Patterns of age-specific mortality in children in endemic areas of sub-Saharan Africa.

Understanding of the age- and season- dependence of malaria mortality is an important prerequisite for epidemiologic models of malaria immunity. However, most studies of malaria mortality have aggregated their results into broad age groups and across seasons, making it hard to predict the likely impact of interventions targeted at specific age groups of children. We present age-specific mortality rates for children aged < 15 years for the period of 2001-2005 in 7 demographic surveillance sites in areas of sub-Saharan Africa with stable endemic Plasmodium falciparum malaria. We use verbal autopsies (VAs) to estimate the proportion of deaths by age group due to malaria, and thus calculate malaria-specific mortality rates for each site, age-group, and month of the year. In all sites a substantial proportion of deaths (ranging from 20.1% in a Mozambican site to 46.2% in a site in Burkina Faso) were attributed to malaria. The overall age patterns of malaria mortality were similar in the different sites. Deaths in the youngest children (< 3 months old) were only rarely attributed to malaria, but in children over 1 year of age the proportion of deaths attributed to malaria was only weakly age-dependent. In most of the sites all-cause mortality rates peaked during the rainy season, but the strong seasonality in malaria transmission in these sites was not reflected in strong seasonality in the proportion of deaths attributed to malaria, except in the two sites in Burkina Faso. Improvement in the specificity of malaria verbal autopsies would make it easier to interpret the age and season patterns in such data

Substantial Contribution of Submicroscopical Plasmodium falciparum Gametocyte Carriage to the Infectious Reservoir in an Area of Seasonal Transmission

BACKGROUND: Man to mosquito transmission of malaria depends on the presence of the sexual stage parasites, gametocytes, that often circulate at low densities. Gametocyte densities below the microscopical threshold of detection may be sufficient to infect mosquitoes but the importance of submicroscopical gametocyte carriage in different transmission settings is unknown. METHODOLOGY/PRINCIPAL FINDINGS: Membrane feeding experiments were carried out on 80 children below 14 years of age at the end of the wet season in an area of seasonal malaria transmission in Burkina Faso. Gametocytes were quantified by microscopy and by Pfs25-based quantitative nucleic acid sequence-based amplification assay (QT-NASBA). The children's infectiousness was determined by membrane feeding experiments in which a venous blood sample was offered to locally reared Anopheles mosquitoes. Gametocytes were detected in 30.0% (24/80) of the children by microscopy compared to 91.6% (65/71) by QT-NASBA (p<0.001). We observed a strong association between QT-NASBA gametocyte density and infection rates (p = 0.007). Children with microscopically detectable gametocytes were more likely to be infectious (68.2% compared to 31.7% of carriers of submicroscopical gametocytes, p = 0.001), and on average infected more mosquitoes (13.2% compared to 2.3%, p<0.001). However, because of the high prevalence of submicroscopical gametocyte carriage in the study population, carriers of sub-microscopical gametocytes were responsible for 24.2% of the malaria transmission in this population. CONCLUSIONS/SIGNIFICANCE: Submicroscopical gametocyte carriage is common in an area of seasonal transmission in Burkina Faso and contributes substantially to the human infectious reservoir. Submicroscopical gametocyte carriage should therefore be considered when implementing interventions that aim to reduce malaria transmission

Sustained use of insecticide-treated curtains is not associated with greater circulation of drug-resistant malaria parasites, or with higher risk of treatment failure among children with uncomplicated malaria in Burkina Faso.

The impact of vector control measures on the evolution of antimalarial drug resistance is an important issue for malaria control programs. We investigated whether the in vivo efficacy of chloroquine (CQ) in children aged 6-59 months with uncomplicated malaria differed in 9 villages that had benefited from long-term use of insecticide-treated curtains (ITCs) and in 9 nearby non-ITC villages. We also compared the prevalence of genetic markers of resistance to CQ and sulfadoxine-pyrimethamine (SP) between the two groups of villages. The study enrolled 1,035 children with uncomplicated malaria and 231 infected but asymptomatic children. After taking account of re-infections, the proportions of children who experienced clinical failure after treatment with CQ were 14% and 19% in ITC and non-ITC villages, respectively (OR = 0.68; 95% CI: 0.39, 1.18). Parasitologic failure was observed in 49% of children in ITC villages and 58% of children in non-ITC villages (OR = 0.71 95%CI: 0.44, 1.13). The proportion of symptomatic children who harbored parasites carrying the pfcrt-76T allele was 43% in ITC villages and 40% in non-ITC villages (OR = 1.09; 95%CI: 0.80, 1.50). The pfmdr1-86Y allele was detected in 31% and 29% of children in the two groups of villages (OR = 1.14; 95%CI: 0.75, 1.72). Triple mutations in the dhfr gene were observed in 12% of children in both groups. No double mutations in the dhps gene were observed. Similar results were observed in asymptomatic children. In this setting, ITC use was not associated with increased circulation of parasites resistant to standard antimalarial drugs, or with a greater risk of treatment failure among children less than 5 years of age

Children in Burkina Faso who are protected by insecticide-treated materials are able to clear drug-resistant parasites better than unprotected children.

