Collier Mosquito Barrier Research Report

Dr. Jeffrey Stivers, head of Research for the Collier Mosquito Control District in Florida, built an experimental 2,400-foot (730 m) mosquito barrier to protect the Stevens’ Landing Condominium Association. Then, for several months, he empirically measured the number of mosquitoes inside and outside the barrier, and he systematically recorded the level of satisfaction expressed by the residents of Stevens’ Landing. The research report concludes, “The system worked so well that the community at Stevens’ Landing voted to have it installed permanently.” The report goes on to say, “Once the system is installed and operational, the District will no longer need to aerially apply insecticide to the area, reducing the potential impact of such an application to the surrounding mangrove marsh environment.”

BioSensory believes this is breakthrough research on several counts:

• For the first time since tsetse flies were controlled with octenol baited traps in Zimbabwe 15 years ago, biological attractants have achieved a scientifically measurable success over a large area for an extended period of time.
• Stevens’ Landing is a worse case location. Mangrove swamps surrounding it are the breeding sites preferred by the black salt marsh mosquito.
• BioSensory octenol lures and Praxair CO₂ were used to bring mosquitoes in contact with contact-pesticide treated “targets” which must be changed every two weeks, yet the operating cost per family is on the order of $5 to $10 per week. The Barrier is less expensive and more effective than temporary relief from repeated aerial pesticide applications.
• Technology such as Dragonfly barrier systems will have the ability to sense mosquito activity, turn itself on and off as needed, and optimize attractant emissions for the level of mosquito pressure will only increase effectiveness of barrier systems and lower operating costs still farther.

Evaluation of the Efficacy of Linalool Candles as Spatial Repellents against Natural Populations of Mosquitoes

Susan McKnight

Abstract:  

In this field study to characterize the action of linalool candles as spatial repellents against natural populations of mosquitoes, subjects received 25.8% fewer mosquito landings at positions with candles containing 65% +enantiomer of linalool with 35% enantiomer of linalool compared with the unscented tea candle.

Introduction

Spatial repellents can provide new technology for protection of humans from mosquito transmitted disease.  Glouck et al. (1967) defined spatial repellent as a repellent that is effective at a distance from the point of application.  Nolen et al. (2002) further defined a spatial repellent as an inhibiting compound, dispensed into the atmosphere of a three dimensional space, which inhibits the ability of mosquitoes to locate and track a target, such as humans or livestock. D.L. Kline (personal communication) observed  that linalool, when used alone, attracts mosquitoes to a trap; however, when used with CO2 or with CO2 + octenol, linalool reduces mosquito collection sizes by as much as 50%.  Kline et al. (2003) found that linalool manifests spatial repellency against Aedes aegypti in a dual port olfactometer study.

As early as 1911, linalool, C₁₀H₁₈O, was described in the British Pharmaceutical Codex as an unsaturated alcohol, isomeric with geraniol, that occurs in a large number of essential oils, such as oils of coriander, lignaloe, bergamot, spike lavender, and thyme. Linalool was initially registered as a pesticide with the U.S. E.P.A. in 1985 for the control of fleas on pets and pet bedding (Cornell Fact Sheet 77, 1985). However, despite the long and common use of linalool, research into biological activity of linalool has recently revealed such divergent activities as being a mate attractant pheromone component in the bee Colletes cunicularius (Borg-Karlson et al., 2003), producing antinociception in two experimental models of pain in mice (Peana et al., 2003), and exhibiting antileishmanial activity in an in vitro study of Leishmania amazonensis in mouse peritoneal macrophages (Rosa et al., 2003).

Candles are commonly used to dispense odors into the atmosphere. Candles containing oil of citronella are sold commercially in the United States and Canada, with some manufacturers claiming that these products “reduce the annoyance of biting insects,” specifically mosquitoes.  In a study of citronella candles using human test subjects, Lindsay et al. (1996) reported that the overall percent reduction in mosquito bites provided by the citronella candles was 42.3% and by plain candles was 23.1%.  Considering the reduction in mosquito biting activity produced by the act of burning candles, the addition of 3% citronella to candles further decreased biting activity by only 19.2%.

The purpose of this field study was to characterize the action of linalool candles as spatial repellents against natural populations of mosquitoes.

 

Materials and Methods

The study was conducted on a trail through a deciduous woodlot in Northwest

Park, Windsor, Connecticut USA (41.88^° N, 72.67° W).  This park is located in the Connecticut River valley.   Four subjects (2 female, 2 male) were used in this study, which was conducted on 4 nights (August 12, 13, 14 & 15, 2003). An additional person timed landing rate counts.  Subjects wore clothing that permitted exposure of legs from knee to ankle.  Subjects had clean bare legs free of insect repellant, lotion, or other scent sources.

