Plasmodium vivax is the most geographically widespread malaria species and the second largest contributor to symptomatic malaria worldwide. It accounts for half of all malaria cases outside Africa, with an estimated 14.3 million clinical vivax malaria cases reported annually, contributing to an annual cost of US$359 million. Children are most vulnerable to infection, with P. vivax prevalence peaking between 2 to 6 years of age. In Papua New Guinea (PNG), there are \>1.5 million suspected P. vivax cases annually, and while P. falciparum infections are the most prevalent, P. vivax transmission is the most intense in the world. P. vivax in PNG provides a unique epidemiological setting in which to assess innovative treatments in children.The complex biology of P. vivax represents a challenge for malaria control and chemotherapy, especially dormant liver-stage parasites (hypnozoites) which can reactivate (relapse) and cause disease at a time remote from the primary infection. Hypnozoite relapse is the primary cause of vivax malaria in endemic regions and is resistant to most antimalarial drugs. Identifying effective treatments for radical cure, the complete elimination of parasites (both blood- and liver-stage), is therefore a priority. The World Health Organization (WHO) recommends a 14-day radical cure regimen for uncomplicated vivax malaria; comprised of blood stage treatment (chloroquine or artemisinin combination therapy (ACT)) and 14 days of the 8-aminoquinoline drug primaquine (PQ; 0.25-0.5 mg/kg/day) for liver-stage cure. More recently, the 8-aminoquinoline tafenoquine has garnered interest as an alternative radical cure agent to primaquine. However, there is limited data on the pharmacokinetics, tolerability and radical cure efficacy of tafenoquine in children. Furthermore, early data suggest a drug interaction between TQ and artemisinin combination therapy (ACT) drugs - which requires further investigation and confirmation. This study will generate critical paediatric safety, tolerability, pharmacokinetic, and preliminary efficacy data for TQ when administered with either artemether-lumefantrine or dihydroartemisinin-piperaquine in PNG children with uncomplicated malaria.
Age range
2 Years – 12 Years
Sex
ALL
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Pharmacokinetic: Tafenoquine terminal elimination half-life
Timeframe: 56-days after tafenoquine administration
Pharmacokinetic: Tafenoquine distribution half-life
Timeframe: 56-days after tafenoquine administration
Pharmacokinetic: Tafenoquine absorption half-life
Timeframe: 56-days after tafenoquine administration
Pharmacokinetics: Tafenoquine clearance
Timeframe: 56-days after tafenoquine administration
Pharmacokinetics: Tafenoquine volume of distribution
Timeframe: 56-days after tafenoquine administration
Pharmacokinetic: Tafenoquine maximal concentration
Timeframe: 56-days after tafenoquine administration
Pharmacokinetics: Tafenoquine area under concentration-time curve
Timeframe: 56-days after tafenoquine administration