Phase I/pharmacokinetic reevaluation of thioTEPA.

Because the initial evaluation of N,N',N''-triethylenethiophosphoramide (thioTEPA) preceded the standardized approach to the Phase I trials, uncertainty surrounds the recommended dose. Since it has recently been demonstrated that an almost 100-fold increase in dose can be administered in bone marrow transplant regimens, we conducted a Phase I reevaluation of thioTEPA. ThioTEPA was administered i.v. in 50 ml 5% dextrose in water over 10 min. Twenty-seven patients were entered at doses ranging from 30 to 75 mg/m2. The major toxic effect was myelosuppression; thrombocytopenia greater than or equal to grade 3 occurred in four of seven patients, and leukopenia greater than or equal to grade 3 in two of seven patients at 75 mg/m2. Among eight patients at 65 mg/m2 only two had greater than or equal to grade 3 myelosuppression making this the recommended new phase II dose for the majority of patients. Moderate (grade 2) easily controlled nausea and vomiting was the only other major side effect. There was no alopecia or mucosal or neurological toxicity. Three partial remissions were observed among nine previously treated ovarian cancer patients. Plasma concentrations of thioTEPA and its major active metabolite triethylenephosphoramide (TEPA) were measured by gas chromatography. The half-life of thioTEPA ranged from 51.6 to 211.8 min, and its pharmacokinetics was dose dependent; total body thioTEPA clearance decreased with increasing dose. The half-life of TEPA was considerably longer than that of the parent compound (3.0 to 21.1 h); as a result, the area under the plasma concentration-time curve (AUC) of TEPA was severalfold greater than that of the parent compound. The ratio of TEPA AUC to thioTEPA AUC decreased with increasing dose, suggesting that formation of TEPA is a saturable step in elimination. The AUC and total body clearance of thioTEPA, but not of TEPA, were closely correlated with neutrophil but not platelet toxicity.

Relationship between irreversible alopecia and exposure to cyclophosphamide, thiotepa and carboplatin (CTC) in high-dose chemotherapy.

Reversible alopecia is a commonly observed, important and distressing complication of chemotherapy. Permanent alopecia, however, is rare after standard-dose therapy, but has occasionally been observed after high-dose chemotherapy with cyclophosphamide, thiotepa and carboplatin (CTC). We evaluated the relationships between total exposure to these three compounds and their different metabolites in the high-dose CTC regimen, and the subsequent development of irreversible alopecia. Twenty-four patients received two or three courses of high-dose CTC, each followed by peripheral blood progenitor cell transplantation. Plasma levels of cyclophosphamide, its active metabolite 4-hydroxycyclophosphamide, thiotepa, its active metabolite tepa, and carboplatin were determined, and the area-under-the-plasma concentration-versus-time curves (AUC) of the compounds were calculated. Eight of the 24 patients included in the study developed permanent alopecia, while seven had normal hair regrowth and nine patients developed incomplete and/or thin hair regrowth. The carboplatin AUC and the summed AUC of thiotepa and tepa were both significantly associated with increasing irreversibility of hair loss. These results suggest that high exposure to carboplatin and the sum of the thiotepa and tepa exposure may lead to the development of permanent alopecia. This knowledge could guide therapeutic drug monitoring in order to prevent the occurrence of permanent alopecia and thereby improve the patients' quality of life.

Simultaneous quantification of cyclophosphamide, 4-hydroxycyclophosphamide, N,N',N"-triethylenethiophosphoramide (thiotepa) and N,N',N"-triethylenephosphoramide (tepa) in human plasma by high-performance liquid chromatography coupled with electrospray ionization tandem mass spectrometry.

