The potential of artemether for the control of schistosomiasis

Schistosoma japonicum: In vitro effects of artemether combined with haemin depend on cultivation media and appraisal of artemether products appearing in the media

We recently found that the exposure of schistosomes in vitro to artemether plus haemin can lead to parasite death, while exposure to each compound singly had no effect. Since these observations might be relevant to understanding the mechanism of action of artemether against schistosomes, we conducted additional experiments. First, we performed a comparative appraisal of Schistosoma japonicum survival after incubation in two media, namely Hanks' balanced salt solution (HBSS) and RPMI 1640, supplemented with inactivated calf serum, antibiotics and different concentrations of artemether and/or haemin. Worm mortalities were consistently higher and occurred faster in HBSS when compared to RPMI 1640. Second, we investigated the behaviour of artemether in different chemical systems, including reduced glutathione or cysteine, in the presence of haemin or ferrous sulfate. Cleavage of the endoperoxide bridge of artemether occurred in all experiments, consistently forming five different products, of which one has not been described previously. Third, RPMI 1640 and HBSS media were supplemented with artemether and haemin in the presence of S. japonicum. The consumption of artemether in RPMI 1640 was much faster than in HBSS. Trace amounts of artemether and five free radical reaction products of artemether could be detected in RPMI 1640 after 24-48 h. In contrast, large amounts of artemether remained without the formation of free radical products in HBSS under the same conditions. These findings coincide with significantly higher schistosome mortalities employing HBSS instead of RPMI 1640. Our results suggest that it is artemether or an active metabolite thereof (most likely a carbon-centred free radical), rather than any free radical reaction product that is harmful for the worms. We speculate that schistosomes ingest artemether and cleave it in their gut. This cleavage is induced by haemin or another iron-containing molecule. These findings might be a further step forward in elucidating the mechanism of action of artemether against schistosomes.

Efficacy and side-effects of two praziquantel treatments against Schistosoma haematobium infection, among schoolchildren from Côte d'Ivoire

Praziquantel is the current drug of choice for the control of schistosome-attributable morbidity and is likely to remain so for several years. However, as there is concern that schistosomes might develop resistance to the drug, the monitoring of praziquantel's efficacy in different epidemiological settings is recommended. Here, the results of an innovative study of the drug's effectiveness, in an area in Côte d'Ivoire that is highly endemic for Schistosoma haematobium, are reported. Each of the subjects (354 schoolchildren aged 5-15 years) was given two oral doses of praziquantel (each of 40 mg/kg) 4 weeks apart. The numbers of schistosome eggs in urine samples collected over several consecutive days prior to the first and after the second treatment were then determined. High cure and egg reduction 'rates', of 93.0% and 96.6%, respectively, were found. Although mild and transient side-effects were frequently observed after the first treatments, no severe systemic complaints were recorded. When the 20 children who remained egg-positive after the second dose were each given a third dose of praziquantel, 16 (80%) of them responded and became egg-negative. Unfortunately, the schistosome strains infecting the remaining four children could not be investigated in detailed laboratory studies, because of the failure of eggs to hatch. There were therefore no unambiguous signs of resistance to praziquantel in this epidemiological setting. The benefits and disadvantages, compared with single-dose treatments, of administering praziquantel twice within a few weeks are discussed. It is anticipated that this approach might prove efficacious in areas of high infection intensity. The integration of such pharmaceutical measures with other readily available control tools is likely to mitigate the current, intolerable burden of schistosomiasis.

Artemisinin: mechanisms of action, resistance and toxicity

Artemisinin and its derivatives are widely used throughout the world. The mechanism of action of these compounds appears to involve the heme-mediated decomposition of the endoperoxide bridge to produce carbon-centred free radicals. The involvement of heme explains why the drugs are selectively toxic to malaria parasites. The resulting carbon-centred free radicals are alkylate heme and proteins, one of which is the translationally controlled tumour protein. Clinically relevant artemisinin resistance has not been demonstrated, but it is likely to occur since artemisinin resistance has been obtained in laboratory models. At high doses, artemisinin can be neurotoxic but toxicity has not been found in clinical studies. The mechanism of neurotoxicity may be similar to the mechanism of action.

Schistosoma japonicum: effect of artemether on glutathione S-transferase and superoxide dismutase

Glutathione S-transferase (GST) and superoxide dismutase (SOD) are major antioxidant enzymes of schistosomes that are involved in detoxification processes. To study the effect of artemether on these enzymes, mice infected with adult Schistosoma japonicum, were treated with artemether either at a subcurative (100 mg/kg) or a curative dose (300 mg/kg). Schistosomes were recovered 24-72 h post-treatment separated by sex and used for GST and SOD activity measurements. Female worms showed consistently higher GST inhibitions than males. For instance, 24 h after administration of 100 mg/kg artemether, GST activities of female worms were inhibited by 23.3%, as compared to 12.7% in males. Both activities were significantly lower when compared to worms recovered from untreated mice. Slightly higher inhibitions were observed at the higher dose of artemether, which gradually increased to levels of 52.5-55.1%, 72 h post-treatment. GST inhibitions could be reversed by application of 1,4-dithiothreitol at a concentration of 10 mmol/L. Adding L-cysteine also reduced GST inhibitions, but in female worms, GST activities remained significantly higher than in worms from untreated animals. Administration of 300 mg/kg artemether resulted in significant reductions of SOD activities in both sexes. In conclusion, these results suggest that the inhibition of GST and, to a lesser extent also SOD enzymes, could lead to increased schistosome susceptibility to oxidant attacks and might be linked with the antischistosomal action of artemether.

