In order to determine the nature and distribution of the nuisance problem in Ohio, we conducted a statewide survey during the summer of 2001. The survey results helped to delineate typical characteristics of homes that are infested by H. axyridis. The average type of house was 73 years old, two-story, wood or vinyl sided and has lots of trees on at least three sides. The colors of the house and roof were not found to be a determining factor for an infestation problem. The data were also used to map the progression of the infestation problem throughout the state over the past decade. The data showed that the problem originated in eastern and southern Ohio and has spread north and west through much of the state in the past decade. The results also gave the relative severity of the problems associated with an infestation. The most irritating problems associated with a H. axyridis infestation are the foul odors the beetles emit and the stains resulting from their hemolymph when they reflex bleed. However, biting and food contamination are also significant concerns. An associated health problem is emerging as evidenced by the 13% of the respondents reporting dermal or respiratory allergic reaction to the beetles.
The survey
participants were also asked to provide the date in the fall of 2001 when the
beetles first arrive in significant numbers at their home. This information was then graphed with local
weather data to derive predictive events for the arrival of H. axyridis in any given locale. It
appears that H. axyridis are prompted
to search for overwintering sites on the first day over 18°C after a
significant drop in temperature, usually to near freezing. Some survey
participants also tracked the management methods used throughout the period of
infestation in the fall of 2001. This data was used to develop case study
reports on the efficacy of the different management techniques.
Problems with H. axyridis begin during the fall when
they aggregate in large numbers in search of an overwintering site. In their native lands H. axyridis would normally overwinter in cracks and crevices of
cliff sides and rock outcroppings (Riddick, et al., 2000). In Ohio where such
structures are relatively uncommon, the preferred overwintering site has become
individual homes. This aggregation
usually begins in early October. Large
swarms can be found moving across the landscape and settling on or around
individual homes. During the swarming period homeowners report the inability to
leave the house without being covered with beetles that often times bite. When
in the home in large numbers H. axyridis
causes much aggravation to the homeowner because these beetles often find their
way into food and drink, disrupt activities such as sleeping and reading and
when disturbed will reflex bleed a yellow-orange, foul-smelling liquid that
stains most surfaces. Additionally, H.
axyridis has been shown to induce allergic reactions in some people
(Yarbrough, et al., 1999).
Once the weather
turns consistently cold the beetles settle into their overwintering sites on or
just inside the home. If they remain
dormant throughout the winter the beetles are less of a concern to the
homeowner. However during warm spells
in the winter and spring the beetles become active and often find their way
into the home and become a nuisance again.
For years very
little was done to address the H.
axyridis nuisance problem because of the desire to preserve it as a
biological control agent. However the
nuisance problem has grown tremendously and now many homes throughout Ohio are
being invaded each year. In order to
assess the extent and nature of the H.
axyridis nuisance problem in Ohio a survey of residents was conducted along
with an evaluation of selected insecticides for their toxicity against the
beetle.
In a follow up
effort in the fall of 2001 the Ohio Lady Beetle Project (OLBP) participants
were instructed to call the Hotline and report the date that the lady beetles
arrived at their home in large numbers or swarms. Dates of arrival were received from 286 project participants.
Daily temperature highs were then obtained from National Weather Service stations
throughout the state. This weather data was used because H. axyridis flight appears to be temperature dependent. The temperature data were then graphed
against the arrival data for a given region in order to discern a pattern of
predictive events. Regions were
comprised of the resident county of the weather station and the counties
immediately surrounding. Since all of the regional graphs were very similar a
statewide graph was created using daily high temperature means and a summation
of the arrival data.
The OLBP participants were also asked to record all
mitigation activities they undertook against H. axyridis during the fall of 2001 and submit that information on
data sheets provided by the project staff.
Data sheets have been received from 41 people. The information from the data sheet was recorded and a summary of
treatment options was produced.
Included in this information were the treatment method, cost and
efficacy. The final portion of the project consisted of testing five
pyrethroid insecticides on their residual effect and efficacy as a killing
agent against H. axyridis, since
pesticide application to the exterior of the home appeared as the most
promising mitigation technique at the time. The beetles were collected from
soybean fields located at the Snyder Farm of the Ohio Agricultural Research
Development Center during August and September of 2001. Twenty-five petri dish
size white vinyl siding disks were treated with insecticides on 27 Aug 2001.
