Distribution of suramin, an antitrypanosomal drug, across the blood-brain and blood-cerebrospinal fluid interfaces in wild-type and P-glycoprotein transporter-deficient mice.

Although 60 million people are exposed to human African trypanosomiasis, drug companies have not been interested in developing new drugs due to the lack of financial reward. No new drugs will be available for several years. A clearer understanding of the distribution of existing drugs into the brains of sleeping sickness patients is needed if we are to use the treatments that are available more safely and effectively. This proposal addresses this issue by using established animal models. Using in situ brain perfusion and isolated incubated choroid plexus techniques, we investigated the distribution of [(3)H]suramin into the central nervous systems (CNSs) of male BALB/c, FVB (wild-type), and P-glycoprotein-deficient (Mdr1a/Mdr1b-targeted mutation) mice. There was no difference in the [(3)H]suramin distributions between the three strains of mice. [(3)H]suramin had a distribution similar to that of the vascular marker, [(14)C]sucrose, into the regions of the brain parenchyma that have a blood-brain barrier. However, the association of [(3)H]suramin with the circumventricular organ samples, including the choroid plexus, was higher than that of [(14)C]sucrose. The association of [(3)H]suramin with the choroid plexus was also sensitive to phenylarsine oxide, an inhibitor of endocytosis. The distribution of [(3)H]suramin to the brain was not affected by the presence of other antitrypanosomal drugs or the P-glycoprotein efflux transporter. Overall, the results confirm that [(3)H]suramin would be unlikely to treat the second or CNS stage of sleeping sickness.

The pharmacokinetics of eflornithine (alpha-difluoromethylornithine) in patients with late-stage T.b. gambiense sleeping sickness.

OBJECTIVE: To investigate the plasma, cerebrospinal fluid (CSF) levels and pharmacokinetics of eflornithine (DFMO) in patients with late-stage T.b. gambiense sleeping sickness who were treated with an oral DFMO at 100 mg/kg or 125 mg/kg body weight every 6 h for 14 days. METHODS: Plasma and CSF concentrations of DFMO were measured during day 10 and day 15 in patients following oral DFMO at 100 mg/kg (group I: n=12) and 125 mg/kg (group II: n=13) body weight every 6 h for 14 days. Clinical and parasitological assessments were performed at 24 h after the last dose of DFMO and at 12 months. RESULTS: Patients in each group had a good initial response, but relapse was observed in six patients (three patients for each group) during 12 months follow-up. Plasma DFMO concentrations did not increase proportionally to doses when the dose increased from 100 mg/kg to 125 mg/kg body weight given every 6 h (60-70% of the expected increase). In most cases, concentration-time profiles of DFMO in each group were best fit using a two-compartment open model with first-order input, with absorption lag-time and first-order elimination. Average trough (C(ss-min)) and average (C(ss-ave)) plasma DFMO concentrations during steady state varied between 189-448 nmol/ml and 234-528 nmol/ml, following 100 mg/kg and 125 mg/kg dose group, respectively. C(max), t(max) and AUC(0- infinity ) values following the last dose were 296-691 nmol/l, 2-3 h, and 2911-6286 nmol h/ml, respectively. V(z)/F, CL/F and t(1/2z) values were 0.47-2.66 l/kg, 0.064-0.156 l/h/kg, and 3.0-16.3 h, respectively. CSF concentrations at steady state varied between 22.3 nmol/ml and 64.7 nmol/ml. Patients who had treatment failure tended to have lower plasma and CSF DFMO concentrations than those who had successful treatment. CONCLUSION: Oral DFMO at the dose of 125 mg/kg body weight given every 6 h for 14 days may not produce adequate therapeutic plasma and CSF levels for patients with late-stage T.b. gambiense sleeping sickness.

The phenomenon of treatment failures in Human African Trypanosomiasis.

Treatment of Human African Trypanosomiasis (HAT or sleeping sickness) relies on a few drugs which are old, toxic and expensive. The most important drug for the treatment of second stage infection is melarsoprol. During the last 50 years treatment failures with melarsoprol were not a major problem in Trypanosoma brucei gambiense patients. Commonly a relapse rate of 5-8% was reported, but in recent years it has increased dramatically in some important foci of T. b. gambiense sleeping sickness. Treatment failures for T. b. rhodesiense are much less of a problem apart from some reports between 1960 and 1985 of refractoriness in T. b. rhodesiense patients in East Africa. Analysis of those isolates revealed that their in vitro sensitivity to melarsoprol was one-tenth that of sensitive isolates, and complete failure to cure the infection in the acute mouse model with melarsoprol levels comparable with those in human patients. There was very little indication of resistance in T. b. gambiense isolates from Côte d'Ivoire and NW Uganda. The in vitro melarsoprol sensitivities for populations from relapsing and from curable patients were in the same range. Melarsoprol concentrations in the plasma and cerebrospinal fluid of patients 24 h after treatment did not show any difference between patients who relapsed and those who could be cured. The reason for relapses in the recent T. b. gambiense epidemics are not known. Other parasite-related factors might be involved, e.g. affinity to extravascular sites other than the CNS which are less accessible to the drug. In conclusion, a combination of factors rather than a single one may be responsible for the phenomenon of melarsoprol treatment failures in T. b. gambiense patients.

