t1/2 beta), volume of distribution of the central compartment (Vdc), volume of distribution at steady state (Vdss), volume of distribution during the postdistributive phase (Vd beta), total clearance (Cl), and mean residence time (MRT) observed were 0.12 +/- 0.15 hours, 2.12 +/- 1.61 hours, 0.324 +/- 0.336 L/kg, 1.09 +/- 1.18 L/kg, 2.09 +/- 3.0 L/kg, 0.755 +/- 0.507 L/hr.kg, and 6.77 +/- 0.72 hours, respectively. The mean +/-SD values of t1/2 and MRT of dimesna were 1.29 +/- 0.6 hours and 6.68 +/- 1.05 hours, respectively, and the ratio of the area under the concentration-time curve (AUC) of mesna to that of dimesna was 1.21 +/- 0.57. The fractions of dose excreted in urine in the form of mesna and dimesna in 20 hours (fu) were 0.361 +/- 0.15 and 0.482 +/- 0.25, and the renal clearance (ClR) values were 0.244 +/- 0.201 L/hr.kg and 0.157 +/- 0.156 L/hr.kg, respectively. The urinary excretion of mesna in these patients was higher than that required for uroprotection for the whole duration of infusion, and there was no significant difference in the pharmacokinetics of mesna between patients who developed hemorrhagic cystitis and those who did not. This was not the case with dimesna, in which patients with hemorrhagic cystitis excreted in urine less than 50% of the amount of dimesna excreted by those without hemorrhagic cystitis.

Urinary excretion of ifosfamide, 4-hydroxyifosfamide, 3- and 2-dechloroethylifosfamide, mesna, and dimesna in patients on fractionated intravenous ifosfamide and concomitant mesna therapy.

The oxazaphosphorine antineoplastic ifosfamide (IF) is metabolized by two different initial pathways: ring oxidation ("activation"), forming 4-OH-IF ("activated IF"), and side-chain oxidation with liberation of chloroacetaldehyde (CAA), forming the inactive metabolites 3-dechloroethylifosfamide or 2-dechloroethylifosfamide (3-DCE-IF, 2-DCE-IF). 4-OH-IF and 4-OH-IF-derived acrolein are thought to be responsible for IF-induced urotoxicity (hemorrhagic cystitis), whereas CAA may be involved in IF-associated nephrotoxicity (renal tubular damage). The thiol compound 2-mercaptoethane sulfonate sodium (mesna) has proved to inactivate sufficiently the urotoxic metabolites of oxazaphosphorine cytostatics and is therefore routinely given to patients receiving IF chemotherapy. The cumulative urinary excretion of IF, 4-OH-IF, 3-DCE-IF, 2-DCE-IF, mesna, and its disulfide dimesna was studied in 11 patients with bronchogenic carcinoma receiving IF on a 5-day divided-dose schedule (1.5 g/m2 daily) with concomitant application of mesna (0.3 g/m2 at 0,4, and 8 h after IF infusion). On day 1 the mean cumulative 24-h urinary recoveries (percentage of the IF dose) recorded for IF, 4-OH-IF, 3-DCE-IF, and 2-DCE-IF were 13.9%, 0.52%, 4.8%, and 1.5%, respectively. On day 5 the corresponding values were 12.2%, 0.74%, 9.9%, and 3.6%, respectively. This time-dependent increase in urinary excretion of IF metabolites, which is caused by rapid autoinduction of hepatic oxidative metabolism, may result in a higher probability for the development of urotoxic and nephrotoxic side effects during prolonged IF application. The mean 24-h urinary recoveries (percentage of the daily mesna dose) recorded for mesna/dimesna on day 1 (day 5) were 23.8%/45.2% (21.2%/39.8%), respectively. The mean molar excess of urinary reduced ("free") mesna over 4-OH-IF ranged from 11 to 72 on day 1 and from 6 to 40 on day 5. This indicates that although urinary excretion of 4-OH-IF rises with repeated IF application, mesna in standard doses should sufficiently inactivate the urotoxic IF metabolites.