The alkylating agents cyclophosphamide (CP) and N, N', N"-triethylenethiophosphoramide (thiotepa) are often co-administered in high-dose chemotherapy regimens. Since these regimens can be complicated by the occurrence of severe and sometimes life-threatening toxicities, pharmacokinetically guided administration of these compounds, to reduce variability in exposure, may lead to improved tolerability. For rapid dose adaptations during a chemotherapy course, we have developed and validated an assay, using liquid chromatography coupled with electrospray tandem mass spectrometry (LC/MS/MS), for the routine quantification of CP, thiotepa and their respective active metabolites 4-hydroxycyclophosphamide (4OHCP) and N, N', N"-triethylenephosphoramide (tepa) in plasma. Because of the instability of 4OHCP in plasma, the compound is derivatized with semicarbazide (SCZ) immediately after sample collection and quantified as 4OHCP-SCZ. Sample pretreatment consisted of protein precipitation with a mixture of methanol and acetronitrile using 100 microl of plasma. Chromatographic separation was performed on an Zorbax Extend C18 column (150 x 2.1 mm i.d., particle size 5 microm), with a quick gradient using 1 mM ammonia solution and acetonitrile, at a flow-rate of 0.4 ml min(-1). The analytical run time was 10 min. The triple quadrupole mass spectrometer was operating in the positive ion mode and multiple reaction monitoring was used for drug quantification. The method was validated over the concentration ranges 200-40,000 ng ml(-1) for CP, 50-5000 ng ml(-1) for 4OHCP-SCZ and 5-2500 ng ml(-1) for thiotepa and tepa, using 100 microl of human plasma. These dynamic concentration ranges proved to be relevant in daily practice. Hexamethylphosphoramide was used as an internal standard. The coefficients of variation were <12% for both intra-day and inter-day precisions for each compound. Mean accuracies were also between the designated limits (+/- 15%). This robust and rapid LC/MS/MS assay is now successfully applied for routine therapeutic drug monitoring of CP, thiotepa and their metabolites in our hospital.

Influence of the tissue distribution of ThioTEPA and its metabolite, TEPA, on the response of murine colon tumours.

Disposition studies in the same animals as those used for assessment of antitumor and toxic effects could increase understanding of the variation in response to cytotoxic drugs. Tissue and plasma levels of ThioTEPA and triethylenephosphoramide (TEPA) were measured to see if any correlation existed between them and the effects of the drug on a series of mouse colon tumours (MAC). The tumour panel included an ascitic form (MAC 15A), an anaplastic (MAC 13) and a well-differentiated (MAC 26) solid tumour, all grown subcutaneously. The maximum tolerated dose of ThioTEPA was 20 mg kg-1 in females bearing MAC 13 and 15 mg kg-1 in males having MAC 15A or 26. The diverse growth characteristics of the tumour cell lines necessitated the use of different methods for assessment of response. After administration of the maximum tolerated dose, the greatest response was observed in MAC 26, in which a growth delay of 15 days-twice the doubling time of the tumour volume-occurred. ThioTEPA produced 58% inhibition of MAC 13 tumour weight, but MAC 15A was unresponsive. One hour after intraperitoneal administration of Thio-TEPA (20 mg kg-1), ratios of tissue to plasma concentration were 1.13, 0.87 and 1.17 in tumours and 0.80, 0.75 and 0.73 in spleens of mice bearing MAC 13, 15A and 26 respectively. These data show greater accumulation of drug in neoplastic than in normal tissues. The pattern of distribution of the metabolite was similar, but there was a lesser degree of tissue accumulation than by the drug. Concentrations of drug and metabolite in neoplastic tissues related to their protein content were 116.0, 126.3 and 183.3 micrograms ThioTEPA/g and 57.5, 83.1 and 78.6 micrograms TEPA/g in MAC 13, 15A and 26 respectively. Combination of these chemosensitivity and pharmacokinetic data indicates that differences in response of these tumours to ThioTEPA cannot be explained by the availability of the drug and metabolite. The therapeutic effects of ThioTEPA cannot be predicted purely from a knowledge of drug and metabolite disposition.

ThioTEPA pharmacokinetics during intravesical chemotherapy: the influence of dose and volume of instillate on systemic uptake and dose rate to the tumour.

ThioTEPA is given intravesically in a variety of schedules to treat superficial bladder cancer. In this study, the influence of the dose of ThioTEPA and the volume of instillate on the dose rate to the tumour and the systemic uptake of ThioTEPA was investigated in eight patients with pTa or pTl disease. Each patient received four courses of ThioTEPA consisting of 30 mg of drug/30 ml of distilled water, 30 mg/60 ml, 60 mg/30 ml and 60 mg/60 ml. Blood and urine samples were obtained for 8 h following instillation, and ThioTEPA and TEPA levels were measured. The AUC(infinity) values (areas under the concentration-time curve, extrapolated to infinity) in plasma were approximately 2 factors higher at the two 60-mg doses. However, the AUC value in the bladder was nearly 70% higher when 60 mg of drug was instilled in 30 ml of distilled water as compared with 60 mg in 60 ml. Thus, by decreasing the volume of instillate it is possible to increase the dose rate to the tumour without increasing the systemic toxicity.

