Secondary Exposure of Family Members to Cyclophosphamide After Chemotherapy of Outpatients With Cancer: A Pilot Study.

PURPOSE/OBJECTIVES: To measure the total amount of cyclophosphamide (CPA) excreted in the urine of patients with cancer and their cohabitating family members seven days after CPA administration. DESIGN: Biological monitoring.
. SETTING: Home setting with outpatients receiving chemo-therapy. SAMPLE: 8 patients administered CPA, 10 cohabitating family members, and 10 control participants. METHODS: During the first seven days after CPA administration, urine samples were collected from the participants. The samples were analyzed for the unchanged form of CPA using gas chromatography in tandem with mass spectroscopy. MAIN RESEARCH VARIABLES: CPA levels
. FINDINGS: CPA was detected in 112 of 276 patient urine samples. The last sample containing detectable CPA levels was collected after more than 48 hours in 63% of the patients, with a maximum length of five days post-treatment. In addition, 243 urine samples were collected from family members, and CPA was detected in the samples of five family members (17-252 ng per member). CPA was not detected in any control participants. CONCLUSIONS: These findings indicate that family members in close contact with patients receiving CPA are at high risk for drug exposure as many as seven days post-treatment
. IMPLICATIONS FOR NURSING: Nurses should educate patients and their family members about preventing exposure to antineoplastic drugs in the home setting.


Environmental contamination, product contamination and workers exposure using a robotic system for antineoplastic drug preparation.

Environmental contamination, product contamination and technicians exposure were measured following preparation of iv bags with cyclophosphamide using the robotic system CytoCare. Wipe samples were taken inside CytoCare, in the clean room environment, from vials, and prepared iv bags including ports and analysed for contamination with cyclophosphamide. Contamination with cyclophosphamide was also measured in environmental air and on the technicians hands and gloves used for handling the drugs. Exposure of the technicians to cyclophosphamide was measured by analysis of cyclophosphamide in urine. Contamination with cyclophosphamide was mainly observed inside CytoCare, before preparation, after preparation and after daily routine cleaning. Contamination outside CytoCare was incidentally found. All vials with reconstituted cyclophosphamide entering CytoCare were contaminated on the outside but vials with powdered cyclophosphamide were not contaminated on the outside. Contaminated bags entering CytoCare were also contaminated after preparation but non-contaminated bags were not contaminated after preparation. Cyclophosphamide was detected on the ports of all prepared bags. Almost all outer pairs of gloves used for preparation and daily routine cleaning were contaminated with cyclophosphamide. Cyclophosphamide was not found on the inner pairs of gloves and on the hands of the technicians. Cyclophosphamide was not detected in the stationary and personal air samples and in the urine samples of the technicians. CytoCare enables the preparation of cyclophosphamide with low levels of environmental contamination and product contamination and no measurable exposure of the technicians.

Simultaneous determination of bendamustine and its active metabolite, gamma-hydroxy-bendamustine in human plasma and urine using HPLC-fluorescence detector: application to a pharmacokinetic study in Chinese cancer patients.

A simple, sensitive and cost-effective assay based on reversed phase high performance liquid chromatography (RP-HPLC) with isocratic mode for simultaneous determination of bendamustine (BM) and its active metabolite, gamma-hydroxy-bendamustine (γ-OH-BM) in human plasma and urine was developed and validated. Sample preparation involved protein precipitation by 10% perchloric acid-methanol solution. The peaks were recorded by using fluorescence detector (excitation wavelength 328 nm and emission wavelength 420 nm). The calibration curves were linear over concentration ranges of 8.192-10,000 ng mL(-1) and 5-1,000 ng mL(-1) for BM in human plasma and urine as well as 10-1,000 ng mL(-1) and 5-1,000 ng mL(-1) for γ-OH-BM in human plasma and urine, respectively. Intra- and inter-run precisions of BM and γ-OH-BM were less than 15% and the bias were within ± 15% for both plasma and urine. This validated method was successfully applied to a pharmacokinetic study enrolling 10 Chinese patients with indolent B-cell non-Hodgkin lymphoma and chronic lymphocytic leukemia administered a single intravenous infusion of 100 mg m(2) bendamustine hydrochloride.