Insecticides tested were: Demand CS (9.7% lambda-cyhalothrin, rate of 0.634 ml/100 ml water); Talstar (7.9%
bifenthrin, rate of 0.781 ml/100 ml); Tempo SC (11.8% cyfluthrin, 0.423 ml/ 100
ml); Suspend SC (4.75% deltamethrin, 1.16 ml/100 ml); and Demon EC (25%
cypermethrin, 1 oz/gal or 0.78 ml/100 ml). Each treatment was replicated 5
times. The disks were
then placed outside during the day and exposed to natural sunlight for 21 days.
Disks were only brought in at night, to conduct bioassays, and to avoid dew or
rain events. Each disk was exposed to approximately 130 hour of daylight. On
September 18, five beetles were placed on each insecticide treated disk plus
and untreated control for one hour. After exposure the beetles were then
removed and placed on filter paper in petri dishes and provided with water.
Beetles were evaluated at 6 times period (16 hours, 24, 40, 48, 64 and 78 hours
after treatment) and placed in 3 categories, alive, dead, or moribund. Data
were analyzed using the analysis of variance function and means were separated
using Fisher’s Protected LSD. (SuperAnova, Abacus Concepts, 1991).
INTRODUCTION
The multicolored
Asian lady beetle, Harmonia axyridis,
was introduced many times into North America to serve as a biological control
agent, first in 1916 (California) and as recent as 1985 (Connecticut) (Tedders
and Schaefer, 1994). The first
established populations of H. axyridis
were reported in Mississippi and Louisiana in 1988 (Chapin and Brou,
1991). Since that time H. axyridis has become a
well-established predatory insect in many parts of the United States, including
Ohio (Horn, 1996). By outcompeting native populations, H. axyridis has become the dominant species of lady beetles in
Ohio, successfully managing populations of aphids, scale insects and other
soft-bodied insect pests on many types of plants and trees. However, the
perceived successful release of non-native generalist predators such as H. axyridis for biological control has
not been without controversy. In such
introductions there have usually been long delays between release and
establishment, displacement of other guild members and negative non-target
impacts. (LaMana and Miller, 1996). And it is these non-target impacts that are
the concern of homeowners across the state and region. While much heralded for
their activity as a bio-control agent during the growing season, H. axyridis becomes a serious nuisance
pest to homeowners during the fall, winter and early spring.
MATERIALS AND METHODS
In May of 2001 a
statewide survey of homeowners experiencing a H. axyridis nuisance problem was conducted. A toll-free number (The Ohio Lady Beetle
Hotline) was set up so that individuals who had experienced a H. axyridis nuisance problem could call
and request that a survey be sent to them. County Extension Agents advertised
the existence of the Hotline throughout the state. The survey was designed to
gain a basic understanding of the kinds of houses that are infested by H. axyridis and the specific nature of
the infestation experienced. All of the responses to the survey questions were
entered into an Excel spreadsheet and summary statistics produced. In some
cases to further refine the results, the data were grouped into three
categories, whether the respondents reported having low (100’s or less), medium
(thousands) or high (millions to “too many to count”) populations of beetles.
RESULTS
By the time that the survey results had begun to be
tabulated in late August nearly 1550 surveys had been sent and of those 1148
returned. The survey respondents were initially asked when the beetles first
became a problem in and around their home.
A few respondents reported that their problem began in the late 1980’s,
but the majority of respondents reported dates in the 1990’s. The map (Figure
1) shows how the problem has spread from a few counties in eastern and
southeastern Ohio in the early 1990’s to nearly half of the counties in Ohio.
Although the map does not show the complete distribution of the H. axyridis nuisance problem since the
survey was not promoted equally in all counties, it is representative of the
relative movement of H. axyridis throughout
Ohio.
The survey respondents were then asked to describe their home. Over half (57%) of the respondents had two-story homes while 31% had a single story. On the exterior of the home, 54% had wood, 43% had vinyl and 23% brick. However the results did not indicate that either house or roof color was a determinant for an infestation problem. It has been reported elsewhere that H. axyridis has a preference for light colors. (Nalepa et al, 1999) As Figure 2 shows, even when the data was broken down into the low, medium and high population categories the beetles equally invaded houses of light, medium or dark color.
