Two field-collected populations of European earwigs were used in this study. The populations were collected 7–23 June 2011, from Columbus, OH, and from Piketon, OH, on 2 July 2011. Earwigs were placed in plastic holding containers and supplied with tropical fish flakes (Tetra Holding Inc., Blacksburg, VA) and potato halves; water was provided via a test tube plugged with cotton.

A 0.05% suspension was prepared using 9.4 g (0.33 oz) of indoxacarb (Arilon 20 WG) in 3.78 L (1 gallon) of distilled water. Indoxacarb was applied using a hand pump spray bottle, with each full pump providing an average discharge of 0.965 mL to an area of 232.6 cm². This yielded a treatment rate of 4.16 L/100 m² (1.02 gallons/1000 ft²) or 20.23 mg AI/m².

Indoxacarb (treatment) or water (control) was sprayed directly onto groups of five adult earwigs from each population. Each group was contained in a petri dish whose walls had been coated with fluon (Insect-a-Slip Insect Barrier, BioQuip Products, Rancho Dominguez, CA, USA) to prevent insect escape. The sprayed earwigs were immediately transferred to an untreated, lidded petri dish containing a 9 cm filter paper disc (Whatman no. 1). Food and water were provided ad libitum throughout the evaluation period. For each population, four replicates were established for the treatment and the control.

Long-lasting effects of indoxacarb were evaluated on both a porous substrate (pine wood) and non-porous substrate (glazed ceramic tile) (U.S. Ceramic Tile, Miami, FL). Indoxacarb was applied to 15.25-cm squares of both substrates at rates of 4.08, 8.15, and 16.30 L/100 m² (1, 2, and 4 gallons per 1,000 ft²) and allowed to dry completely (4 h). The lowest indoxacarb rate represents that typically used indoors whereas the two higher rates typically are used outdoors. The control was treated with water at the highest application rate. For each substrate, four replicates were established for each of the three indoxacarb rates and the control.

In residual bioassays, groups of five adult earwigs were confined within an inverted 9 cm petri dish (walls coated with fluon, as previously described) positioned on top of a substrate. Earwigs were kept in direct contact with each substrate for either 5 min or 1 h, then they were transferred to an untreated, lidded petri dish containing filter paper (9 cm dia). Food (tropical fish flakes) and water were provided to earwigs throughout the evaluation period.

For each replicate, the number of earwigs in each health category was recorded. A continuum of behavioral responses was used to categorize each earwig’s condition as defined herein:

At each observation time (4 h, 16 h, 1 d, 2 d, 3 d, 5 d, 7 d, 10 d, 14 d, and 21 d), earwigs in each replicate were individually assessed to determine their condition. If an earwig did not show immediate signs of movement, it was gently probed with featherweight forceps to assess its reaction. Each earwig was placed on its dorsum to determine whether it could assume normal posture (ataxic versus moribund).

Earwigs that were categorized as ataxic, moribund, or dead were aggregated and referred to as ‘critically affected.’ The percentage of critically affected earwigs then was transformed using arcsine square root (angular transformation). These data were analyzed in Statistica 6.0 [20] using the repeated-measures ANOVA with population, treatment, exposure time, and substrate as independent variables. Data for each observation time were evaluated as a repeated-measures dependent variable.

There were no significant differences in responses of the two earwig populations, Piketon and Columbus (F = 1.04, df = 1, 12, p = 0.33), so data were combined for analyses. Within 16 h of being directly sprayed with indoxacarb, 93% of earwigs were ataxic, moribund, or dead, and 100% of the earwigs displayed similar symptoms of severe intoxication at the 1-d observation. Although onset of symptoms was rapid, progression to death was relatively slow, and dead earwigs did not predominate until the 21-d observation. Recovery of directly sprayed earwigs was not evident during the 21-d observation period. In contrast, in soil contact bioassays with cypermethrin and deltamethrin, some earwigs recovered after initially experiencing knock down [13].

Substrate was not a significant factor as earwigs equally succumbed to indoxacarb residues on a porous and non-porous substrate (F = 1.25, df = 1, 96, p = 0.27). Additionally, population did not significantly influence the percentage of earwigs affected by treatment (F = 1.01, df = 1, 96, p = 0.32). Therefore, substrate and population data were pooled for analyses.

Treatment and exposure time were significant factors (F = 2768.7, df = 3, 120, p < 0.001 and F = 27.16, df = 1, 120, p < 0.001, respectively) in terms of the percentage critically affected earwigs, with the initial onset of symptoms typically slightly slower when earwigs were exposed to indoxacarb for 5 min compared to 1 h, but all earwigs were critically affected after 1 d (Table 1). In contrast, just a few control earwigs were ataxic, moribund, or dead during the 21-d bioassay period. The treatment x observation interaction was significant (F = 95.0, df = 27, 1080, p < 0.001) because more adverse effects were observed at 16 h and 1 d for the highest indoxacarb rate (16.30 L/100 m²) compared to the lower rates (4.08 and 8.15 L/100 m²). The treatment x exposure time x observation interaction was significant (F = 4.11, df = 27, 1080, p <0.001) because the percentage of critically affected earwigs at the 16-h and 1-d observations overlapped depending on indoxacarb exposure time and rate. At both the 16-h and 1-d observations, comparable data were obtained for longer exposure (1 h) to the lowest application rates (4.08 and 8.15 L/100 m²) and shorter exposure (5 min) to the highest rate, 16.30 L/100 m² (Table 1). At 2 d and thereafter, all earwigs were critically affected regardless of indoxacarb application rate and exposure time (Table 1). Furthermore, earwigs that were briefly exposed to dried indoxacarb residues showed no signs of recovery during the 21-d observation period. In contrast, in controls, the vast majority of earwigs were healthy at all observations.

In contact bioassays as well as in residual bioassays, the progression from ataxia or moribundity to death was relatively slow for earwigs, commencing around day 7, and >50% mortality was not observed until 21-d post-treatment. Hence, many intoxicated earwigs survived for weeks despite being critically affected by indoxacarb. However, in outdoor habitats, it is expected that intoxicated earwigs would be quite vulnerable to desiccation, predation, or pathogens, which would lead to much higher mortality (albeit secondary) than was observed in a laboratory setting. This expectation is supported by previous field research with indoxacarb [21] wherein ataxic European earwigs were observed on and/or underneath several carpenter ant-infested landscaping trees that had been sprayed with 0.1% indoxacarb (1.5 m up the trunk and 1.5 m around base). Although ataxic earwigs were observed 1-d post-treatment, none was subsequently found during a 28-d observation period. These field observations and results from the current study suggest that indoxacarb could provide control of earwigs in and around structures.

Other studies with indoxacarb likewise have shown that this insecticide is a slow-acting toxicant against various urban insect pests. Intoxication of termites [Reticulitermes flavipes (Kollar)] followed a predictable sequence of disorientation, ataxia, and moribundity followed by death over a period of 8 to 23 d depending on concentration and exposure time [22]. In the German cockroach [Blattella germanica (L.)], untreated cockroaches succumbed after being exposed to bait-fed cockroaches; mortality was attributed to consumption of the excretions and regurgitate of indoxacarb-intoxicated cockroaches as well as cannibalism. Furthermore, the horizontal transfer of indoxacarb continued beyond secondary mortality, with significant tertiary mortality observed [23].