Occupational exposure to cyclophosphamide in nurses at a single center.

OBJECTIVE: To evaluate biological and environmental exposure to cyclophosphamide in nurses at a single institution. METHODS: Biological exposure to cyclophosphamide in nurses administering cyclophosphamide compared with two control groups: nononcology nurses not administering cyclophosphamide and community members without recent hospital exposure. Environmental exposure to chemotherapy was measured using surface wipes taken from oncology and nononcology areas in the hospital. RESULTS: More than one third of all nurses and no community controls tested positive for urinary cyclophosphamide. Oncology and nurse controls tested positive in equal numbers. Surface wipes were positive only in the oncology ward. CONCLUSION: We have demonstrated elevated levels of cyclophosphamide in one third of all nurses and cyclophosphamide contamination of surfaces within the oncology patient environment. This suggests that environmental contamination plays a major role in biological exposure to cyclophosphamide.

Evaluación de la exposición ocupacional a Ciclofosfamida en nueve hospitales del Perú / Evaluation of occupational exposure to Cyclophosphamide in nine hospitals of Peru

Objetivos. Evaluar la exposición ocupacional a ciclofosfamida en nueve hospitales del Perú. Materiales y métodos. Estudio observacional de tipo transversal realizado durante el año 2010 en el cual se colectó muestras de orina de 24 h de 96 trabajadores de las unidades de mezclas oncológicas y servicios de oncología de nueve hospitales del Perú, la cuantificación de ciclofosfamida se realizó por la metodología de GC-MS ( Gas Cromathography-Mass Spectroscopy). Se realizó, además, muestreo de superficies de trabajo utilizando paños húmedos para la determinación de ciclofosfamida. Resultados. Se detectó la presencia de ciclofosfamida en orina en 67 trabajadores (concentración promedio de excreción: 74,2 ng/24 h), lo cual representa el 70% del total de la población evaluada. Basado en la excreción se puede clasificar la exposición total entre los hospitales, en términos de exposición alta (>18,9 ng/24 h), moderada (1,725 - 18,9 ng/24 h) y baja (<1,725 ng/24 h), con una frecuencia porcentual de 31,3; 26,0 y 42,7% respectivamente. Además, como parte de la evaluación ambiental, se encontró concentraciones de ciclofosfamida de 14,72, 14,98 y 5,12 ng/cm².Conclusiones. Se evidencia una contaminación por ciclofosfamida en las áreas donde se realizan los preparados oncológicos y la presencia de ciclofosfamida en muestras de orina de trabajadores expuestos a citostáticos.

Objetives. Evaluate occupational exposure to cyclophosphamide in nine hospitals of Peru. Materials and methods. Cross-cutting observational study conducted in 2010, for which 24-hour urine samples were obtained from 96 employees of the oncologic mixture units and oncology services of nine hospitals in Peru, the quantification of cyclophosphamide was done through the GC-MS methodology ( Gas Cromathography-Mass Spectroscopy). Additionally, working surfaces were tested by obtaining samples with wet wipes for identification of cyclophosphamide. Results. Cyclophosphamide was detected in urine samples in 67 employees (average concentration of excretion: 74.2 ng/24 h), accounting for 70% of the total population to be assessed. Based on the excretion, total exposure among hospitals can be classified as high level (>18.9 ng/24 h), moderate level (1,725 - 18.9 ng/24 h) and low level (<1,725 ng/24 h), with a percent incidence of 31.3; 26.0 and 42.7% respectively. Additionally, as part of the environmental evaluation, concentrations of cyclosphamide were found in 14.72, 14.98 and 5,12 ng/cm2. Conclusions. Contamination through cyclophosphamide in areas where oncological preparations are done and the presence of cyclophosphamide in urine samples of workers exposed to cytostatics substance were observed.