Stability of thioTEPA and its metabolites, TEPA, monochloroTEPA and thioTEPA-mercapturate, in plasma and urine.

The degradation of N,N',N"-triethylenethiophosphoramide (thioTEPA) and its metabolites N,N',N"-triethylenephosphoramide (TEPA), N, N'-diethylene,N"-2-chloroethylphosphoramide (monochloroTEPA) and thioTEPA-mercapturate in plasma and urine has been investigated. ThioTEPA, TEPA and monochloroTEPA were analyzed using a gas chromatographic (GC) system with selective nitrogen/phosphorous detection; thioTEPA-mercapturate was analyzed on a liquid chromatography-mass spectrometric (LC-MS) system. The influences of pH and temperature on the stability of thioTEPA and its metabolites were studied. An increase in degradation rate was observed with decreasing pH as measured for all studied metabolites. In urine the rate of degradation at 37 degrees C was approximately 2.5+/-1 times higher than at 22 degrees C. At 37 degrees C thioTEPA and TEPA were more stable in plasma than in urine, with half lives ranging from 9-20 h for urine and 13-34 h for plasma at pH 6. Mono- and dichloro derivatives of thioTEPA were formed in urine and the monochloro derivative was found in plasma. Degradation of TEPA in plasma and urine resulted in the formation of monochloroTEPA. During the degradation of TEPA in plasma also the methoxy derivative of TEPA was formed as a consequence of the applied procedure. The monochloro derivative of thioTEPA-mercapturate was formed in urine, whereas for monochloroTEPA no degradation products could be detected.

Population pharmacokinetics of cyclophosphamide and its metabolites 4-hydroxycyclophosphamide, 2-dechloroethylcyclophosphamide, and phosphoramide mustard in a high-dose combination with Thiotepa and Carboplatin.

The anticancer prodrug cyclophosphamide (CP) is activated by the formation of 4-hydroxycyclophosphamide (4OHCP), which decomposes into phosphoramide mustard (PM). This activation pathway is inhibited by thiotepa. CP is inactivated by formation of 2-dechloroethylcyclophosphamide (2DCECP). The aim of this study was to develop a population pharmacokinetic model describing the complex pharmacokinetics of CP, 4OHCP, 2DCECP, and PM when CP is administered in a high-dose combination with thiotepa and carboplatin. Patients received a combination of CP (1000-1500 mg/m/d), carboplatin (265-400 mg/m/d), and thiotepa (80-120 mg/m/d) administered in short infusions over 4 days. Twenty blood samples were collected per patient per course. Concentrations of CP, 4OHCP, 2DCECP, PM, thiotepa, and tepa were determined in plasma. Using NONMEM, an integrated population pharmacokinetic model was used to describe the pharmacokinetics of CP, 4OHCP, 2DCECP, and PM, including the already described processes of autoinduction of CP and the interaction with thiotepa. Data were available on 35 patients (70 courses). The pharmacokinetics of CP were described with a 2-compartment model, and those of 4OHCP, 2DCECP, and PM with 1-compartment models. Before onset of autoinduction, it was assumed that CP is eliminated through a noninducible pathway accounting for 20% of total CP clearance, whereas 2 inducible pathways resulted in formation of 4OHCP (75%) and 2DCECP (5%). It was assumed that 4OHCP was fully converted to PM. Induction of CP metabolism was mediated by 2 hypothetical amounts of enzyme whose quantities increased in time in the presence of CP (kenz=0.0223 and 0.0198 hours). Induction resulted in an increased formation of 4OHCP (approximately 50%), PM (approximately 50%), and 2DCECP (approximately 35%) during the 4-day course, and concomitant decreased exposure to CP (approximately 50%). The formation of 2DCECP was not inhibited by thiotepa. Apparent volumes of distribution of CP, PM, and 2DCECP could be estimated being 43.7, 55.5, and 18.5 L, respectively. Exposure to metabolites varied up to 9-fold. The complex population pharmacokinetics of CP, 4OHCP, 2DCECP, and PM in combination with thiotepa and carboplatin has been established and may form the basis for further treatment optimization with this combination.