BACKGROUND: It has been suggested that reducing exposure to malaria by vector control might impair the development of naturally acquired immunity to malaria. It is also thought that an individual's ability to clear drug-resistant malarial parasites after treatment is enhanced by acquired immunity. METHODS: To investigate the hypothesis that insecticide-treated materials may affect the acquisition of immunity to malaria, we compared the ability of children living in villages in which insecticide-treated curtains (ITCs) had been used for 6-8 years to clear resistant parasites after treatment with chloroquine (CQ) with that of children living in unprotected villages. RESULTS: A total of 1035 children aged 6-59 months with falciparum malaria were treated with CQ; 409 were subsequently identified as carrying parasites with the pfcrt-76T allele. More children from ITC villages cleared parasites harboring this allele than did children from non-ITC villages (34.1% vs. 24.0%; adjusted odds ratio [OR], 1.80 [95% confidence interval {CI}, 1.15-2.80]; P=.01). The difference in the clearance of parasites with the pfcrt-76T allele was seen in children aged 6-35 months (32.3% vs. 19.3%; adjusted OR, 2.34 [95% CI, 1.18-4.66]; P=.02) but not in older children (37.3% vs. 37.0%; adjusted OR, 1.09 [95% CI, 0.56-2.10]; P=.97). Rates of adequate clinical response among children carrying parasites with the pfcrt-76T allele were similar in ITC and non-ITC villages (75.1% vs. 68.6%; adjusted OR, 1.21 [95% CI, 0.61-2.39]; P=.58). CONCLUSION: Our data suggest that the children who were protected from malaria by ITCs acquired functional immunity more rapidly than did the control children

Data from: Substantial contribution of submicroscopical Plasmodium falciparum gametocyte carriage to the infectious reservoir in an area of seasonal transmission

Background: Man to mosquito transmission of malaria depends on the presence of the sexual stage parasites, gametocytes, that often circulate at low densities. Gametocyte densities below the microscopical threshold of detection may be sufficient to infect mosquitoes but the importance of submicroscopical gametocyte carriage in different transmission settings is unknown. Methodology/Principal Findings: Membrane feeding experiments were carried out on 80 children below 14 years of age at the end of the wet season in an area of seasonal malaria transmission in Burkina Faso. Gametocytes were quantified by microscopy and by Pfs25-based quantitative nucleic acid sequence-based amplification assay (QT-NASBA). The children's infectiousness was determined by membrane feeding experiments in which a venous blood sample was offered to locally reared Anopheles mosquitoes. Gametocytes were detected in 30.0% (24/80) of the children by microscopy compared to 91.6% (65/71) by QT-NASBA (p<0.001). We observed a strong association between QT-NASBA gametocyte density and infection rates (p = 0.007). Children with microscopically detectable gametocytes were more likely to be infectious (68.2% compared to 31.7% of carriers of submicroscopical gametocytes, p = 0.001), and on average infected more mosquitoes (13.2% compared to 2.3%, p<0.001). However, because of the high prevalence of submicroscopical gametocyte carriage in the study population, carriers of sub-microscopical gametocytes were responsible for 24.2% of the malaria transmission in this population. Conclusions/Significance: Submicroscopical gametocyte carriage is common in an area of seasonal transmission in Burkina Faso and contributes substantially to the human infectious reservoir. Submicroscopical gametocyte carriage should therefore be considered when implementing interventions that aim to reduce malaria transmission

Characteristics of membrane feeding assay blood donors and mosquito infections

host = id of the host. calib_no = the calibration line number used to convert TTP (time to positivity readouts) from QT-NASBA into gametocyte density. ttp = time to positivity readout from QT-NASBA used to generate gametocyte density estimate. age = age of blood donor. asexual = asexual parasite density of blood donor (estimated using microscopy). no_dissected = number of mosquitoes dissected to determine mosquito infection. no_infected = number of mosquitoes dissected with observable oocyst

Membrane feeding results.

*<p>by Pfs25 QT-NASBA;</p>¶<p>p-value for a test for trend;</p>¥<p>only the total number of oocysts per batch of fed mosquitoes was recorded, not the number of oocysts of individual mosquitoes. Therefore only a summary measure can be presented and no analyses could be done on individual oocyst densities.</p><p>The total number of samples is lower than 80 because QT-NASBA results were not available for 9 individuals. Two individuals without QT-NASBA results that were gametocyte positive by microscopy were included. The relative contribution to transmission was based on the product of the proportion of infected mosquitoes (4^th row) and the prevalence of this subgroup in the population (1^st row).</p