Pharmacokinetics and excretion of 14C-bendamustine in patients with relapsed or refractory malignancy.

BACKGROUND: Bendamustine is an alkylating agent with clinical activity against a variety of hematologic malignancies and solid tumors. To assess the roles of renal and hepatic drug elimination pathways in the excretion and metabolism of bendamustine, a mass balance study was performed in patients with relapsed or refractory malignancies. METHODS: A single 60-minute intravenous dose of 120 mg/m(2), 80-95 µCi (14)C-bendamustine hydrochloride was administered to six patients, followed by collection of blood, urine, and fecal samples at specified time points up to day 8 or until the radioactivity of the 24-hour urine and fecal collections was below 1% of the administered dose (whichever was longer). Total radioactivity (TRA) was measured in all samples, and concentrations of unchanged bendamustine and its metabolites γ-hydroxy-bendamustine (M3), N-desmethyl-bendamustine (M4), and dihydroxy bendamustine (HP2) were determined in plasma and urine, using validated liquid chromatography-tandem mass spectrometry methods. RESULTS: The mean recovery of TRA in excreta was 76% of the radiochemical dose. Approximately half of the administered dose was recovered in urine and a quarter in feces. Less than 5% of the administered dose was recovered in urine as unchanged bendamustine. Bendamustine clearance from plasma was rapid, with a half-life of ~40 minutes. Plasma concentrations of M3, M4, and HP2 were very low relative to bendamustine concentrations. Plasma levels of TRA were higher and more sustained as compared with plasma concentrations of bendamustine, M3, M4, and HP2, suggesting the presence of one or more longer-lived (14)C-bendamustine-derived compounds. Fatigue (50%) and vomiting (50%) were the most frequent treatment-related adverse events. A grade 3/4 absolute lymphocyte count decrease occurred in all patients at some point during the study. CONCLUSION: Bendamustine is extensively metabolized, with subsequent excretion in both urine and feces. Accumulation of bendamustine is not anticipated in cancer patients with renal or hepatic impairment, because of the dose administration schedule and short half-life.

[Evaluation of occupational exposure to cyclophosphamide in nine hospitals of Peru]. / Evaluación de la exposición ocupacional a Ciclofosfamida en nueve hospitales del Perú

OBJECTIVES: Evaluate occupational exposure to cyclophosphamide in nine hospitals of Peru. MATERIALS AND METHODS: Cross-cutting observational study conducted in 2010, for which 24-hour urine samples were obtained from 96 employees of the oncologic mixture units and oncology services of nine hospitals in Peru, the quantification of cyclophosphamide was done through the GC-MS methodology ( Gas Cromathography-Mass Spectroscopy). Additionally, working surfaces were tested by obtaining samples with wet wipes for identification of cyclophosphamide. RESULTS: Cyclophosphamide was detected in urine samples in 67 employees (average concentration of excretion: 74.2 ng/24 h), accounting for 70% of the total population to be assessed. Based on the excretion, total exposure among hospitals can be classified as high level (>18.9 ng/24 h), moderate level (1,725 - 18.9 ng/24 h) and low level (<1,725 ng/24 h), with a percent incidence of 31.3; 26.0 and 42.7% respectively. Additionally, as part of the environmental evaluation, concentrations of cyclosphamide were found in 14.72, 14.98 and 5,12 ng/cm2. CONCLUSIONS: Contamination through cyclophosphamide in areas where oncological preparations are done and the presence of cyclophosphamide in urine samples of workers exposed to cytostatics substance were observed.

Metabolite profiling of bendamustine in urine of cancer patients after administration of [14C]bendamustine.

