In vitro and in vivo evaluation of 28DAP010, a novel diamidine for treatment of second-stage African sleeping sickness.

African sleeping sickness is a neglected tropical disease transmitted by tsetse flies. New and better drugs are still needed especially for its second stage, which is fatal if untreated. 28DAP010, a dipyridylbenzene analogue of DB829, is the second simple diamidine found to cure mice with central nervous system infections by a parenteral route of administration. 28DAP010 showed efficacy similar to that of DB829 in dose-response studies in mouse models of first- and second-stage African sleeping sickness. The in vitro time to kill, determined by microcalorimetry, and the parasite clearance time in mice were shorter for 28DAP010 than for DB829. No cross-resistance was observed between 28DAP010 and pentamidine on the tested Trypanosoma brucei gambiense isolates from melarsoprol-refractory patients. 28DAP010 is the second promising preclinical candidate among the diamidines for the treatment of second-stage African sleeping sickness.

Comparison of nanosuspensions and hydroxypropyl-beta-cyclodextrin complex of melarsoprol: pharmacokinetics and tissue distribution in mice.

The aim of this work was to develop and compare two formulations of melarsoprol (nanosuspension and hydroxypropyl-beta-cyclodextrin inclusion complex). The arsenic concentrations in the organs have been assessed on a mouse model. Since this organoarsenical drug has been proposed for the treatment of cerebral trypanosomiasis and refractory leukaemias, special emphasis has been put on the bone marrow and on the brain. The organic solution of melarsoprol (Mel B, 0.039mmol/kg), injected intravenously as control formulation, was found to concentrate significantly in the bone marrow (C(max)=1.64mmol/g), though, not surprisingly, the brain concentration was quite high (C(max)=0. 093mmol/g) and the LD(50) was 0.12mmol/kg. The hydroxypropyl-beta-cyclodextrin inclusion complex was found to concentrate much more in the brain (C(max)=0.25mmol/g) leading to a higher acute toxicity (i.e., lower LD(50); 0.056mmol/kg). Nevertheless, even if the encephalopathy risk has to be taken in to account, this could be considered as a positive point for the treatment of the cerebral trypanosomiasis, which is the main indication for this drug. On the contrary, the use of nanosuspensions allowed us to reduce the cerebral concentration (C(max)=0.02micromol/g) and the acute toxicity (LD(50)=0.25mmol/kg). Moreover, nanosuspensions, especially those prepared with polxamer 407, preserved a good in vitro antileukemic activity (IC(50)=3.34+/-0.33 after 48h on K562) with high bone marrow concentrations (C(max)=1.85micromol/g). As a consequence this formulation could be proposed for the treatment of refractory leukaemias.

Current chemotherapy of human African trypanosomiasis.

Human African trypanosomiasis is a fatal disease caused by Trypanosoma brucei gambiense and Trypanosoma brucei rhodesiense that has re-emerged in recent years. However, very little progress has been made in the development of new drugs against this disease. Most drugs still in use were developed one or more decades ago, and are generally toxic and of limited effectiveness. The most recently introduced compound, eflornithine, is only useful against sleeping sickness caused by T. b. gambiense, and is prohibitively expensive for the African developing countries. We present here an overview of today's approved and clinically used drugs against this disease.

Arsenicals (melarsoprol), pentamidine and suramin in the treatment of human African trypanosomiasis.

Human African trypanosomiasis (HAT), otherwise known as sleeping sickness, has remained a disease with no effective treatment. Recent progress in HAT research suggests that a vaccine against the disease is far from being successful. Also the emergence of drug-resistant trypanosomes makes further work in this area imperative. So far the treatment for the early stage of HAT involves the drugs pentamidine and suramin which have been very successful. In the second stage of the disease, during which the trypanosomes reside in the cerebrospinal fluid (CSF), treatment is dependent exclusively on the arsenical compound melarsoprol. This is largely due to the inability to find compounds that can cross the blood brain barrier and kill the CSF-residing trypanosomes. This review summarises our current understanding on the treatment of HAT.

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.

Melarsoprol refractory T. b. gambiense from Omugo, north-western Uganda.

Culture adapted T. b. gambiense isolated from Northwest Uganda were exposed to 0.001-0.14 microg/ml melarsoprol or 1.56-100 microg/ml DL-alpha-difluoromethylornithine (DFMO). Minimum inhibitory concentrations (MICs) of each drug were scored for each isolate after a period of 10 days drug exposure. The results indicate that T. b. gambiense isolates from Northwest Uganda had elevated MIC values for melarsoprol ranging from 0.009 to 0.072 microg/ml as compared with T. b. gambiense isolates from Cote d'Ivoire with MIC values ranging from 0.001 to 0.018 microg/ml or with T. b. rhodesiense from Southeast Uganda with MIC values from 0.001 to 0.009 microg/ml. All MIC values obtained fell below expected peak melarsoprol concentrations in serum of treated patients. However, it may not be possible to maintain constant drug concentrations in serum of patients as was the case in our in vitro experiments. Importantly, the MIC of 0.072 microg/ml exhibited by one of the isolates from Northwest Uganda was above levels attainable in CSF indicating that this isolate would probably not be eliminated from CSF of treated patients. PCR amplification of the gene encoding the P2-like adenosine transporter followed by restriction digestion with Sfa NI enzyme revealed presence of fragments previously observed in a trypanosome clone with laboratory-induced arsenic resistance. From our findings it appears that reduced drug susceptibility may be one factor for the frequent relapses of sleeping sickness after melarsoprol treatment occurring in Northwest Uganda.

