A Method for Evaluating Insecticide Efficacy against Bed Bug, Cimex lectularius, Eggs and First Instars

Podsumowanie

Insecticide evaluations are often targeted against adult insects, rather than immature stages. Here, we present a protocol for evaluating insecticides against bed bug eggs with a comparison to the first nymphal bed bug stage. These protocols could be adjusted for other insects to evaluate insecticide efficacy in non-adult life stages.

Streszczenie

Standard toxicity evaluations of insecticides against insect pests are primarily conducted on adult insects. Evaluations are based on a dose-response or concentration-response curve, where mortality increases as the dose or concentration of an insecticide is increased. Standard lethal concentration (LC₅₀) and lethal dose (LD₅₀) tests that result in 50% mortality of a test population can be challenging for evaluating toxicity of insecticides against non-adult insect life stages, such as eggs and early instar or nymphal stages. However, this information is essential for understanding insecticide efficacy in all bed bug life stages, which affects control and treatment efforts. This protocol uses a standard dipping bioassay modified for bed bug eggs and a contact insecticidal assay for treating nymphal first instars. These assays produce a concentration-response curve to further quantify LC₅₀ values for insecticide evaluations.

Wprowadzenie

Bed bugs are a significant urban pest that can cause blood loss, skin irritations, sleeplessness, depression, and anxiety in their human hosts ^1,2,3,4,5,6. The costs of eliminating and controlling bed bugs are high and often times require multiple visits to a home by a pest control company⁷. Multiple visits are usually required because of the cryptic behavior of bed bugs and the difficulties associated with killing them. In particular, bed bug eggs are difficult to control because of their small size and the protection of the embryo by the eggshell.

Currently, a common practice for many pest control companies throughout the United States is to treat a home for bed bugs using a chemical insecticide. It is well known that the eggs are difficult to control, so many companies have implemented a two-week time frame for re-treatments⁸. This allows bed bug eggs enough time to hatch, so that the first instar will emerge and purportedly be easier to kill with insecticides. However, there is a dearth in studies evaluating the efficacy of liquid insecticides against bed bug eggs and first instars.

Insect eggs have been documented to be the most difficult life stage to control in urban insect pests, other than bed bugs, in addition to many agricultural pests. Most of these difficulties have been attributed to the eggshell, while a few studies have reported insecticide resistance. Resistance in the egg stage has been documented in Triatoma infestans⁹, Pediculus humanus capitis¹⁰, Plutella xylostella¹¹, Rhyzopertha dominica¹², Cimex lectularius¹³, and multiple stored product beetles (i.e. Oryzaephilus surinamensis, Tribolium castaneum, Cryptolestes ferrugineus and Rhyzopertha dominica).¹⁴The development of resistance in the egg stage and immature stages, as well as complications associated with insecticide penetration through the eggshell, necessitates the need for insecticide efficacy bioassays against these life stages.

This protocol provides a step-by-step procedure for determining the efficacy of insecticides in the egg and first instar stage of common bed bugs, Cimex lectularius. Both of these protocols are concentration-response assays to allow quantification of LC₅₀ values. Concentration-response assays are commonly used for toxicological studies, however this protocol has been adapted for easily treating groups of bed bug eggs and first instars. These assays can be adapted for various insect species' eggs and immature life stages.

Protokół

NOTE: This protocol includes two insecticide assays for separately treating bed bug eggs and first instars. Both protocols were conducted using the same insecticides, however, the protocols had to be adapted to ensure insecticide exposure and to easily manipulate the specimens.

1. Egg Dipping Insecticide Assay

1. Pull mated, well-fed adult female bed bugs from a colony and place the females (5-10) into a Petri dish with filter paper. Have at least ten replicates to ensure that there will be enough eggs for the insecticide assay. Check to see if the females have laid eggs every day.
   1. Once they lay eggs, take the females out of the Petri dish (6 cm × 5 cm) and put them into new Petri dishes with a new filter paper daily and record the date on the old and new Petri dishes.
   2. Allow the eggs to age 4 to 5 days before starting the assay. Susceptibility to insecticides changes during embryonic development, so it is important to control for egg age. Hold all life stages at 12:12 L:D photoperiod, 60% RH, and 27 °C.
2. Once the eggs have aged appropriately, remove the bed bug eggs gently from filter papers using soft-tip forceps. Gently scrape the bottom of the egg attached to the filter paper using the forceps and then gently grab without applying much pressure on the egg to limit throwing bed bug eggs.
3. Place the removed bed bug eggs into their respective groups inside of plastic Petri dishes. Limit static electricity from flinging bed bug eggs by rubbing the bottom of each Petri dish on the outside with a fabric softener sheet. Treat groups of bed bug eggs (5-10 eggs per group) all at once. Consider one group a replicate and use at least five (or more) replicates for this assay.
4. Prepare serial dilutions of insecticides to get a range of 5 different concentrations (0.21-21 µL/mL for imidacloprid (0.1%)/β-cyfluthrin (0.5%) and a control solution with solvent (tap water) only. Make 20 mL of each concentration to have enough volume for the dipping assay.
5. Cut centrifuge tubes (50 mL) at the 35 mL line medially using a rotary tool with a cut-off wheel accessory and then cut a hole into the cap of the centrifuge tube (diameter = 2.54 cm) using the same rotary tool with an aluminum oxide grinding stone accessory. Leave 5 cm on the edge of the cap when cutting, so that the cap will securely screw into the tube (Figure 1).
6. Cut fine mesh into squares large enough to fit into the cap (~5 cm²). Screw the mesh tightly, eliminating any bumps, into the centrifuge tubes using the centrifuge tube cap.
7. Place a group of bed bug eggs (one replicate) using a paint brush onto the mesh inside of the centrifuge tube. Dip the group of bed bugs inside of the cut centrifuge tube into an insecticide concentration for 5 seconds.
8. Remove the centrifuge tube out of the insecticide solution. Dry the mesh with the eggs inside by placing the centrifuge tube directly onto a laboratory tissue.
9. Remove the group of eggs out of the centrifuge tube using a small, fine-bristle paint brush and place them into a clean Petri Dish with a clean filter paper.
10. Record egg mortality (failure to hatch) for 14 days to ensure all eggs have had sufficient time to hatch.
11. Correct for mortality in the control treatment using Abbott's formula (% test mortality -% control mortality/ 100 - control mortality x 100).
12. Insert recorded mortality with the corresponding concentrations into the analysis software¹⁵ to calculate LC₅₀ values.

