Abstract:
Background: There is renewed acknowledgement that targeting gametocytes is essential for malaria control and elimination efforts. Simple mathematical models were fitted to data from clinical trials in order to determine the mean gametocyte circulation time and duration of gametocyte carriage in treated malaria patients.
Methods: Data were used from clinical trials from East Africa. The first trial compared non-artemisinin combination therapy (non-ACT: sulphadoxine-yrimethamine (SP) plus amodiaquine) and artemisinin-based combination therapy
(ACT: SP plus artesunate (AS) or artemether-lumefantrine). The second trial compared ACT (SP+AS) with ACT in combination with a single dose of primaquine (ACT-PQ: SP+AS+PQ). Mature gametocytes were quantified in peripheral blood samples by nucleic acid sequence based amplification. A simple deterministic compartmental model was fitted to gametocyte densities to estimate the circulation time per gametocyte; a similar model was fitted to gametocyte prevalences to estimate the duration of gametocyte carriage after efficacious treatment.
Results: The mean circulation time of gametocytes was 4.6-6.5 days. After non-ACT treatment, patients were estimated to carry gametocytes for an average of 55 days (95% CI 28.7 - 107.7). ACT reduced the duration of gametocyte carriage
fourfold to 13.4 days (95% CI 10.2-17.5). Addition of PQ to ACT resulted in a further fourfold reduction of the duration of gametocyte carriage.Conclusions: These findings confirm previous estimates of the circulation time of gametocytes, but indicate a much longer duration of (low density) gametocyte carriage after apparently successful clearance of asexual parasites. ACT shortened the period of gametocyte carriage considerably, and had the most pronounced effect on mature
gametocytes when combined with PQ.
Description:
1Department of Infectious & Tropical Diseases, London School of Hygiene &
Tropical Medicine, London, UK, 2Department of Medical Microbiology,
Radboud University Nijmegen Medical Centre, Nijmegen, The Netherlands,
3MRC Centre for Outbreak Analysis & Modelling, Department of Infectious
Disease Epidemiology, Imperial College London, London, UK, 4Kilimanjaro
Clinical Research Institute, Moshi, Tanzania, 5Kenya Medical Research Institute,
Nairobi, Kenya and 6International Centre of Insect Physiology and Ecology,
Mbita, Kenya