Investigations of the metabolites of the trypanocidal drug melarsoprol.

BACKGROUND: Melarsoprol remains the first-choice drug for trypanosomiasis (human African sleeping sickness). To contribute to the sparse pharmacologic data and to better understand the cause of the frequent serious adverse reactions, we investigated the metabolism of this 50-year-old organoarsenic compound. RESULTS: The half-life of melarsoprol determined by HPLC was <1 hour compared with 35 hours determined by bioassay and atomic absorption spectroscopy, indicating the existence of active metabolites. One metabolite, melarsen oxide, was identified by ultraviolet HPLC after incubation of melarsoprol with microsomes. The maximum plasma concentration of melarsenoxide was reached 15 minutes after administration; the clearance was 21.5 mL/min/kg and the half-life of free melarsen oxide was 3.9 hours. Either melarsen oxide or a yet-undiscovered active metabolite is irreversibly bound to proteins, as shown by ultrafiltration, precipitation experiments, and atomic absorption spectroscopy. Because of the poor pharmaceutical properties of melarsoprol, the therapeutic potential of melarsen oxide was investigated. In a rodent model of acute infection, 20 of 20 mice were cured (0.1 to 1 mg/kg intravenously or 2.2 mg/kg intraperitoneally). In a rodent model of central nervous system infection, five of six mice survived for more than 180 days (5 mg/kg intravenously), indicating a sufficient melarsen oxide penetration across the blood-brain barrier. CONCLUSION: The prospects for the future of trypanosomiasis treatment are deplorable. Investigations on the improvement of the use of the old drugs are therefore required. The results of this study may build a basis for further research on the cause of severe adverse reactions.

An automated biological assay to determine levels of the trypanocidal drug melarsoprol in biological fluids.

For the investigation of the pharmacokinetic properties of a drug, methods for sensitive and precise quantification are a prerequisite. Only few functional methods exist for the determination of the trypanocidal drug melarsoprol in biological fluids: A bioassay which requires microscopical evaluation and two HPLC methods, which require sample extraction and are difficult to automatize due to the drug's properties. We report the development of an automated biological assay, based on the fluorescent dye Alamar blue. To validate the assay for melarsoprol, 108 serum and 37 cerebrospinal fluid (CSF) samples were spiked with melarsoprol at concentrations of 17-92 ng/ml for CSF and 17 ng/ml-2.2 microg/ml for serum. The precision (repeatability) expressed as the interday average coefficient of variation was 9.9% for serum and 18.8% for CSF samples over the respective concentration range. The accuracy (measurement for the systematic error) of the test was 99.4% for serum and 96.4% for CSF. The assay's limit of quantitation with the use of the trypanosome stock STI 704 BABA was 4 ng/ml for both serum and CSF samples.

Determination of melarsoprol in biological fluids by high-performance liquid chromatography and characterisation of two stereoisomers by nuclear magnetic resonance spectroscopy.

The analysis of melarsoprol in whole blood, plasma, urine and cerebrospinal fluid is described. Extraction was made with a mixture of chloroform and acetonitrile followed by back-extraction into phosphoric acid. A reversed-phase liquid chromatography system with ultraviolet detection was used. The relative standard deviation was 1% at concentrations around 10 mumol/l and 3-6% at the lower limit of determination (9 nmol/l in plasma, 93 nmol/l in whole blood, 45 nmol/l in urine and 10 nmol/l in cerebrospinal fluid). Melarsoprol is not a stable compound and samples to be stored for longer periods of time should be kept at -70 degrees C. Plasma samples can be stored at -20 degrees C for up to 2 months. Chromatography showed that melarsoprol contains two components. Using nuclear magnetic resonance spectroscopy the two components were shown to be diastereomers which slowly equilibrate by inversion of the configuration at the As atom.

ELISA assay for melarsoprol.

A sensitive ELISA method has been developed for measuring the trypanocidal drug melarsoprol. The test allows for the detection of the drug in human sera and in cerebrospinal fluid at the ng/ml level. Preliminary analyses on patient sera and CSF confirm the feasibility of the method. Further application of the test will enable to conduct the necessary pharmacokinetic and metabolic studies; the drug monitoring should hopefully result in improved treatment schedules minimizing the undesired side effects, e.g. lethal encephalopathies.