Bendamustine is an alkylating agent consisting of a mechlorethamine derivative, a benzimidazole group, and a butyric acid substituent. A human mass balance study showed that bendamustine is extensively metabolized and subsequently excreted in urine. However, limited information is available on the metabolite profile of bendamustine in human urine. The objective of this study was to elucidate the metabolic pathways of bendamustine in humans by identification of its metabolites excreted in urine. Human urine samples were collected up to 168 h after an intravenous infusion of 120 mg/m(2) (80-95 µCi) [(14)C]bendamustine. Metabolites of [(14)C]bendamustine were identified using liquid chromatography (high-resolution)-tandem mass spectrometry with off-line radioactivity detection. Bendamustine and a total of 25 bendamustine-related compounds were detected. Observed metabolic conversions at the benzimidazole and butyric acid moiety were N-demethylation and γ-hydroxylation. In addition, various other combinations of these conversions with modifications at the mechlorethamine moiety were observed, including hydrolysis (the primary metabolic pathway), cysteine conjugation, and subsequent biotransformation to mercapturic acid and thiol derivatives, N-dealkylation, oxidation, and conjugation with phosphate, creatinine, and uric acid. Bendamustine-derived products containing phosphate, creatinine, and uric acid conjugates were also detected in control urine incubated with bendamustine. Metabolites that were excreted up to 168 h after the infusion included products of dihydrolysis and cysteine conjugation of bendamustine and γ-hydroxybendamustine. The range of metabolic reactions is generally consistent with those reported for rat urine and bile, suggesting that the overall processes involved in metabolic elimination are qualitatively the same in rats and humans.

Development and validation of LC-MS/MS assays for the quantification of bendamustine and its metabolites in human plasma and urine.

A sensitive liquid chromatography tandem mass spectrometry (LC-MS/MS) assay is described for the quantification of the anti-cancer agent bendamustine and its phase I metabolites γ-hydroxy-bendamustine (M3) and N-des-methylbendamustine (M4) and for its product of two-fold hydrolysis, dihydroxy-bendamustine (HP2), in human plasma and urine. Like most alkylating nitrogen mustards, bendamustine is prone to chemical hydrolysis in aqueous solution. To minimize degradation of bendamustine, urine samples were stabilized by a 100-fold dilution with human plasma and then processed identically to plasma samples. Sample aliquots of 200 µL were mixed with an internal standard solution and acidified before separation of the analytes from the biomatrix with solid phase extraction. Dried and reconstituted extracts were injected on a Synergi Hydro RP column for the analysis of bendamustine, M3 and M4 or a Synergi Polar RP column for the analysis of HP2. Gradient elution was applied using 5mM ammonium formate with 0.1% formic acid in water and methanol as mobile phases. Analytes were ionized using an electrospray ionisation source in positive mode and detected with a triple quadrupole mass spectrometer. The quantifiable range for bendamustine, M3 and M4 was 0.5-500 ng/mL in plasma and 0.5-50 µg/mL in urine, and that for HP2 was 1-500 ng/mL in plasma and 0.1-50 µg/mL in urine. The assays were accurate and precise, with inter-assay and intra-assay accuracies within ± 20% of nominal and CV values below 20% at the lower limit of quantification and within ± 15% of nominal and below 15% at the other concentration levels tested. These methods were successfully applied to evaluate the pharmacokinetic profile of bendamustine and its metabolites in cancer patients treated with bendamustine.

A comprehensive understanding of thioTEPA metabolism in the mouse using UPLC-ESI-QTOFMS-based metabolomics.

