Translator Disclaimer
11 April 2019 Alternative Survey Methods for the Emerald Ash Borer
Author Affiliations +

As part of an ongoing project to improve survey and detection for the emerald ash borer, Agrilus planipennis, several field assays were conducted to (1) determine how often traps need to be checked during a given field season, and (2) compare the effectiveness of traps with “dry” (with insecticidal strips or internal funnel) vs. “wet” (with propylene glycol surfactant) collection cups. There were no significant differences among any of the trap check intervals or the trap methods tested. This will provide new tools to surveyors, and allow them more flexibility as they survey for this invasive pest.

The emerald ash borer, Agrilus planipennis Fairmaire (Coleoptera: Buprestidae), a highly destructive pest of ash (Fraxinus L.) (Oleaceae), was discovered initially in North America in 2002 near Detroit, Michigan, USA. It has subsequently been detected in 31 additional US states and in 2 Canadian provinces (Haack et al. 2002; Emerald Ash Borer Info 2017). Since its arrival in the mid-1990s (Siegert et al. 2014), it is estimated that A. planipennis has killed tens of millions of trees throughout this range (Emerald Ash Borer Info 2017).

Since 2008, the US Department of Agriculture, Animal and Plant Health Inspection Service, Plant Protection and Quarantine (USDAAPHIS-PPQ) Emerald Ash Borer Cooperative Program has conducted a multi-state emerald ash borer survey (USDA APHIS PPQ 2017). The traps currently deployed are glue-coated purple prism traps (Francese et al. 2008, 2013a) baited with [3Z]-hexenol, a green leaf volatile found to increase A. planipennis trap catch (Grant et al. 2010, 2011; Poland et al. 2011; Crook et al. 2012).

Multi-funnel traps (Lindgren 1983) have been shown to be a promising tool for catching emerald ash borer (Francese et al. 2011). Because these traps lack the messy adhesive-coating found on the prism traps, multi-funnel traps are a more user-friendly option that do not need to be discarded after each use. Green multi-funnel traps, based on a color attractive to emerald ash borer (Crook et al. 2009; Francese et al. 2010) caught more A. planipennis than the standard black multi-funnel traps, purple multi-funnel traps, and prism traps in trapping assays conducted in heavily infested areas in southeastern and south-central Michigan. Fluon®-coated intercept panel traps have been shown to increase cerambycid trap catch, and remain effective for more than 1 field season (Graham et al. 2010; Graham & Poland 2012; Allison & Redak 2017). Fluon®-coated green multifunnel traps also caught 40× more emerald ash borer adults than traps not treated with any coating (Francese et al. 2013b). In low emerald ash borer density areas, green multi-funnel traps have been shown to be as effective in detecting populations as purple prisms (Crook et al. 2014).

Green multi-funnel traps have been available for use as a survey and detection tool for emerald ash borer since 2015, but due to their initial purchase and associated survey costs, they are not in wide programmatic use. The current survey guidelines recommend that during the course of the field season, multi-funnel traps be checked every 2 to 3 wk and prism traps only every 6 wk (USDA APHIS PPQ 2017). This additional maintenance leads to extra travel and personnel hours spent surveying, which increases program costs. Trap upkeep costs would include the additional killing agent that gets added at each trap check. Currently, the recommended killing agent in the US for the green multifunnel traps is a propylene glycol solution (about 20–30%) in water, in the form of “recreational vehicle” antifreeze (USDA APHIS PPQ 2017). Several studies found that traps equipped with a wet cup captured more cerambycid and buprestid species than traps equipped with a dry cup; however, because there were no Agrilus species captured in these studies, additional investigations are needed to evaluate this trapping method for A. planipennis (Allison & Redak 2017).

The overall goal of the research presented here was to assess various trap modifications and survey methods that could help to both reduce the aforementioned costs associated with multi-funnel traps, and thus provide alternatives to sticky traps for survey of emerald ash borer. In particular, the main objectives were to investigate the effect of the trap checking frequency and the effect of wet vs. dry killing agents on emerald ash borer trap catch and detection. To test these objectives, 2 separate trapping studies, the trap check interval study (Study 1) and the trap cup collection method study (Study 2), were conducted using green plastic multi-funnel traps (Chemtica USA, Durant, Oklahoma, USA) previously described by Francese et al. (2011). Traps were unbaited and coated with a 50% dilution of Fluon® that previously had been shown to be as effective at catching A. planipennis (Francese et al. 2013b) and other woodborers (Allison et al. 2016) as a 100% dilution. For both studies, traps were hung from ropes in the lower canopy (5–8 m) of host along the edges of white (Fraxinus americana L.) and green (Fraxinus pennsylvanica Marshall) ash-dominated woodlots in Edmore, Michigan; North Andover, Massachusetts; and Bethel, Ohio, USA. No lures were used on the traps. We replicated treatments in a randomized complete block design with trap lines as blocks. Within each trap line, we put traps in adjacent trees with an average of 5 m between traps.

