Uncomplicated Malaria Clinical Trial
Artemisinin combination therapy (ACT) with artemether lumefantrine (AL) is currently the
first line treatment policy in Tanzania. AL is an efficacious drug that also has the
capacity to reduce malaria transmission to mosquitoes. Nevertheless, there is concern about
the development of parasite resistance against AL and there have been very few clinical
trials that compared different ACT regimens. A recent clinical trial shows that the
combination of dihydroartemisinin-piperaquine (DP) may be more efficacious than AL and may
have a more pronounced beneficial effect on post-treatment malaria transmission. Screening
for molecular markers that are related to parasite susceptibility to ACT drugs and to
post-ACT treatment malaria transmission can assist in preventing the development and spread
of ACT resistance.
In the current study, the investigators compared AL and DP for the treatment of
uncomplicated malaria. The investigators endpoints are
- clinical efficacy
- post-treatment gametocytaemia by molecular techniques
- post-treatment malaria transmission.
2.1 MALARIA AND ITS TRANSMISSION TO MOSQUITOES Malaria is the most important parasitic
disease in the world. Approximately one fourth of the world population is at risk of
contracting the disease, and every year more than 2 million people, mainly young children in
sub-Sahara Africa, die of malaria. Malaria is caused by single-cell (protozoan) parasites of
the genus Plasmodium. Four species can cause human disease: P. falciparum, P. vivax, P.
ovale and P. malariae. The parasites are transmitted between humans by the bite of an
infected female mosquito (Anopheles). Inside the human body, the malaria parasites multiply
rapidly in the liver cells. After approximately six days, parasites leave this organ and
subsequently infect red blood cells (erythrocytes). A next wave of Plasmodium replication
takes place in the erythrocytes, then the red blood cell bursts, followed by infection of
new red blood cells by the parasites. Since this part of the malaria life cycle involves
asexual replication, parasites in this phase are referred to as asexual parasites. A small
fraction of these asexual parasites develop into sexual stage parasites (gametocytes).
Asexual parasites are responsible for malaria morbidity and mortality, while gametocytes
ensure transmission of the parasite from humans to mosquitoes. Malaria transmission takes
place when mature gametocytes are ingested by mosquitoes that are taking a blood meal. Once
ingested, male and female gametocytes merge to form a zygote that develops though an
ookinete stage into an oocyst that can be detected on the mosquito midgut within one week
after feeding. The oocyst will burst and sporozoites are released that migrate to the
mosquito salivary glands. Once the salivary glands are infected with sporozoites, the
mosquito is capable of infecting new human beings.
2.2 MALARIA TREATMENT WITH ARTEMISININ COMBINCATION THERAPY (ACT) Accurate diagnosis
followed by prompt and efficacious treatment is the backbone of any malaria control
programme. However, malaria treatment has been facing huge challenges in recent years. A
number of affordable antimalarial drugs have been used to cure malaria since the 1940s:
these include chloroquine (CQ), sulphadoxine-pyrimethamine (SP; Fansidar®), mefloquine,
amodiaquine (AQ) and quinine. The emergence and spread of resistance to these commonly-used
drugs has been largely responsible for the worsening of the malaria situation observed in
the past few years.
Across the African continent, guidelines have recently been changed. The World Health
Organization (WHO) recommends for falciparum malaria the use of combination therapies,
preferably those containing artemisinin derivatives (ACTs - artemisinin-based combination
therapies). Artemisinin derivatives, e.g. artesunate, artemether and dihydroartemisinin,
being extremely potent antimalarial agents are the ideal partners in combinations with other
antimalarials. ACTs have three demonstrable advantages over conventional therapy, i) they
are efficacious in treating malaria patients, ii) substantially reduce post-treatment
gametocyte carriaga and iii) "protect" the partner drug from selecting resistant parasites.
In Tanzania, both CQ and SP have lost clinical efficacy. CQ was replaced by SP in 2001 and
in the year 2006, SP was officially replaced by Artemether-Lumefantrine (AL: Coartem®). The
policy change to the artemisinin-based drug AL is in line with the WHO recommendations to
shift to ACT as first line antimalarial treatment.
2.3 RESISTANT PARASITES, MALARIA TRANSMISSION AND ACT Parasite resistance against SP has a
genetic background in mutations in the parasite dihydrofolate reductase (dhfr) and
dihydropteroate synthetase (dhps) genes. Single nucleotide polymorphisms (SNPs) in these
genes are associated with clinical treatment failure. There is now also accumulating
evidence that these mutant parasite strains also have a transmission advantage compared to
wildtype parasites. Gametocyte carriage is higher for parasite with mutations in the dhfr
and dhps genes, even if parasites are successfully cleared due to a longer parasite
clearance time. Importantly, these mutant parasites are also more infectious to mosquitoes.
These are worrying findings that may explain the rapid spread of parasite resistance in the
population. The findings also indicate that gametocytes may be used as an early warning
system to indicate the development of parasite resistance: parasite strains that produce
most gametocytes are likely to have a reduced susceptibility to the drug.
So far, ACT has proved to be an efficient tool to reduce the transmission of malaria to
mosquitoes. Compared to monotherapy with SP, ACT reduces post-treatment gametocyte
prevalence and density. This translates in a reduction in post-treatment malaria
transmission. Compared to monotherapy, fewer individuals are infectious to mosquitoes after
ACT treatment and the average number of infected mosquitoes and the oocyst burden in
mosquitoes is reduced. Importantly, ACT does not completely prevent malaria transmission but
may counteract the transmission of mutant parasite strains.
2.4 ACT RESISTANCE There is a genuine fear that resistance against ACTs may develop.
Although there is no direct evidence of full-blown clinical treatment failure of artemisinin
derivatives, there are some worrying findings suggesting a reduced susceptibility of
parasite isolates for ACTs. An increased resistance of parasite isolates to different
artemisinin derivatives was observed in vitro for P. falciparum field isolates from
Cambodia, French Guiana, and Senegal. This resistance was associated with SNPs at codon
S769N of the ATPase6 locus of P. falciparum. In addition, the lumefantrine component of AL
may exert a selective pressure for parasites with a mutation in the parasite multi-drug
resistance 1 gene (Pfmdr1). In general, there is fear that there may be a selection for the
artemisinin partner drugs. Although ACTs are clearly giving hopeful results, it is not yet
evident which combination of drugs provides the best results, especially in the light of
possible artemisinin resistance18. Recently, the combination of
dihydroartemisinin-piperaquine (DP) was found to be superior to AL in reducing the risk of
recurrent parasitaemia and post-treatment gametocytaemia.
Based on the finding that SP resistant parasite strains exhibit a higher gametocyte
production under drug pressure, we hypothesize that gametocytaemia after treatment can be
used to screen for parasites that are most likely to have a reduced susceptibility to ACT.
2. JUSTIFICATION Studies on the development of resistance to ACT and the spread of ACT
resistant parasite strains in the population are extremely relevant from a public health
perspective. If resistance against artemether-lumefantrine or other ACTs develops, there
will be no alternative drug available for first-line treatment. The identification of
predictive markers for ACT resistance will be of great value for the protection of ACT.
Studies on malaria transmission after ACT are of great importance in identifying those
mutations that may eventually cause ACT resistance.
The current study determines the efficacy of two different ACTs with a specific focus on
detecting markers for resistance or reduced susceptibility of parasites to ACTs and the
transmission potential of mutant parasites.
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Allocation: Randomized, Endpoint Classification: Efficacy Study, Intervention Model: Parallel Assignment, Masking: Double Blind (Subject, Caregiver, Outcomes Assessor), Primary Purpose: Treatment
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