Pharmacokinetic investigations in patients from northern Angola refractory to melarsoprol treatment.

Melarsoprol, an organo-arsenical drug, has been the drug of choice for late-stage trypanosomiasis for 50 years. Because of the lack of alternatives any abatement of this medication will have a dramatic negative impact on the perspectives for patients. As a large number of patients refractory to melarsoprol treatment was recently reported from northern Uganda and northern Angola, we investigated in northern Angola whether interpatient pharmacokinetic differences influence the outcome of melarsoprol treatment. Drug levels were determined by a biological assay in serum and cerebrospinal fluid (CSF) of 22 patients. Nine patients could be successfully treated, eight were refractory and the outcome was unclear or no adequate follow-up information was available for five patients. No differences in the pharmacokinetic parameters (maximum serum concentration Cmax, half-life t1/2 beta, total clearance CL and the volume of distribution Vss) could be detected between the groups. Serum and CSF concentrations for all patients were in the expected range. This result indicates that other underlying factors are responsible for treatment failures.

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.

Role of glutathione in the biliary excretion of the arsenical drugs trimelarsan and melarsoprol.

After administration of the inorganic sodium arsenite or arsenate to rats, the biliary excretion of arsenic is rapid, is accompanied by the biliary output of large amounts of GSH, and is completely arrested by the GSH depletor diethyl maleate (DEM). We studied the biliary excretion of trimelarsan (TMA) and melarsoprol (MAP) in rats in order to determine whether biliary excretion is also significant in the disposition of these trivalent organic arsenicals that are used as therapeutic agents and whether GSH is also involved in their hepatobiliary transport. After injection of either drug (100 micromol/kg, i.v.), arsenic was rapidly excreted in bile (up to 1 micromol/kg. min, approximately 55% of dose/100 min). Concurrently, TMA and MAP increased the biliary output of GSH 3- and 6 fold, and lowered the hepatic GSH content by 24% and 27%, respectively. In TMA-injected rats, pretreatment with DEM or buthionine sulfoximine decreased the initial biliary excretion of arsenic by 75% and 40%, respectively, whereas in MAP-injected rats these GSH depletors diminished arsenic output by 45% and 20%. Both arsenicals reacted with GSH in vitro, giving rise to the same product, which was also shown by HPLC analysis to be a major biliary metabolite of both TMA and MAP. This metabolite was sensitive to gamma-glutamyltranspeptidase in vitro and its biliary excretion was virtually prevented by the GSH depletors, confirming that it is a GSH conjugate (purportedly melarsen-diglutathione). Some TMA was excreted in the bile unchanged, whereas a significant amount of MAP also appeared there as two glucuronides. The biliary excretion of unchanged TMA and MAP glucuronides was increased by experimental depletion of GSH. These studies indicate that the biliary excretion of TMA and MAP (1) is very significant in their disposition, (2) is partially dependent on the hepatic availability of GSH, as these arsenicals are excreted in part as a GSH conjugate, and (3) is concomitant with the increased appearance of GSH in bile, probably originating from dissociation of the unstable GSH conjugate of these arsenicals. Thus, conjugation with GSH is important in the elimination of both TMA and MAP, although glucuronidation is also involved in the fate of MAP.

Clinical study of an organic arsenical, melarsoprol, in patients with advanced leukemia.

Inorganic arsenic trioxide (As(2)O(3)) induces a high proportion of complete remissions in relapsed patients with acute promyelocytic leukemia (APL). Previously, we have shown that both As(2)O(3 )and melarsoprol, an organic arsenical used for the treatment of trypanosomiasis, exhibit broad antileukemic activity against both chronic and acute myeloid and lymphoid leukemia cell lines. Given the breadth of this activity, we initiated a clinical study to evaluate the pharmacokinetics, safety, and potential efficacy of melarsoprol in patients with refractory or resistant leukemia. Using the antitrypanosomal dose and schedule, patients received escalating intravenous doses daily for 3 days, repeated weekly for 3 weeks. Doses were 1 mg/kg on day 1, 2 mg/kg on day 2, and 3.6 mg/kg on day 3 and on all days thereafter, up to a maximum daily dose of 200 mg. Eight patients [6 AML (2 morphologic APL), 1 CML, 1 CLL] were treated. Mean peak plasma concentrations of the parent drug were obtained immediately after injection, ranged from 1.2 microg/ml on day 1 to 2.4 microg/ml on day 3, were dose proportional, and decayed with a t(1/2) congruent with 15 min. A minor clinical response (regression of splenomegaly and lymphadenopathy) was observed in a patient with chronic lymphocytic leukemia. Central nervous system (CNS) toxicity proved limiting on this dose and schedule. Three patients experienced generalized grand mal seizures during the second week of therapy. We concluded that this dose and schedule of melarsoprol is associated with excessive CNS toxicity and that verification of the striking preclinical activity in patients with leukemia will require developing an alternative dose and schedule.