The trap check frequency study was conducted in both North Andover, Massachusetts (n = 7) and Bethel, Ohio (n = 7) to determine how often multi-funnel traps needed to be checked. Four trap check intervals were compared: 1-wk, 3-wk, 6-wk, and 12-wk. Trap timing intervals were chosen based on the recommended survey guidelines (3 wk), recommended lure change timing (6 wk), and the full location specific predicted A. planipennis flight period duration (12 wk). Because 1 of the 12 wk traps placed in Massachusetts fell during the course of the season, the trap line that was a part of that replicate was removed from the study.

A trap cup collection method study was conducted on private land in Edmore, Michigan (n = 5), North Andover, Massachusetts (n = 5), and at East Fork State Park in Bethel, Ohio (n = 8) to compare alternate methods for killing and collecting captured A. planipennis adults. Four treatments were compared: (1) standard wet collection cup filled with 150 to 200 mL of propylene glycol (Camco Easygoing -50, Camco, Greensboro, North Carolina, USA); (2) dry collection cup with an internal funnel (cone 7.0 cm long, 13.7 cm diam.; stem 6.7 cm long, 3.9 cm diam.) placed in the bottom trap funnel to reduce the chances of escape; (3) dry collection cup containing an insecticidal strip (Vaportape II; 2,2-dichlorovinyl dimethyl phosphate (10%) Hercon Environmental, Emingsville, Pennsylvania, USA); and (4) dry collection cup containing an internal funnel and an insecticidal strip. Internal funnels were coated with Fluon® (50% solution) to prevent beetles from climbing out of the collection cup.

During trap checks, the contents of each trap cup were strained using a paper paint filter. Paint filters were then placed in individual, labeled Whirl-Pak sampling bags (Nasco, Fort Atkinson, Wisconsin, USA), ethanol was added for preservation, and samples were stored in a freezer until sorting and identification could be conducted. In both assays, collected beetles were summed for each trap over the entire field season. Summed catch was log-transformed (y + 0.5) prior to statistical analysis to normalize the data, which was confirmed by testing residuals after ANOVA. Separate analyses of variance (ANOVA) were performed on the transformed total number of A. planipennis adults captured per trap for each study, to compare treatment effects (cup collection method or trap check interval depending on the study) (JMP 10) (SAS Institute 2012). Confidence intervals (95%) were calculated from the standard error of the transformed trap catch. Means and confidence intervals were then back-transformed for presentation in the text and tables that follow.

In the trap check frequency study, the interval between checks (F = 0.66; df = 3, 52; P = 0.58) did not significantly affect trap catch (Table 1). Because there was greater decomposition and the 6- and 12-wk interval, samples had to be sorted and identified in a fume hood to reduce the smell; however, identification characteristics were not affected. These results suggest that from the program perspective, multi-funnel traps could be checked less frequently than currently recommended, which would greatly reduce costs. However, it also should be noted that leaving the traps in the field for 12 wk without checking them could lead to loss of data as was the case with the 12-wk trap that fell during the course of the study.

In the trap collection method study, collection method did not (F = 0.03; df = 3, 68; P = 0.99) play a significant role in trap catch (Table 2). Based on these results, dry cup methods could be used as an alternative to the propylene glycol wet cups. These results are encouraging, especially for emerald ash borer trapping in more remote areas where transporting or disposing of used propylene glycol is not practical. As expected, the dry cup without a killing agent was still effective, but would not be recommended in most situations because live beetles were found in the traps during the check period. However, this method does show promise for live-trapping other woodborer species attracted to these traps.

The staff members of the USDA APHIS PPQ Otis Laboratory, and Bethel and Brighton Field Stations provided field work assistance: Scott Gula, Mandy Furtado, Erin Schott, Elizabeth Reardon, MacKenzie O'Kane, Alexander Reitz, Brenna Walters, Sam Engle, Alyssa Perry, and Patrick Gemperline. Ann Ray of Xavier University provided planning and technical assistance. This work was funded by the USDA APHIS PPQ Emerald Ash Borer Program.

Table 1.

Back-transformed mean (± 95% confidence intervals) Agrilus planipennis trap catch in green multi-funnel traps checked at 1 of 4 intervals (n = 14). Trap catch had been summed for each trap for the entire season.


Table 2.

Back-transformed mean (± 95% confidence intervals) Agrilus planipennis trap catch in green multi-funnel traps using 1 of 4 different collection methods (n = 18). Trap catch had been summed for each trap for the entire season.