High-performance liquid chromatography of the anti-tumour agent triethylenethiophosphoramide and its metabolite triethylenephosphoramide with sodium sulphide, taurine and o-phthalaldehyde as pre-column fluorescent derivatization reagents.

The method described is based on the reaction of triethylenethiophosphoramide (ThioTEPA) and triethylenephosphoramide (TEPA), through their ethyleneimine groups, with sodium sulphide, taurine and o-phthalaldehyde to give fluorescent products, and separation of the derivatives by reversed-phase high-performance liquid chromatography. The method was successfully applied to the determination of ThioTEPA and TEPA in rabbit plasma samples after clean-up with an Extrelut 3 column. The recoveries of ThioTEPA and TEPA from plasma were 66.1-80.3% and the limits of determination in plasma were ca. 10 and 20 ng/ml, respectively.

Simultaneous determination of N,N',N"-triethylenethiophosphoramide, cyclophosphamide and some of their metabolites in plasma using capillary gas chromatography.

A sensitive assay for the simultaneous determination of N,N',N"-triethylenethiophosphoramide (thioTEPA), its metabolite N,N',N"-triethylenephosphoramide (TEPA), cyclophosphamide (CP) and its metabolite 2-dechloroethylcyclophosphamide (2-DCE-CP) in plasma has been developed and validated. The analytes were determined using gas chromatography with nitrogen/phosphorus selective detection after liquid-liquid extraction with chloroform using 100 microl of plasma. Diphenylamine (for TEPA, thioTEPA and 2-DCE-CP) and imipramine (for CP) were used as internal standards. The limits of quantitation for thioTEPA, TEPA, CP and 2-DCE-CP were 5, 5, 50 and 250 ng/ml, respectively. Linear calibration curves were observed over two decades of concentration. Accuracy, within-day and between-day precision were less than 13% for all analytes. Stability of the analytes proved to be satisfactory for at least 1 month, stored at -70 degrees C. Analysis of samples obtained from patients receiving cyclophosphamide, thioTEPA and carboplatin in a high-dose regimen demonstrated the applicability of the assay.

Gas chromatographic analysis of triethylenethiophosphoramide and triethylenephosphoramide in biological specimens.

Comprehensive pharmacokinetic studies could realise a greater potential for the antitumour agent triethylenethiophosphoramide (ThioTEPA), and these would be aided by the development of a selective and sensitive assay. After extraction of ThioTEPA and its metabolite, triethylenephosphoramide (TEPA), from plasma using Sep-Pak C18 cartridges, the compounds were separated by capillary chromatography, detected using a nitrogen detector and quantified by reference to an internal standard, hexaethylphosphoramide. The limits of sensitivity were 1-5 ng/ml. Analytical recoveries were 74 and 95%, for TEPA and ThioTEPA, respectively, in the therapeutic range. At similar concentrations, extents of protein binding, determined by ultrafiltration, were not significant. Preliminary investigations of the elimination of ThioTEPA show that drug loss occurs more quickly in mice than in humans and in both species the metabolite is extensively recycled.

Population pharmacokinetics of thioTEPA and its active metabolite TEPA in patients undergoing high-dose chemotherapy.

AIMS: To study the population pharmacokinetics of thioTEPA and its main metabolite TEPA in patients receiving high-dose chemotherapy consisting of thioTEPA (80-120 mg x m(-2) x day(-1)), cyclophosphamide (1000-1500 mg x m(-2) x day(-1)) and carboplatin (265-400 mg x m(-2) x day(-1)) for 4 days. METHODS: ThioTEPA and TEPA kinetic data were processed with a two-compartment model using the nonlinear mixed effect modelling program NONMEM. Interindividual variability (IIV), interoccasion variability (IOV) and residual variability in the pharmacokinetics were estimated. The influence of patient characteristics on the pharmacokinetics was also determined. RESULTS: A total number of 40 patients receiving 65 courses of chemotherapy was included. Clearance of thioTEPA (CL) was 34 l x h(-1) with an IIV and IOV of 18 and 11%, respectively. The volume of distribution of thioTEPA was 47 l (IIV = 7.5%; IOV = 19%). The fraction of thioTEPA converted to TEPA divided by the volume of distribution of TEPA was 0.030 l-1 (IIV = 39%; IOV = 32%) and the elimination rate constant of TEPA was 0.64 h(-1) (IIV = 27%; IOV = 32%). CL of thioTEPA was correlated with alkaline phosphatase and serum albumin. The volume of distribution of thioTEPA and the elimination rate constant of TEPA were correlated with total protein levels and body weight, respectively. CONCLUSIONS: A model for the description of the pharmacokinetics of thioTEPA and TEPA was developed. Factors involved in the interpatient variability of thioTEPA and TEPA pharmacokinetics were identified. Since, IOV of both thioTEPA and TEPA was equal to or smaller than IIV, therapeutic drug monitoring based on data of previous courses may be meaningful using this population model.