The average house age of the survey respondents was 53 years. The data did not indicate that house age was a determinant of an infestation problem. However older houses were slightly more likely to experience high populations of lady beetles.
The survey respondents were also asked to describe the landscape immediate surrounding their home in the four directions (N, S, E & W). Figure 3 shows that having trees or a forest to any of the four cardinal directions was a good indicator of a H. axyridis infestation problem.
Questions were also designed to gain an understanding of the nature of the infestation problem experienced. The respondents were asked in what room and on what surface did the beetles most frequently appear. Most of the people experienced problems in their living rooms (58%), bedrooms (53%) and kitchens (46%) with the beetles appearing most frequently on the windows (86%) and ceilings (64%). When asked about the problems associated with a H. axyridis infestation, the survey respondents most frequently mentioned that the beetles produced a foul odor (77%) and stained various surfaces (71%) throughout the house. However a notable number also indicated that they were bitten by the beetles (42%) or that the beetles ended up falling into their food and drinks (41%).
The respondents were also asked if they experienced an allergic reaction to the beetles. Overall 13% of the respondents reported having allergic reactions and 6% actually had that reaction confirmed by a doctor. Furthermore, the data does suggest a dose response when broken down into the high, medium and low population categories (Figure 4). More of the respondents who reported allergic reactions also reported having high populations of beetles in their homes.
Finally, the respondents were asked what action they took against the lady beetles. The large majority of the respondents used vacuuming (90%) as their primary method of managing their H. axyridis infestation problem. Other methods used included applying pesticides (44%), sealing and caulking (34%) and trapping (7%). Six percent of the survey participants also reported that they took no action against the beetles. When asked how pleased they were with the results of the actions they took, only 1% of the group reported being satisfied.
The response from the OLBP participants regarding the date of arrival of the H. axyridis swarms at their location provided enough information to track the migration of the beetles to overwintering sites. There were three periods of migration, October 2-3, October 9-11 and October 20 with the middle period being the most notable. When this data was graphed against high temperature means for the state a predictive pattern of temperature declines was revealed. Figure 5 shows that during the days before each flight period the temperature dropped quickly. The low temperature for those days (September 30 – October 1, October 7-9 and October 18 – 19) fell to near or below freezing. Then on the next day over 18°C the beetles began their migration.
While only a small number of OLBP participants have returned the data sheets detailing actions taken against the lady beetle, some of the information indicates a direction for research on better management techniques. The most popular and reportedly effective method of reducing the number of H. axyridis in the home was to apply a pesticide on the exterior of the house. The products used by homeowners most frequently contained the pesticides cyfluthrin, permethrin and tralomethrin. Cyfluthrin also topped the list of chemicals applied by a pest control company followed by lambda-cyhalothrin and the combination of deltamethrin plus cypermethrin. 58% of the respondents reported applying the pesticides after the first swarm of H. axyridis arrived. The other respondents applied their pesticides anywhere from one week before and up to the day of arrival. The respondents were also to rate the efficacy of the treatment. All of the treatments that were applied by a professional were rated as significantly reducing the number of beetles that got into the home. The homeowner-applied pesticides were rated slightly less effective. Cyfluthrin, Deltamethrin + Cypermethrin, lambda-Cyhalothrin and Permethrin were consistently rated as effective chemicals. Furthermore the timing of the application of the chemical does not appear to affect its efficacy. Pesticides applied shortly after the lady beetles arrived received nearly as high ratings for efficacy as those that were applied before the beetles appeared.
Homeowners also reported using other methods to exclude H. axyridis from their home. Caulking to seal gaps and holes and screening any large openings such as vents were other popular mitigation techniques. Most reported caulking around windows and doors in addition to filling in any other visible cracks. This method alone was not viewed as successful in keeping the beetles out of the home. However when used in conjunction with other methods, especially exterior pesticide sprays, the survey respondents indicated a significant reduction in the number of beetles entering the home. Camphor cakes or oil, vanilla candles and bay leaves were other exclusion methods used by some homeowners. The camphor cakes or oil and bay leaves were placed around the windows, usually between the screen and the window on the exterior side. The candles were used with the intent of keeping H. axyridis out of the room in which they were burned. Most of the research participant indicated that the botanicals had no observable effect on their H. axyridis population. However, a few people with only a moderate infestation problem reported that camphor worked well for them.