Urinary elimination of cyclophosphamide alkylating metabolites and free thiols following two administration schedules of high-dose cyclophosphamide and mesna.

Twenty patients with a variety of neoplastic diseases were treated with preparative regimens containing high-dose cyclophosphamide (CY) administered as a 2-h infusion (60 mg/kg) for 2 days or by continuous infusion (1500 mg/m2/day) for 4 days. In patients receiving CY by 2-h infusion, the uroprotectant 2-mercaptoethane sulfonate (MESNA) was administered as an intermittent, bolus intravenous infusion (20% of CY dose) every 6 h. In patients receiving continuous infusion CY, MESNA was administrated concomitantly at an equivalent dose to CY by continuous infusion. During the first 24 h of CY administration, urine was collected at 2-h intervals and analyzed for free thiols and CY-alkylating metabolites. In patients receiving CY by short infusion and MESNA by intermittent bolus infusion, urinary concentrations of alkylating metabolites peaked at 4-8 h. During each dose of MESNA, urinary free thiols peaked at 2 h following administration but fell to pre-treatment levels at subsequent intervals. In patients receiving CY by continuous infusion, CY alkylating metabolites increased gradually over the 24-h study period while free thiols remained at a constant level during this period. With bolus administration of CY and intermittent bolus administration of MESNA every 6 h, there are periods where urinary CY-alkylating metabolites are elevated and free thiol concentrations are diminished. During continuous infusion of CY and MESNA, urinary CY alkylating metabolites reached peak concentrations at 18-22 h while the exposure of the bladder to free thiols remained constant. Recommendations are provided to increase the exposure of free thiols in the bladder when MESNA is administered by bolus or continuous infusion.

Liquid chromatographic analysis of mesna and dimesna in plasma and urine of patients treated with mesna.

We describe in this report an expedient and accurate liquid chromatographic method for measurement of mesna and dimesna in plasma and urine. The separation of mesna and the internal standard (p-aminobenzoic acid, IS) was achieved on a 10-microns, 8 mm (i.d.) x 10-cm C18-Resolve cartridge in conjunction with radial compression system. An aqueous solution of sodium citrate (0.1 M), tetrabutyl ammonium phosphate (0.001 M), and triethylamine (1:10,000, vol/vol), adjusted to pH 5 with 85% phosphoric acid was used at a flow rate of 2 ml/min as a mobile phase. The compounds were detected in the effluent electrochemically at +450 mV. After an appropriate amount of IS was added, the plasma sample (100 microliters or fraction thereof) was deproteinized with an equal volume of 0.0825 M sulfuric acid containing sodium hexametaphosphate (1.25% wt/vol), whereas urine was diluted 1:50 with water and mixed 1:1 with an aqueous solution of sodium hexametaphosphate (1.25% wt/vol). Dimesna was reduced back to mesna with sodium borohydride before analysis of the total mesna. The peak height ratio (drug/IS) varied linearly with the concentration, and the correlation coefficient was > 0.992 for both mesna and dimesna. The intrarun precision at different concentrations of mesna was equally good and the coefficient of variation was consistently < 4.5%. No interference from endogenous substances or any concomitantly used drug was observed. This assay is currently being used for measurement of mesna and dimesna in plasma of bone marrow recipients who receive high doses of cyclophosphamide.

Oral bioavailability of mesna tablets.

To test the feasibility of uroprotection with sodium 2-mercaptoethane-sulfonate (mesna) in tablet form the bioavailability of mesna tablets was determined in healthy volunteers by HPLC. The area under the plasma concentration-time curve (AUC) of free mesna was significantly lower following oral (110 mumol.l-1 x h-1; 95% CI 98-122) than following i.v. administration of 1.2 g of mesna (201 mumol.l-1 x h-1; 95% CI 158-244). The AUC for total mesna, i.e. dimesna and mixed disulfides, however, were comparable in the two groups, with 628 (539-717) and 772 (713-831) mumol.l-1 x h-1, respectively. The mean residence time was significantly longer following oral mesna, at 79 (76-83) min vs 239 (229-250) min. Following oral mesna 51.1% (46.2-56.0%) of the administered dose was recovered in the urine in 24 h, compared with 60.6 (53.6-67.6)% in 4 h following i.v. mesna, and the average concentration of mesna in the urine exceeded 3 mmol.l-1 for 8 h. The data indicate that mesna in tablet form has an adequate bioavailability for uroprotection and therefore may be preferable to liquid mesna, which has an unpleasant taste. Oral mesna has a longer mean residence time than i.v. mesna, which means that uroprotection can be achieved with longer dosing intervals.