References Cited

  1. Allison JD, Redak RA. 2017. The impact of trap type and design features on the survey and detection of bark and wood boring beetles and their associates: a review and meta-analysis.Annual Review of Entomology62: 127–146. Google Scholar

  2. Allison JD, Graham EE, Poland TM, Strom BL. 2016. Dilution of fluon before trap surface treatment has no effect on longhorned beetle (Coleoptera: Cerambycidae) captures.Journal of Economic Entomology109: 1215–1219. Google Scholar

  3. Crook DJ, Francese JA, Rietz ML, Lance DR, Hull-Sanders HM, Mastro VC, Silk PJ, Ryall KL. 2014. Improving detection tools for emerald ash borer (Coleoptera: Buprestidae): comparison of multifunnel traps, prism traps and lure types at varying population densities.Journal of Economic Entomology107: 1496–1501. Google Scholar

  4. Crook DJ, Francese JA, Zylstra KE, Fraser I, Sawyer AJ, Bartels DW, Lance DR, Mastro VC. 2009. Laboratory and field response of the emerald ash borer (Coleoptera: Buprestidae) to selected regions of the electromagnetic spectrum.Journal of Economic Entomology102: 2160–2169. Google Scholar

  5. Crook DJ, Khrimian A, Cosse A, Fraser I, Mastro VC. 2012. Influence of trap color and host volatiles on capture of the emerald ash borer (Coleoptera: Buprestidae).Journal of Economic Entomology105: 429–437. Google Scholar

  6. Emerald Ash Borer Info. 2017. Emerald ash borer.(online) (last accessed 24 Nov 2018). Google Scholar

  7. Francese JA, Crook DJ, Fraser I, Lance DR, Sawyer AJ, Mastro VC. 2010. Optimization of trap color for emerald ash borer (Coleoptera: Buprestidae).Journal of Economic Entomology103: 1235–1241. Google Scholar

  8. Francese JA, Fraser I, Lance DR, Mastro VC. 2011. Efficacy of multi-funnel traps for capturing emerald ash borer (Coleoptera: Buprestidae): effect of color, glue, and other trap coatings.Journal of Economic Entomology104: 901–908. Google Scholar

  9. Francese, JA, Oliver JB, Fraser I, Lance DR, Youssef N, Sawyer AJ, Mastro VC. 2008. Influence of trap placement and design on capture of the emerald ash borer (Coleoptera: Buprestidae).Journal of Economic Entomology101: 1831–1837. Google Scholar

  10. Francese JA, Rietz ML, Crook DJ, Fraser I, Lance DR, Mastro VC. 2013a. Improving detection tools for the emerald ash borer (Coleoptera: Buprestidae): comparison of prism and multifunnel traps at varying population densities.Journal of Economic Entomology106: 2407–2414. Google Scholar

  11. Francese JA, Rietz ML, Mastro VC. 2013b. Optimization of multifunnel traps for emerald ash borer (Coleoptera: Buprestidae): influence of size, trap coating and color.Journal of Economic Entomology106: 2415–2423 Google Scholar

  12. Graham EE, Mitchell RF, Reagel PF, Barbour JD, Millar JG, Hanks LM. 2010. Treating panel traps with a fluoropolymer enhances their efficiency in capturing cerambycid beetles.Journal of Economic Entomology103: 641–647. Google Scholar

  13. Graham EE, Poland TM. 2012. Efficacy of fluon conditioning for capturing cerambycid beetles in different trap designs and persistence on panel traps over time.Journal of Economic Entomology105: 395–401. Google Scholar

  14. Grant GG, Poland TM, Ciaramitaro T, Lyons DB, Jones GC. 2011. Comparison of male and female emerald ash borer (Coleoptera: Buprestidae) responses to phoebe oil and (Z)-3-hexenol lures in light green prism traps.Journal of Economic Entomology104: 173–179. Google Scholar

  15. Grant GG, Ryall KL, Lyons DB, Abou-Zaid MM. 2010. Differential response of male and female emerald ash borers (Col., Buprestidae) to (Z)-3-hexenol and manuka oil.Journal of Applied Entomology134: 26–33. Google Scholar

  16. Haack RA, Jendek E, Liu H, Marchant KR, Petrice TR, Poland TM, Ye H. 2002. The emerald ash borer: a new exotic pest in North America.Newsletter of the Michigan Entomological Society47: 1–5. Google Scholar

  17. Lindgren BS. 1983. A multiple funnel trap for scolytid beetles (Coleoptera).The Canadian Entomologist115: 299–302. Google Scholar

  18. Poland TM, McCullough DG, Anulewicz AC. 2011. Evaluation of double-decker traps for emerald ash borer (Coleoptera: Buprestidae).Journal of Economic Entomology104: 517–531. Google Scholar

  19. USDA-APHIS-PPQ (US Department of Agriculture, Animal and Plant Health Inspection Service, Plant Protection and Quarantine). 2017. 2017 emerald ash borer survey guidelines.(online) (last accessed 24 Nov 2018). Google Scholar

  20. SAS Institute. 2012. JMP version 10.SAS Institute, Cary, North Carolina, USA. Google Scholar

  21. Siegert NW, McCullough DG, Liebhold AM, Telewski FW. 2014. Dendrochronological reconstruction of the epicenter and early spread of emerald ash borer in North America.Diversity and Distributions20: 847–858. Google Scholar

Joseph A. Francese, Everett G. Booth, Vanessa M. Lopez, and Benjamin Sorensen "Alternative Survey Methods for the Emerald Ash Borer," Florida Entomologist 102(1), 243-245, (11 April 2019).
Published: 11 April 2019

Back to Top