Most of the data sheets also indicated that people relied heavily on vacuuming, usually numerous times per day, to manage their H. axyridis population. Some people even indicated that they purchased a vacuum or shop vac just for this purpose. This method did not eliminate H. axyridis from the home but did provide some help. It should be noted that all beetles vacuumed were disposed of, not released outside.
Very few people tried trapping devices to help manage their H. axyridis problem. The few that used sticky traps (both white and yellow) found them to be ineffective. Black light traps were also suggested. A few people constructed homemade versions and also found them to be useless.
The final method employed by some homeowners was to apply a pesticide on the interior of the home, usually around the windows and doors. Most of these chemicals were applied by the homeowner who commonly used permethrin. The professionally applied chemicals included chlorpyrifos and chlorpyrifos with permethrin. All of the homeowners who applied pesticides to the interior of their home also applied them to the exterior. And all of these people found this combination of treatments to be successful.
The results from the long-term efficacy test of the five pyrethroid pesticides showed some clear differences. Table 1 shows the percent of beetles that are dead or moribund in each treatment after 78 hours. All treatments provided some level of control. The lambda-cyhalothrin and deltamethrin treatments were the best with over 95% of the beetles either dead or dying. The bifenthrin treatment was next with 84% and statistically the same as the deltamethrin treatment. Cyfluthrin and cypermethrin killed only about 50% of the beetles at this time.
The number of dead or moribund individual at the various times is presented in Figure 6. At the 16-hour reading, over 80% of the beetles were dead or dying in all the treatments. However over time some beetles recovered and were alive 40 to 48 hours after exposure, particularly in the Demon and Tempo treatments. After 48 hours, those beetles that were classified as dead or dying remained in that condition.
Graphing the reported arrival dates of the beetles against
the temperature highs shows a predictive weather pattern for the initiation of
migration. While needing further
research, it appears that H. axyridis
are prompted to search for overwintering sites on the first day over 18°C after
a significant drop in temperature, usually to near freezing. The most effective
mitigation treatment reported was the application of pesticides to the exterior
of the home. Combining this treatment
with others such as vacuuming, caulking or screening only increased their
success. While the importance of pesticides as a tool to combat a H. axyridis infestation was evidenced by
the treatment reports, the efficacy test on these chemicals shows the choice of
pesticide is important. Our results suggest that one application to the
exterior of a vinyl sided house with lambda-cyhalothrin, deltamethrin or
bifenthrin should give at least 3 weeks of protection and may provide seasonal
control of H. axyridis.
The work of the Ohio Lady Beetle Program indicates the need for much more research. The issues surrounding H. axyridis are complicated at best. Research needs to commence to help find options for homeowners to keep H. axyridis from infesting their homes while at the same time preserving the beetle for its valuable biocontrol function.
LaMana, M.L. and Miller, J.C. 1996. Field Observations on Harmonia axyridis Pallas (Coleoptera: Coccinellidae) in Oregon. Biological Control. 6:232-237.
Nalepa, C.A., Kidd, K.A. and Hopkins, D.I. 2000. The Multicolored Asian Lady Beetle (Coleoptera: Coccinellidae): Orientation to Aggregation Sites. J. Entomol. Sci. 35(2):150-157.
Riddick, E.W., Aldrich, J.R., DeMilo, A. and Davis, J.C. 2000. Potential for Modifying the Behavior of the Multicolored Asian Lady Beetle (Coleoptera: Coccinellidae) with Plant-Derived Natural Products. Annals of the Entomological Society of America. 93(6):1314-1321
Tedders, W.L. and Schaefer, P.W. 1994. Release and Establishment of Harmonia axyridis (Coleoptera: Coccinellidae) in the Southeastern United States. Entomological News. 105(4): 228-243.
Yarbrough, MD, J.A., Armstrong, MD, J.L., Blumberg, MD, M.Z., Phillips, BS, A.E., McGahee, RN, E., and Dolen, MD, W.K. 1999. Allergic rhinoconjunctivitis caused by Harmonia axyridis (Asian lady beetle, Japanese lady beetle or lady bug). J Allergy Clin Immunol. 104:704-705.