Pyrethroid Resistance Reduces the Efficacy of Space Sprays for Dengue Control on the Island of Martinique (Caribbean)

The mosquito Aedes aegypti is the major vector of the Dengue virus in human populations and is responsible of serious outbreaks worldwide. In most countries, vector control is implemented by the use of insecticides to reduce mosquito populations. During epidemics, insecticides of the pyrethroid family (blocking the voltage gated sodium channel protein in the nerve sheath) are used by space spraying with vehicle mounted thermal foggers to kill adult mosquitoes. Unfortunately some populations of Ae. aegypti have become resistant to these insecticides, leading to operational challenges for public health services. In Martinique (French West Indies), resistance to pyrethroids was detected in the 1990s. The present study assessed the impact of this resistance on the efficacy of vector control operations in 9 localities of Martinique. Here we showed that the resistance strongly reduces the efficacy of pyrethroid-based treatments, thus emphasizing the urgent need for alternative insecticides or tools to reduce dengue transmission

Development of environmental tools for anopheline larval control

<p>Abstract</p> <p>Background</p> <p>Malaria mosquitoes spend a considerable part of their life in the aquatic stage, rendering them vulnerable to interventions directed to aquatic habitats. Recent successes of mosquito larval control have been reported using environmental and biological tools. Here, we report the effects of shading by plants and biological control agents on the development and survival of anopheline and culicine mosquito larvae in man-made natural habitats in western Kenya. Trials consisted of environmental manipulation using locally available plants, the introduction of predatory fish and/or the use of <it>Bacillus thuringiensis </it>var. <it>israelensis </it>(<it>Bti</it>) in various combinations.</p> <p>Results</p> <p>Man-made habitats provided with shade from different crop species produced significantly fewer larvae than those without shade especially for the malaria vector <it>Anopheles gambiae</it>. Larval control of the African malaria mosquito <it>An. gambiae </it>and other mosquito species was effective in habitats where both predatory fish and <it>Bti </it>were applied, than where the two biological control agents were administered independently.</p> <p>Conclusion</p> <p>We conclude that integration of environmental management techniques using shade-providing plants and predatory fish and/or <it>Bti </it>are effective and sustainable tools for the control of malaria and other mosquito-borne disease vectors.</p