ThioTEPA, an alkylating agent with anti-tumor activity, has been used as an effective anticancer drug since the 1950s. However, a complete understanding of how its alkylating activity relates to clinical efficacy has not been achieved, the total urinary excretion of thioTEPA and its metabolites is not resolved, and the mechanism of formation of the potentially toxic metabolites S-carboxymethylcysteine (SCMC) and thiodiglycolic acid (TDGA) remains unclear. In this study, the metabolism of thioTEPA in a mouse model was comprehensively investigated using ultra-performance liquid chromatography coupled with electrospray ionization quadrupole time-of-flight mass spectrometry (UPLC-ESI-QTOFMS) based-metabolomics. The nine metabolites identified in mouse urine suggest that thioTEPA underwent ring-opening, N-dechloroethylation, and conjugation reactions in vivo. SCMC and TDGA, two downstream thioTEPA metabolites, were produced from thioTEPA from two novel metabolites 1,2,3-trichloroTEPA (VII) and dechloroethyltrichloroTEPA (VIII). SCMC and TDGA excretion were increased about 4-fold and 2-fold, respectively, in urine following the thioTEPA treatment. The main mouse metabolites of thioTEPA in vivo were TEPA (II), monochloroTEPA (III) and thioTEPA-mercapturate (IV). In addition, five thioTEPA metabolites were detected in serum and all shared similar disposition. Although thioTEPA has a unique chemical structure which is not maintained in the majority of its metabolites, metabolomic analysis of its biotransformation greatly contributed to the investigation of thioTEPA metabolism in vivo, and provides useful information to understand comprehensively the pharmacological activity and potential toxicity of thioTEPA in the clinic.

Multicenter study for environmental and biological monitoring of occupational exposure to cyclophosphamide in Japan.

PURPOSE: A multicenter field survey of environmental contamination and exposure of healthcare professionals to anticancer drugs were performed. SETTING: Three university hospitals, one cancer specialty hospital and two corporate hospitals from across Japan. METHOD: The environmental contamination with cyclophosphamide (CP) was investigated. A wipe examination was performed at six sites apiece in two divisions. The urinary excretion of the CP over 24 h was determined. The subjects of the survey included physicians, pharmacists, and nurses, for a total of seven at each facility irrespective of job title. The wipe samples were collected at 12 sites within two divisions at each facility. For the exposure survey, the total urine volume was determined, and a portion of the urine sample was then collected from each participants at each facility. Urine was collected for 24 h. The samples were determined by using the GC-MS method. RESULTS: Wipe examination: contamination with CP was identified at 50% of the sites. The concentration was high (CP > 1.00 ng/cm(2)) in the general environment in two hospitals and in the safety cabinet in one hospital. In the survey for the exposure of staff to anticancer drugs, 276 samples were obtained from 41 healthcare professionals. CP was detected in 90 samples obtained from 23 subjects. The amount of exposure was greatly different among the facilities. The urinary excretion of CP per subject was between 2.7 and 462.8 ng/24 h. The range of urinary excretion for each hospital was between 4.6 and 211.2 ng/24 h.

Validation of urinary excretion of cyclophosphamide as a biomarker of exposure by studying its renal clearance at high and low plasma concentrations in cancer patients.

OBJECTIVES: Cyclophosphamide (CP) is an alkylating agent classified as a human carcinogen. Health care workers handling this drug may be exposed during, e.g., preparation or administration. Cyclophosphamide is readily absorbed by inhalation and by dermal uptake. A biomarker, CP in urine, has frequently been used to assess the occupational exposure to CP, but has not been fully validated. The aim of this study was to investigate if the proportion of the CP dose that is excreted in urine (renal clearance) is constant over different plasma drug concentrations and other pharmacokinetic parameters, e.g., urine flow. METHODS: Pharmacokinetics of CP were studied in 16 breast cancer patients that were treated with postoperative adjuvant chemotherapy including CP. Plasma and urine from the patients were collected at different occasions up to 12 days after the dose. Urine was collected during 4-h periods and blood was sampled at the end of each period. Analysis of CP was performed by liquid chromatography tandem mass spectrometry. The limit of detection for CP in urine and plasma was 0.01 and 0.02 ng/ml, respectively. The precisions of the developed methods were determined to < or =8%. RESULTS: The administered doses of CP in absolute amounts ranged between 800 and 2,240 mg. Mean renal clearance of CP was 8.6 (confidence interval 6.5-10.7) ml/min and was not significantly dependent of the plasma drug concentration. However, a significant correlation between renal clearance and urine flow was observed. There was a large inter-individual variation in the plasma and urine concentrations even when the same doses were given. CONCLUSIONS: Cyclophosphamide in urine can be continued to be used as a biomarker to monitor occupational exposure to CP, however the inter-individual variability of excretion of CP in urine, and its dependency on urine flow must be taken into consideration in future applications.