Ultrastructural alterations in adult Schistosoma mansoni caused by artemether

Progress has been made over the last decade with the development and clinical use of artemether as an agent against major human schistosome parasites. The tegument has been identified as a key target of artemether, implying detailed studies on ultrastructural damage induced by this compound. We performed a temporal examination, employing a transmission electron microscope to assess the pattern and extent of ultrastructural alterations in adult Schistosoma mansoni harboured in mice treated with a single dose of 400 mg/kg artemether. Eight hours post-treatment, damage to the tegument and subtegumental structures was seen. Tegumental alterations reached a peak 3 days after treatment and were characterized by swelling, fusion of distal cytoplasma, focal lysis of the tegumental matrix and vacuolisation. Tubercles and sensory organelles frequently degenerated or collapsed. Typical features of subtegumental alterations, including muscle fibres, syncytium and parenchyma tissues, were focal or extensive lysis, vacuolisation and degeneration of mitochondria. Severe alterations were also observed in gut epithelial cells and vitelline cells of female worms. Our findings of artemether-induced ultrastructural alterations in adult S. mansoni confirm previous results obtained with juvenile S. mansoni and S. japonicum of different ages.

Schistosomiasis: from risk assessment to control

In this article, an account of some of the hot areas in schistosomiasis research is given, emphasizing what has been achieved during the past several years in impact assessment and identifying the research frontiers where further action is needed.

Comparative study of the effects of artemether and artesunate on juvenile and adult Schistosoma mansoni in experimentally infected mice

Artemether and artesunate, derivatives of the antimalarial artemisinin, also exhibit antischistosomal properties. There is a need to assess comparatively the activity of both compounds against different developmental stages of schistosome parasites. Since artemisinin derivatives will be increasingly used to treat malaria, it is important to study the effects of 7-day monotherapy regimens on schistosome infections. We carried out experiments with mice, infected with juvenile or adult Schistosoma mansoni, and treated with artemether or artesunate at various doses and regimens including those currently used for monotherapy of malaria. Three doses of artemether, at concentrations of 150 or 300 mg/kg, administered to mice with juvenile S. mansoni resulted in worm reductions of 88-97%, which were significantly higher than the 67-77% obtained with artesunate (P < 0.05). Total concentrations of 600 or 800 mg/kg artemether, administered over 2 or 4 consecutive days to mice with adult S. mansoni, reduced the worm burden significantly by 46-51% (P < 0.05). The reduction of the worm burden observed with artesunate was considerably lower, 24-33%, and not significant when compared with untreated control mice. Seven-day monotherapy regimens of artemether or artesunate given at different concentrations to mice with adult S. mansoni showed total worm reductions of 53-61% or 34-49%, respectively. We conclude that artemether and artesunate are efficacious antischistosomal agents, with artemether displaying consistently higher activities. Our findings may contribute to the current strategic discussions on the effect and use of artemisinin derivatives against schistosomes when they are used in malaria chemotherapy in areas of co-endemicity of both parasites.

Recent investigations of artemether, a novel agent for the prevention of schistosomiasis japonica, mansoni and haematobia

Two decades ago, a group of Chinese scientists discovered the antischistosomal properties of artemether, a derivative of the antimalarial drug artemisinin. However, it was only recently that the importance of this finding was recognized internationally, following a collaborative effort between Chinese, European and African scientists, who investigated the effects of artemether against the major human schistosome species. Laboratory studies revealed that artemether exhibits the highest activity against juvenile stages of the parasites, while adult worms are significantly less susceptible. There was no indication of neurotoxicity following repeated high doses of artemether given fortnightly for up to 5 months. Randomized controlled clinical trials confirmed that artemether, orally administered at a dose of 6 mg/kg once every 2-3 weeks, results in no drug-related adverse effects, and significantly reduces the incidence and intensity of schistosome infections. The risk that these treatment regimens might select for resistance, particularly for resistant-plasmodia, appears to be low. Combined treatment with artemether and praziquantel, given to animals harbouring juvenile and adult schistosome worms, resulted in significantly higher worm burden reductions than each drug administered singly. In conclusion, artemether-integrated with other control strategies-has considerable potential for reducing the current burden of schistosomiasis in different epidemiological settings.

Transmission electron microscopic observations on ultrastructural damage in juvenile Schistosoma mansoni caused by artemether

Artemether, a derivative of the antimalarial artemisinin, has been shown to induce rapid and extensive alteration to the tegument of juvenile Schistosoma japonicum, S. mansoni and S. haematobium. Less is known with regard to ultrastructural damage caused by artemether; therefore, the present work was designed to assess the damage in juvenile S. mansoni. Mice infected with S. mansoni were treated intragastrically with a single dose of 400 mg/kg artemether 21 days post-infection. Between 8 h and 14 days after treatment groups of two mice were sacrificed, and schistosomula recovered for transmission electron microscopic observations. Ultrastructural damage was seen in the tegument, subtegumental musculature, parenchymal tissues and gastrodermis. It was already apparent 8 h after drug administration and increased gradually to reach a peak, 7 days post-treatment. Tegumental alterations were characterised by swelling, vesiculation and degeneration of sensory structures. Damage in subtegumental musculature, parenchymal tissues and gastrodermis included swelling, focal or extensive lysis, and decrease in granular endoplasmatic reticulum. Fourteen days after treatment ultrastructural damage was still seen in most schistosomula, however, there was partial repair in some specimens. The ability of artemether to cause extensive ultrastructural damage to juvenile S. mansoni correlates with its schistosomicidal effects and confirms earlier findings with S. japonicum.