False-positive ketone tests: a bedside measure of urinary mesna.

The sulfhydryl mesna is increasingly used to protect the bladder and kidney from effects of chemotherapy with ifosfamide and cyclophosphamide. Mesna reacts with reagents on urinary test strips designed to detect ketones. Test-strip results were correlated to sulfhydryl concentrations in 931 urine specimens obtained after infusions of mesna. These data may be used to estimate urinary mesna concentrations at the bedside or to test compliance in outpatients given oral mesna therapy.

Mesna excretion and ifosfamide nephrotoxicity in children.

To characterize the excretion of 2-mercaptoethanesulfonate sodium (mesna) administered by intermittent infusion, urinary concentrations of mesna and its corresponding inactive disulfide were measured during 50 courses of ifosfamide (1.6 g/m2 for 5 days) and mesna (400 mg/m2 at 0.25, 4, and 6 h after each ifosfamide dose) administered i.v. to 19 patients. Some patients had previously received nephrotoxic therapy that might influence the excretion of mesna and its associated uroprotective effects. The median urinary free thiol concentration increased to 3 mM by 1 h after mesna infusion, declining to background levels by 4 h. The rate of mesna excretion correlated with the creatinine clearance rate in a subset of six patients. The proportion of mesna recovered in urine within 4 h after infusion was lower (P less than 0.05) in children who had evidence of preexisting renal tubular damage. Ifosfamide-induced tubular proteinuria was associated with lower urinary mesna recovery. Low urinary mesna concentrations indicated potentially subtherapeutic renal tubular levels. However, ifosfamide nephrotoxicity was subclinical and is not necessarily linked to differences in mesna excretion.

[Urinary bioavailability of sodium-2-mercaptoethanesulfonate (Uromitexan) following intravenous, subcutaneous and continuous subcutaneous administration]. / Bioverfügbarkeit von Natrium-2-mercaptoethansulfonat (Uromitexan) im Urin nach intravenöser, subkutaner und kontinuierlich subkutaner Applikation.

The dose-limiting urotoxicity of the oxazaphosphorines (t1/2 = 4-15 h) is due to renal elimination of metabolites such as acrolein. The occurrence of hemorrhagic cystitis can be safely prevented by the concomitant use of i.v. or oral 2-mercaptoethanesulfonate sodium (DCI MESNA; Uromitexane). The bioavailability of oral MESNA is in the range of 20-50% and its unpleasant taste severely limits patient compliance. Due to the short half-life of MESNA (approx. 40 min) a regular fractionated or continuous administration is mandatory. In 6 healthy volunteers we have studied the pharmacokinetics of urinary MESNA elimination for the assessment of MESNA bioavailability after i.v. and s.c. drug administration. MESNA was given at doses of 400 mg for i.v. and s.c. bolus injections and 800 mg for continuous s.c. administration by a portable infusion pump. For the s.c. route an isotonic solution was prepared. The total amount of urinary thiols was assessed by the Ellman method (photometric reading at 412 nm). Total elimination of i.v. MESNA was 83.2 +/- 3.4% of the dose administered. The respective results for s.c. bolus and s.c. continuous drug administration were 81.9 +/- 3.4% and 79.4 +/- 3.6% of the dose. Continuous administration theoretically will provide optimal uroprotection from short term (hemorrhagic cystitis) and long term (bladder fibrosis and cancer) toxicity.

Excretion of disodium bis-2-mercaptoethanesulphonate (dimesna) in the urine of volunteers after oral dosing.