A pooled analysis to study trends in exposure to antineoplastic drugs among nurses.

OBJECTIVES: Several studies have shown that exposure to antineoplastic drugs can cause toxic effects on reproductive health as well as carcinogenic effects. Numerous studies have corroborated that hospital workers are exposed to these drugs. This study focused on trends in exposure to antineoplastic drugs since the introduction of guidelines in The Netherlands. METHODS: Data from three cross-sectional exposure surveys conducted in The Netherlands were pooled to examine trends in occupational exposure to cyclophosphamide. Nurses' 24 h urine samples were analyzed in separate fractions, surface contamination was determined and gloves used during preparation or while handling patient urine were collected. The difference in detectable urine samples between 1997 and 2000 was determined by a generalized estimating equations (GEE) binomial regression model. Mixed models were used to study the time trend in surface and glove contamination levels. RESULTS: The percentage of nurses' urine samples with detectable cyclophosphamide had decreased 4-fold between 1997 and 2000. Median cyclophosphamide levels in the positive urine samples were 3-fold lower in 2000 than in 1997. Surface and glove contamination had statistically significantly decreased between 1997 and more recent years. CONCLUSIONS: Nurses working at outpatient clinics or oncology wards are still being exposed to cyclophosphamide, but their exposure decreased considerably between 1997 and 2000, presumably due to the introduction of detailed guidelines and regulations in The Netherlands, the subsequent increased use of LuerLock connections and infusion systems prefilled with saline, and growing hazard awareness of nurses working with antineoplastic drugs.

Determination of treosulfan in plasma and urine by HPLC with refractometric detection; pharmacokinetic studies in children undergoing myeloablative treatment prior to haematopoietic stem cell transplantation.

A direct and selective HPLC method with refractometric detection was worked out for determination of treosulfan in plasma and urine of children. Before injection onto reverse phase column plasma samples with treosulfan and barbital (I.S.) were clarified using filtration. The mobile phase was composed of phosphate buffer, pH 5 and acetonitrile. The linear range of the standard curve of treosulfan spanned concentrations of 10.0-2000.0 microg/ml and 50.0-10000.0 microg/ml in plasma and urine, respectively, and covered the levels found in biological fluids after infusion of the drug. The limit of detection amounted to 5 microg/ml for plasma and 25 microg/ml for urine. Intra- and inter-day precision and accuracy of the measurement fulfilled analytical criteria accepted in pharmacokinetic studies. Recovery of treosulfan as well as stability in biological fluids was also calculated. The validated method was successfully applied in pharmacokinetic studies of treosulfan administered to children prior to haematopoietic stem cell transplantation. Differences between pharmacokinetics of treosulfan in children and adults were also studied.

Pharmacokinetics, metabolism, and routes of excretion of intravenous irofulven in patients with advanced solid tumors.