2. First Instar Insecticide Assay

1. Separate a group of well-fed bed bugs (5 adult males and 5 adult females), preferably fed 1 day prior, and place them into a Petri dish (6 cm × 5 cm) with filter paper provided for mating and egg laying. Allow the adult bed bugs to mate and lay eggs for approximately 7-9 days. For feeding, use an artificial feeding system that circulates hot water in glass tubes surrounding blood¹⁶. For this study, use defibronated rabbit blood.
2. Remove the adults from the Petri dishes (6 cm × 5 cm) and allow the eggs to hatch into first instars within the Petri dishes. It takes approximately 7-9 days for bed bug eggs to hatch at room temperature.
3. Collect the unfed first instars of the same age using a paint brush. Age can be determined by removing the first instars daily and recording the day they hatched. Place them into new, clean Petri dishes until the insecticide assay. First instar nymphs are not very desiccant resistant, so the insecticide assay should be completed as soon as possible.
4. For the assay, prepare serial dilutions of imidacloprid/β-cyfluthrin to get a range of 5 different concentrations and a control solution with solvent only. Formulated products labeled for bed bug control in the United States were used for these studies, therefore the solvent was water (according to the label).
5. Pipette 150 µL aliquots of each insecticide concentration and water for the control group onto individual filter papers (#1; 4.2 cm diameter). Distribute the insecticide over the entire filter paper using the pipetter by applying droplets around the entire edge and center of the filter paper.
6. Place the treated filter papers individually on top of individual hardboard panels (7 cm²).
7. Release groups of first instars (5 to 10 per group) onto the individual filter papers while still wet with insecticide and cover the first instars with an inverted bottom of a Petri dish.
8. Place a weight on top of the Petri dish to prevent the first instar bed bugs from escaping the treated surface.
9. Record mortality of first instar bed bugs after 24 h exposure to all insecticide concentrations.
10. Correct for mortality in the control treatment using Abbott's formula (% test mortality -% control mortality/ 100 - control mortality x 100).
11. Insert recorded mortality and concentrations into the analysis software¹⁵ to calculate LC₅₀ values.

Wyniki

The eggs were dipped into 5 different concentrations of imidacloprid/ β-cyfluthrin (µL/mL). The first instars were placed onto treated surfaces of five different concentrations of imidacloprid/β-cyfluthrin (Figure 2).

We used three different populations of C. lectularius: Harlan, Richmond, and Epic Center (Table 1). The Harlan strain is susceptible to pyrethr...

Dyskusje

A critical step in this assay is to ensure that no eggs that are removed from a surface are damaged prior to the assay. Many insects cement their eggs to a substrate, therefore, a preliminary test may be needed to ensure that removal does not cause mortality. This test can be conducted with several replications of a treated group (bed bugs removed from filter paper) compared to a control group (bed bugs not removed). Similar low rates of mortality (or no mortality) between the treated and control group will ensure that ...

Materiały

Name	Company	Catalog Number	Comments
Petri dishes	Fisher Scientific Inc.	08-757-105	Plastic
Filter paper	Whatman	1001-042
Featherweight forceps	Fisher Scientific Inc.	4750
Temprid SC (imidacloprid/bifenthrin)	Bayer CropScience
Transport GHP (acetamiprid/bifenthrin)	FMC Corp.
Centrifuge tube		06-443-18	50 mL; flat-top threaded
Fine mesh		7250C
KimWipe		06-666A	11 cm X 21 cm
Small paint brush			Any small paint brush
Hardboard panels			Composite wood or tile would be sufficient from a home improvement store
Metal weights			Any type of metal screw that will hold the weight of the Petri dish down onto a surface