Determination of N,N',N"-triethylenethiophosphoramide and its active metabolite N,N',N"-triethylenephosphoramide in plasma and urine using capillary gas chromatography.

A sensitive assay for the determination of N,N',N"-triethylenethiophosphoramide (thioTEPA) and its metabolite N,N',N"-triethylenephosphoramide (TEPA) in micro-volumes human plasma and urine has been developed. ThioTEPA and TEPA were analysed using gas chromatography with selective nitrogen-phosphorus detection or mass spectrometry after extraction with a mixture of 1-propanol-chloroform from the biological matrix. Diphenylamine was used as internal standard. The limit of detection was 1.5 ng/ml for thioTEPA and 2.5 ng/ml for TEPA, using 100 microl of biological sample; recoveries ranged between 70 and 90% and both accuracy and precision were less than 10%. Linearity was accomplished in the range of 10-1000 ng/ml for plasma and 100-10000 ng/ml for urine using thermionic nitrogen-phosphorus detection. With mass spectrometry a linear range of 100-25000 ng/ml TEPA in plasma or urine was obtained. For thioTEPA a second-order polynomial function describes the relationship between the analyte concentration in the range of 500-25000 ng/ml and detection response. TEPA proved to be stable in plasma and urine for at least 10 weeks at -80 degrees C. ThioTEPA and TEPA plasma concentrations of two patients treated with thioTEPA are presented demonstrating the applicability of the assay for clinical samples.

Human plasma pharmacokinetics and urinary excretion of thiotepa and its metabolites.

Thiotepa has been used clinically for greater than 30 years but its pharmacokinetics remain poorly defined. We determined the plasma pharmacokinetics and urinary excretion of thiotepa and its metabolites in 21 patients with breast cancer who received 25 courses of iv bolus thiotepa (12 mg/m2) as part of combination chemotherapy. Plasma samples were obtained before injection: at 5, 10, 15, 30, 45, 60, 90, and 120 minutes; and, when possible, 180 and 240 minutes after injection. In eight courses, urine was collected as 4-hour aliquots for 24 hours after therapy. All samples were analyzed for thiotepa and tepa by gas-liquid chromatography. Urinary alkylating activity was assessed spectrophotometrically after reaction with 4-(p-nitrobenzyl)-pyridine. Plasma concentrations of thiotepa declined in a biexponential fashion with an alpha-half-life of 7.7 +/- 1.2 minutes and a beta-half-life of 125 +/- 21 minutes. Total-body clearance of thiotepa was 186 +/- 20 ml/minute/m2. The volume of the central compartment was calculated as 0.25 +/- 0.04 L/kg, and the steady-state volume of distribution was calculated as 0.70 +/- 0.11 L/kg. Tepa was detectable in plasma by 5 minutes after the injection of thiotepa. Tepa concentrations increased from 0.093 +/- 0.068 to 0.127 +/- 0.11 micrograms/ml over the 240-minute collection period. By 120 minutes, the concentration of tepa equaled that of thiotepa, and tepa persisted longer in the plasma than did thiotepa. During the first 24 hours after injection, urinary excretion of thiotepa, tepa, and alkylating activity accounted for 1.5%, 4.2%, and 23.5% of the administered dose, respectively. These results extend our laboratory's previous animal studies of thiotepa and argue for metabolism of thiotepa to tepa as a major mechanism of clearance of this compound. Further metabolism or breakdown of both compounds may explain the urinary excretion of alkylating materials other than parent compound and tepa.