Irofulven is currently in Phase 2 clinical trials against a wide variety of solid tumors and has demonstrated activity in ovarian, prostate, gastrointestinal, and non-small cell lung cancer. The objectives of this study were to determine its pharmacokinetics and route of excretion and to characterize its metabolites in human plasma and urine samples after a 30-min i.v. infusion at a dose of 0.55 mg/kg in patients with advanced solid tumors. Three patients were administered i.v. 100 microCi of [14C]irofulven over a 30-min infusion on day 1 of cycle 1. Serial blood and plasma samples were drawn at 0 (before irofulven infusion) and up to 144 h after the start of infusion. Urine and fecal samples were collected for up to 144 h after the start of infusion. The mean urinary and fecal excretion of radioactivity up to 144 h were 71.2 and 2.9%, respectively, indicating renal excretion was the major route of elimination of [14C]irofulven. The C(max), AUC(0-infinity), and terminal half-life values for total radioactivity were 1130 ng-Eq/ml, 24,400 ng-Eq . h/ml, and 116.5 h, respectively, and the corresponding values for irofulven were 82.7 ng/ml, 65.5 ng . h/ml, and 0.3 h, respectively, suggesting that the total radioactivity in human plasma was a result of the metabolites. Twelve metabolites of irofulven were detected in human urine and plasma by electrospray ionization/tandem mass spectrometry. Among these metabolites, the cyclopropane ring-opened metabolite (M2) of irofulven was found, and seven others were proposed as glucuronide and glutathione conjugates.

[Identification of glufosfamide metabolites in rats].

AIM: To elucidate the metabolic pathway of glufosfamide in rats. METHODS: In this study, a liquid chromatography-tandem mass spectrometric method was developed and applied to characterize the metabolites of glufosfamide in rat urine, after an i.v. administration of 50 mg x kg(-1). The analysis was performed under two ionization modes in two different chromatographic systems, separately. To make sure that the compounds detected in rat urine were metabolites or degradation products, the stability of glufosfamide, isophosphoramide mustard (M1), and the degradation products of M1 in urine were investigated. RESULTS: In positive ionization mode, besides glufosfamide, two metabolites, isophosphoramide mustard and monoaziridinyl derivative of isophosphoramide mustard, were detected. In negative ionization mode, only glufosfamide itself was detected, while derivatives of isophosphoramide mustard have no response in such condition. CONCLUSION: Glufosfamide was mainly unchanged excreted in urine, and two metabolites were detected as isophosphoramide mustard and monoaziridinyl derivative of isophosphoramide mustard.

Role of GSTM1, GSTP1, and GSTT1 gene polymorphism in ifosfamide metabolism affecting neurotoxicity and nephrotoxicity in children.

The aim of this study was to evaluate the impact of GSTM1, GSTT1, and GSTP1 gene polymorphism on urinary excretion of unchanged ifosfamide, 2-dechloroethylifosfamide (2DCIF), and 3-dechloroethylifosfamide (3DCIF) with regard to the incidence of ifosfamide-related nephrotoxicity and neurotoxicity in children. The study comprised 76 children (38 girls, 38 boys) ages 9.84 to 210 months who were being treated for various malignant diseases with ifosfamide. The children were enrolled after identification of genotype coding for three classes of glutathione S-transferases (GSTM1, GSTT1, and GSTP1) at the initial stage of diagnosis. (P) nuclear magnetic resonance spectroscopy was used to analyze the urinary excretion of unchanged ifosfamide, 2DCIF, and 3DCIF metabolites on consecutive days after the end of the 3-hour infusion of ifosfamide. In children with polymorphic locus of the GSTP1 gene compared with children with homozygous wild alleles, increased urinary excretion of 3DCIF (P=0.029) and decreased creatinine clearance was found (Mann-Whitney P=0.03; median 81.1 mL/min/1.73 m vs. 105.0 mL/min/1.73 m, respectively). The authors' multidimensional analysis model revealed that besides the total ifosfamide dose and co-administration of other toxic drugs, polymorphic locus of GSTP1 gene may be one of the factors determining a higher toxicity of the cytostatic agent. The model was construed at P=0.029. Moreover, no correlation was found between the GSTM1 or GSTT1 genotype and ifosfamide toxicity and the urinary excretion of its metabolites. The results of this analysis indicate that individual reactions to ifosfamide can depend on inherited genetic polymorphisms, especially associated with the GSTP1 gene coding detoxifying enzyme.

