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Comparability between insecticide resistance bioassays for mosquito vectors: time to review current methodology?

Owusu HF, Jančáryová D, Malone D, Müller P - Parasit Vectors (2015)

Bottom Line: With resistance to insecticides on the rise, surveillance of the target population for optimal choice of insecticides is a necessity.Time-to-knockdown was shown to be an unreliable predictor of 24 h mortality.While the diagnostic dose in the WHO susceptibility test does not allow for detecting shifts at low or extreme resistance levels, time-to-knockdown measured in the CDC bottle assay is a poor predictor of 24 h mortality.

View Article: PubMed Central - PubMed

Affiliation: Epidemiology and Public Health Department, Swiss Tropical and Public Health Institute, Socinstrasse 57, PO Box, CH-4002, Basel, Switzerland. henry.owusu@unibas.ch.

ABSTRACT

Background: Insecticides play an integral role in the control of mosquito-borne diseases. With resistance to insecticides on the rise, surveillance of the target population for optimal choice of insecticides is a necessity. The Centers for Disease Control and Prevention (CDC) bottle assay and the World Health Organization (WHO) susceptibility test are the most frequently used methods in insecticide resistance monitoring. However, the two bioassays differ in terms of insecticide delivery and how insecticide susceptibility is measured. To evaluate how equivalent data from the two assays are, we compared the two methods side-by-side.

Methods: We did a literature search from 1998 to December 2014 to identify publications that performed both assays on the same mosquito population and compared the results. We then tested the WHO and CDC bioassays on laboratory strains of Aedes aegypti, Anopheles stephensi, An. gambiae and An. arabiensis with different insecticide resistance levels against permethrin, λ-cyhalothrin, DDT, bendiocarb and malathion. In addition, we also measured the relationship between time-to-knockdown and 24 h mortality.

Results: Both published data and results from the present laboratory experiments showed heterogeneity in the comparability of the two bioassays. Following their standard procedures, the two assays showed poor agreement in detecting resistance at the WHO cut-off mark of 90% (Cohen's κ = 0.06). There was better agreement when 24 h mortality was recorded in the CDC bottle assay and compared with that of the WHO susceptibility test (Cohen's κ = 0.5148). Time-to-knockdown was shown to be an unreliable predictor of 24 h mortality.

Conclusion: Even though the two assays can detect insecticide resistance, they may not be used interchangeably. While the diagnostic dose in the WHO susceptibility test does not allow for detecting shifts at low or extreme resistance levels, time-to-knockdown measured in the CDC bottle assay is a poor predictor of 24 h mortality. Therefore, dose-response assays could provide the most flexibility. New standardized bioassays are needed that produce consistent dose-response measurements with a minimal number of mosquitoes.

No MeSH data available.


Summary plot showing the relationship between 24 h mortality and the time it takes to knockdown 50 % of the population (KDT50) for all strains and insecticides tested in the present laboratory study. Symbols show point estimates and 95 % confidence intervals and colours show the insecticides tested. The confidence intervals for mortality are computed after Wilson [31] and those for KDT using the boxplot function
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Fig2: Summary plot showing the relationship between 24 h mortality and the time it takes to knockdown 50 % of the population (KDT50) for all strains and insecticides tested in the present laboratory study. Symbols show point estimates and 95 % confidence intervals and colours show the insecticides tested. The confidence intervals for mortality are computed after Wilson [31] and those for KDT using the boxplot function

Mentions: A plot of the time it takes to knockdown 50 % of the test population (KDT50) from the various strains and insecticides against mortality showed no clear pattern, corroborating the results from the GLMM models (Fig. 2). The KDT50 values ranged from 4 min in the treatment of ROCK and VK7 with bendiocarb to 28 min in the treatment of VK7 with DDT.Fig. 2


Comparability between insecticide resistance bioassays for mosquito vectors: time to review current methodology?

Owusu HF, Jančáryová D, Malone D, Müller P - Parasit Vectors (2015)

Summary plot showing the relationship between 24 h mortality and the time it takes to knockdown 50 % of the population (KDT50) for all strains and insecticides tested in the present laboratory study. Symbols show point estimates and 95 % confidence intervals and colours show the insecticides tested. The confidence intervals for mortality are computed after Wilson [31] and those for KDT using the boxplot function
© Copyright Policy - open-access
Related In: Results  -  Collection

License 1 - License 2
Show All Figures
getmorefigures.php?uid=PMC4492098&req=5

Fig2: Summary plot showing the relationship between 24 h mortality and the time it takes to knockdown 50 % of the population (KDT50) for all strains and insecticides tested in the present laboratory study. Symbols show point estimates and 95 % confidence intervals and colours show the insecticides tested. The confidence intervals for mortality are computed after Wilson [31] and those for KDT using the boxplot function
Mentions: A plot of the time it takes to knockdown 50 % of the test population (KDT50) from the various strains and insecticides against mortality showed no clear pattern, corroborating the results from the GLMM models (Fig. 2). The KDT50 values ranged from 4 min in the treatment of ROCK and VK7 with bendiocarb to 28 min in the treatment of VK7 with DDT.Fig. 2

Bottom Line: With resistance to insecticides on the rise, surveillance of the target population for optimal choice of insecticides is a necessity.Time-to-knockdown was shown to be an unreliable predictor of 24 h mortality.While the diagnostic dose in the WHO susceptibility test does not allow for detecting shifts at low or extreme resistance levels, time-to-knockdown measured in the CDC bottle assay is a poor predictor of 24 h mortality.

View Article: PubMed Central - PubMed

Affiliation: Epidemiology and Public Health Department, Swiss Tropical and Public Health Institute, Socinstrasse 57, PO Box, CH-4002, Basel, Switzerland. henry.owusu@unibas.ch.

ABSTRACT

Background: Insecticides play an integral role in the control of mosquito-borne diseases. With resistance to insecticides on the rise, surveillance of the target population for optimal choice of insecticides is a necessity. The Centers for Disease Control and Prevention (CDC) bottle assay and the World Health Organization (WHO) susceptibility test are the most frequently used methods in insecticide resistance monitoring. However, the two bioassays differ in terms of insecticide delivery and how insecticide susceptibility is measured. To evaluate how equivalent data from the two assays are, we compared the two methods side-by-side.

Methods: We did a literature search from 1998 to December 2014 to identify publications that performed both assays on the same mosquito population and compared the results. We then tested the WHO and CDC bioassays on laboratory strains of Aedes aegypti, Anopheles stephensi, An. gambiae and An. arabiensis with different insecticide resistance levels against permethrin, λ-cyhalothrin, DDT, bendiocarb and malathion. In addition, we also measured the relationship between time-to-knockdown and 24 h mortality.

Results: Both published data and results from the present laboratory experiments showed heterogeneity in the comparability of the two bioassays. Following their standard procedures, the two assays showed poor agreement in detecting resistance at the WHO cut-off mark of 90% (Cohen's κ = 0.06). There was better agreement when 24 h mortality was recorded in the CDC bottle assay and compared with that of the WHO susceptibility test (Cohen's κ = 0.5148). Time-to-knockdown was shown to be an unreliable predictor of 24 h mortality.

Conclusion: Even though the two assays can detect insecticide resistance, they may not be used interchangeably. While the diagnostic dose in the WHO susceptibility test does not allow for detecting shifts at low or extreme resistance levels, time-to-knockdown measured in the CDC bottle assay is a poor predictor of 24 h mortality. Therefore, dose-response assays could provide the most flexibility. New standardized bioassays are needed that produce consistent dose-response measurements with a minimal number of mosquitoes.

No MeSH data available.