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Insecticide Resistance

Person in lab holding a glass bottle.

The use of insecticides to kill mosquitoes that spread Zika, dengue, and chikungunya viruses, is one part of an integrated mosquito management program. Insecticides may be used by professionals and by homeowners. Insecticides can be applied by hand (indoor and outdoor sprays and foggers), by truck, or by aerial (airplane) spraying.

Over time and repeated use, insecticide resistance can occur in mosquito populations. Insecticide resistance is an overall reduction in the ability of an insecticide product to kill mosquitoes. This means that, when used as directed, the product no longer works, or only partially works. Insecticide resistance can be product specific, or it can develop to a certain class(es) of product.

In order to delay or prevent the development of insecticide resistance in vector populations, integrated vector management programs should include a resistance management component (Florida Coordinating Council on Mosquito Control 1998). Ideally, this should include annual monitoring of the status of resistance in target populations to:

  • Provide baseline data for program planning and pesticide selection before the start of control operations.
  • Detect resistance at an early stage so that timely management can be implemented.
  • Continuously monitor the effect of control strategies on insecticide resistance.

How Insecticide Resistance is Measured

Monitoring for resistance in the vector population is essential and is useful in determining the potential causes for control failures, should they occur. CDC has developed an assay to determine if a particular insecticide active ingredient is able to kill mosquito vectors. The technique, referred to as the CDC bottle bioassay, is simple, rapid, and economical compared with alternatives. The results can help guide the choice of insecticide used for spraying.

How the Bottle Bioassay Works

  • A bottle is coated with a known amount of insecticide (diagnostic dose). Mosquitoes are then put into the bottle and observed for 2 hours.
  • Resistance is determined by the percentage of mosquitoes that die (mortality rate) at the pre-determined threshold time during those 2 hours. The test should be run for the entire 2 hours unless all mosquitoes have died earlier than the 2 hours.

Bottle Bioassay Threshold Times and Amounts

CDC has determined bottle bioassay threshold times and diagnostic doses for several species of mosquitoes. Using the suggested bottle diagnostic dosages, the threshold times for various susceptible colonies are provided below. The CDC entomology laboratory uses these threshold times and amounts for their bottle bioassays. The concentrations and cut-off times can be used as a starting point for determining diagnostic doses and threshold times for additional species if susceptible colonies or populations are available. Once developed, the test can be routinely used for insecticide resistance testing.

Chemical Final Concentration/Bottle µg/bottle Ae. aegypti REX colony Ae. albopictus LC colony Cx. molestus colony Cx. pipiens NY/Chicago colony Cx. tarsalis BFS/KNWR colony Cx. quinque SEABRING colony
100% Mortality Expected (minutes)
Chlorpyrifos 20 45 45 45 90 60 45
Deltamethrin 0.75 30 30 120+ 45 TBD 60
Etofenprox 12.5 15 30 105 15 60 30
Fenthion 800 TBD TBD 30 75 45 45
Malathion 50 30 30
Malathion 400 15 30 30 45 45 45
Naled 2.25 30 30 30 45 45 45
Permethrin 15 15 15
Permethrin 43 10 10 30 30 30 30
Prallethrin 0.05 120+ 120+ 120+ 60 120+ 60
Pyrethrum 15 15 30 120+ 45 30 45
Resmethrin 30 5 10 30 15 10 30
Sumethrin 20 10 45 120 30 30 45

Information for Aedes aegypti, Ae. albopictus, and four Culex species mosquitoes are provided for areas where these species may be co-circulating. Culex species mosquitoes are important vectors of other arboviruses such as West Nile virus, St. Louis encephalitis virus, and Western equine encephalitis virus, which are endemic in the United States.

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