Dimesna was given to volunteers (n = 6) and levels of free thiols, mesna, cysteine and disulphides measured in urine. Mesna is excreted in the urine following oral dimesna administration. Peak urinary free thiol levels occur between 10 and 20 hr. Cysteine and mixed disulphides are also excreted. Mesna might be useful in prolonged bladder protection during oxazaphosphorine cancer chemotherapy.

False-positive results for ketone with the drug mesna and other free-sulfhydryl compounds.

All free-sulfhydryl compounds tested produced false-positive reactions in the Legal test for ketones. The color developed in the ketone pad of urine dipsticks [N-Multistix SG, Multistix 10 SG (Ames), and Chemstrip 9 (Boehringer-Mannheim)] was misinterpreted for ketone bodies, both by visual and automated reading. In contrast to the reaction with true ketones, a drop of glacial acetic acid added onto the ketone pad of dipsticks discharged the false-positive red color. A red-violet also developed instantly with free -SH compounds in the Acetest tablet assay (Ames), but quickly faded. In general, the presence of acidic groups such as -COOH and -SO3H in the structure appeared to increase the nitroprusside reactivity of free -SH compounds, whereas the presence of a -NH2 group appeared to decrease it. Currently, false-positive ketone reactions ascribable to a free -SH group are most likely to be seen for urine containing mesna. The false-positive test for ketones caused by free -SH compounds can be recognized and ruled out by proper procedures. On the other hand, this chromogenic reaction with free thiols might be used for monitoring urinary excretion of mesna.

The fate of [14C]-mesna in the rat.

[14C]-Mesna (sodium 2-mercaptoethanesulphonate) has a short serum t1/2 (about 16.5 min) and is excreted in the urine. Within 24 h approx. 77% of the administered dose appeared in the urine. It is bound to serum albumin and immunoglobulins. Total serum protein binding is about 9.7% of the total amount present in serum. [14C]-mesna + [14C]-dimesna (bis[2-mercaptoethane sulphonate]) are present in the blood stream, and so are found in the body organs at low concentration, however, localisation of radioactivity occurs in the kidneys. The binding of [14C]-mesna to proteins and the localisation of [14C]-mesna or [14C]-dimesna in the kidneys are discussed in the context of the cell killing efficacy of the oxazaphosphorines.

Identification and quantification of metabolite conjugates of activated cyclophosphamide and ifosfamide with mesna in urine by ion-pair extraction and fast atom bombardment mass spectrometry.

The high bladder toxicity of the alkylating oxazaphosphorine anticancer drugs, cyclophosphamide and ifosfamide is effectively reduced by the concomitant administration of mesna (sodium 2-mercaptoethane sulphonate). The formation and rapid urinary excretion of conjugates of the activated (4-hydroxylated) oxazaphosphorine metabolites with mesna has been suggested as the pharmacological basis for the selective detoxification, but separation and identification of such metabolites in vivo have been extremely difficult due to their high polarity and chemical lability. In this study an ion-pair extraction procedure in combination with positive and negative ion fast atom bombardment mass spectrometry has been developed which enabled the identification and quantification of the conjugation products of activated oxazaphosphorine metabolites with mesna in urine. The conjugates extracted as the tetra-n-butylammonium salts are directly identified by their characteristic positive molecular ion adducts and fragment ions, and the corresponding abundant molecular anions. The pattern of molecular and fragment ion formation was established by comparison of the fast atom bombardment mass spectra of synthetic cyclophosphamide-mesna conjugates with various organic and inorganic counter ions. The ifosfamide-4-(2-thioethylsulphonate) (ifosfamide-mesna) conjugate was identified as a metabolite in the urine of rats, and in patients after administration of the combination, ifosfamide + mesna. By means of a two-step extraction and with the use of suitable analogues as internal standards, procedures for the quantification of parent oxazaphosphorine and of oxazaphosphorine-mesna conjugates by negative ion fast atom bombardment mass spectrometry have been developed, and first examples for the determination of excretion kinetics are described.