The importance of 2,3-dimercaptopropinol (British anti-lewisite, BAL) in the trypanocidal activity of topical melarsoprol.

Both melarsomine dichlorhydrate (mel Cy, Cymelarsan) and melarsen oxide can be dissolved in dimethylsulfoxide and converted into a gel by the addition of hydroxypropylcellulose. When Trypanosoma brucei brucei-infected mice are treated topically with these gels the circulating trypanosomes are rapidly cleared from the circulation but the infections relapse soon after the last application. However, when these two compounds are allowed to react with 2,3-dimercaptopropinol (British anti-lewisite, BAL) and form "melarsoprol" their efficacy, especially in the case of mel Cy, is restored to that of commercial melarsoprol (Arsobal) and trypanosomes in the central nervous system (CNS) can be eliminated. This would indicate that the dimercaptopropinol portion of the molecule does not act solely as an "antidote" to arsenic toxicity, but also plays an important role in the absorption of melarsoprol through the skin and/or blood-brain barrier into the CNS and/or into the trypanosome.

Pharmacokinetics of melarsoprol in uninfected vervet monkeys.

The level of the trypanocidal drug melarsoprol was determined in serum and cerebrospinal fluid (CSF) of six healthy vervet monkeys after intravenous application of the drug following a standard treatment schedule and a recently suggested alternative protocol. The maximum serum levels measured were about 3 micrograms/ml. A three-compartment model was used to analyze the serum data. The mean residence time calculated for melarsoprol in serum was 18 h, the volume of distribution was 3.6 l/kg and the clearance was 3.5 ml/min*kg. In the CSF the drug levels were generally very low, not exceeding 55 ng/ml, and the adaptation of the drug levels was found to be very low. The comparison of the drug concentrations required to eliminate trypanosomes in vitro and the drug concentrations reached in the CSF during treatment revealed that the latter might be insufficient in some cases to eliminate all trypanosomes from this site. The peak serum levels during alternative application of the drug were lower compared to those during empirical treatment. No evidence for drug cumulation in the body was found. The results of this study are compared with recent pharmacokinetic data from human patients, and discussed in the context of the problem of relapses and reactive encephalopathy occurring after treatment of sleeping sickness.

[Current therapy of trypanosomiasis]. / Actualités thérapeutiques de la trypanosomiase.

The authors review the available products used for human african trypanosomiasis (HAT) chemotherapy: pentamidine, suramin, melarsoprol and the new compound DFMO. The administration of pentamidine at the beginning of the nervous stage, when the number of cells in the cerebrospinal fluid do not exceed 20/mn3 is a new approach for HAT treatment. At this time of the disease, patients generally are healthy and the pentamidine therapy avoids the use of the toxic melarsoprol (Arsobal). An alternative protocol for Arsobal therapy (2, 16 mg/kg/d for 10 consecutive days) has been described from pharmacokinetics data to decrease the rate of relapses and the duration of hospital care. Efficacy and tolerance of this new protocol must be evaluated by randomised clinical trials. Preliminary data of clinical trials using short-term DFMO therapy are encouraging. DFMO therapy be less expensive. From its efficacy and tolerance, DFMO is a choice chemotherapy for HAT treatment, especially in the case of resistance to usual trypanocides. Both MLD 73811 and IMOL 881 are new trypanocidal compounds, effective on Trypanosoma brucei rhodesiense and T. b. gambiense. In addition, IMOL 881 is effective on the animal trypanosomes, T. evansi and T. equiperdum. Waiting for the availability of these new products, classical trypanocides remain the basis of HAT treatment.

Pharmacokinetic properties of the trypanocidal drug melarsoprol.

With a biological assay and atomic absorption spectrometry we determined the level of melarsoprol in the serum and cerebrospinal fluid of 19 patients treated with melarsoprol in Daloa, Ivory Coast. Most serum levels were between 2 and 4 micrograms/ml 24 h after administration, and were still > or = 0.1 microgram/ml after 120 h. Levels in the cerebrospinal fluid were between 0 and 0.1 microgram/ml. Elimination was biphasic, with a pronounced beta 1 phase. Mean terminal elimination half-life of melarsoprol was about 35 h, volume of distribution was about 100 l and total clearance was about 50 ml/min. The results of these first pharmacokinetic studies on melarsoprol were used to simulate possible alternative therapy schemes which might avoid some of the problems that arise with melarsoprol use.