Trabectedin (Yondelis, formerly ET-743), a mass balance study in patients with advanced cancer.

Trabectedin (Yondelis, formerly ET-743) is an anti-cancer drug currently undergoing phase II development. Despite extensive pharmacokinetic studies, the human disposition and excretory pathways of trabectedin remain largely unknown. Our objective was to determine the mass balance of trabectedin in humans. To this aim, we intravenously administered [(14)C]trabectedin to 8 cancer patients, followed by collection of whole blood, urine and faeces samples. A 24-h infusion was administered to 2 patients, whereas the other 6 patients received a 3-h infusion. Levels of total radioactivity and unchanged trabectedin were determined and used for calculation of pharmacokinetic parameters. No schedule dependency of pharmacokinetic parameters was observed apart from C(max). Plasma and whole blood concentrations of [(14)C]trabectedin related radioactivity were comparable. Only 8% of the plasma exposure to [(14)C]trabectedin related compounds is accounted for by trabectedin, indicating the importance of metabolism in trabectedin elimination. Trabectedin displays a large volume of distribution (+/-1700 L), relative to total radioactivity (+/-220 L). [(14)C]trabectedin related radioactivity is mainly excreted in the faeces (mean: 55.5% of the dose). Urinary excretion accounts for 5.9% of the dose on average resulting in a mean overall recovery of 61.4% (3-h administration schedule). The excretion of unchanged trabectedin is very low both in faeces and in urine (< 1% of dose). In conclusion, trabectedin is extensively metabolised and principally excreted in the faeces.

[Increased urinary excretion of the neurotoxic side-chain metabolites of ifosphamide in children with polymorphism of the glutathione S-transferases genes]. / Zwiekszone dobowe wydalanie neurotoksycznych metabolitów ifosfamidu u dzieci z dziedziczonym polimorfizmem genów kodujacych transferazy S-glutationu.

UNLABELLED: From 5% to 30% of children treated with ifosphamide (IF) develop symptoms of neurotoxicity due to toxic metabolites of the drug: 2- and 3- dechloroifosphamide (2- and 3-DCIF) and chloracetaldehyde (CAA), which cause glutathione depletion in cells. The aim of the study is to establish the influence of polymorphism of genes encoding for glutathione S-transferases classes pi (GSTP1), mi (GSTM1) and theta (GSTT1) on frequency of neurotoxicity of IF and amounts of toxic metabolites of the drug excreted in urine. MATERIAL AND METHODS: Neurotoxicity of IF was assessed in 76 children (38 girls and 38 boys), aged 9 to 210 months with diffrent kinds of neoplasms. They were treated with IF in 3-hours infusion in doses from 1.5 g/m2 to 3 g/m2 for 3 to 5 days. Before chemotherapy, deletions of GSTT1, GSTM1 genes and transition at +313 A-G in GSTP1 gene were identified with PCR and PCR-FRLP method, respectively. Daily urine excretion of 2-DCIF, 3-DCIF and unmetabolised IF was assessed with nuclear magnetic resonance (31P NMR). RESULTS: Symptoms of neurotoxicity were observed in 14 (18%) of 76 examined children treated with IF Comparing to children without neurological symptoms, in children with encephalopathy urinary excretion of unchanged ifosphamide was lower (p=0.055) and 2DCIF and 3DCIF was increased. Concomitantly, in children with transition at 313 A-->G GSTP1 gene concentrations of 2DCIF and 3DCIF were increased. Excretion of unmetabolised IF was statistically significantly higher in children with deletion of GSTT1 gene (p=0.02). Moreover, no correlation was found between the GSTM1 genotype and the excretion of ifosphamide and its metabolites. CONCLUSION: The results suggest that ifosphamide can be the substrate for glutathione S-transferases. Polymorphism of genes coding for glutathione S-transferases can influence individual reactions to iphosphamide.