Four test stations were set up on folding metal chairs at 30 m. intervals on a 3 m. wide park trail adjacent to a swamp. Four wooden stakes driven to the height of 1 meter created a 2.5 m. square around each folding metal chair. Candles were placed on the top of the stakes so that each test station was surrounded by 4 candles of the treatment.  The treatments were Fragrance A (65% +enantiomer of linalool with 35% -enantiomer of linalool), Fragrance B (linalool=35% -enantiomer of linalool with 65% +enantiomer of linalool), OFF Citronella candle, and plain unscented tea candle. On the first night, four candles of OFF® Citronella candle were placed at “1” station, four candles of  Fragrance

A were placed at “2” station, four candles of  plain unscented tea candle were placed at “3” station, and four candles of Fragrance B were placed at “4” station.  On three subsequent nights, the candles were placed at different stations so that each type of candle was tested at each station. Candles were lit thirty minutes before beginning experiment to insure the presence of a molten pool of wax in each candle.

Landing rate counts were initiated by 1900 h each night. Subjects were assigned to one of the 4 test stations at the beginning of the evening and rotated through all 4 stations each night. Subjects sat on the back of the test station chair with feet on the seat of the chair. Subjects collected mosquitoes landing on their legs with a battery-operated hand aspirator for 10 minutes.  The collection vials were removed and sealed for mosquito identification. For the three subsequent trials each night, human test subjects moved to another test station.  After taking position at the new test station and inserting new collection vials in the aspirator, test subjects repeated the mosquito collections for 10 minutes.  Each test subject tested at each station each night.

All mosquitoes collected were identified to species using the keys of Darsie and Ward (1981) and Darsie (2002).  Weather information was obtained from the Bradley International Airport weather station located 1 km north of the study area (NOAA, 2003).

.Results

Each night 141-187 mosquitoes were collected (Table 1). The mosquito species collected and percent composition were: Aedes cinereus Meigen 1.2%, Aedes vexans (Meigen) 25.3%, Anopheles punctipennis (Say) 16.2%, Anopheles quadrimaculatus Say

3.3%, Coquilletidia perturbans (Walker) 24.7%, Culex pipiens Linnaeus 0.2%,

Ochlerotatus canadensis (Theobald) 0.5%, Ochlerotatus japonicus (Theobald) 9.9%, Ochlerotatus triseriatus (Say) 0.5%, Ochlerotatus trivittatus (Coquillett) 18.2%, and Ochlerotatus excrucians (Walker) 0.5%.  Daily high temperatures were 32.2° to 30.5° C. and daily low temperatures were 18.3° to 22.2° C. during the landing count evaluations.  Wind speed was less than 5 km/h during all nights.  No rain fell during the evaluations.

The data were subjected to analysis of variance (ANOVA) (Freund, 1984). The treatments were significantly different at a 90% confidence level (Table 2). Subjects received the fewest mosquito landings with Fragrance A candles and the greatest number of mosquito landings with OFF® Citronella candles (Table 3).

Subjects received 25.8% fewer mosquito landings at positions with Fragrance A (65% +enantiomer of linalool with 35% -enantiomer of linalool) compared with the unscented tea candle (Table 4).  Mosquito landings on subjects surrounded by Fragrance A candles was less variable over the four nights than in the other 3 treatments (Graph 1).

 

Table 1. Total mosquitoes collected by treatment, day, and location.

	Day 1	Day 2	Day 3	Day 4
Location 1	Citronella =71	FragranceA=29	Tea Candle=45	FragranceB=35
Location 2	FragranceA=23	Tea Candle=46	FragranceB=53	Citronella=50
Location 3	Tea Candle=41	FragranceB=37	Citronella=43	FragranceA=33
Location 4	FragranceB=52	Citronella=48	FragranceA=30	Tea Candle=23
Total	187	160	171	141

 

Table 2. ANOVA totals for location, day, and treatments.

Source of Variation	Degrees of Freedom	Sum of Squares	Mean Square	F
Location	3	134.68	44.90	0.377
Day	3	280.18	93.40	0.783
Treatment	3	1238.18	412.73	3.462
Error	6	715.37	119.23
Total	15	2368.44

 

Table 3. Mean number of mosquitoes collected per 10-min landing rate count at positions with Fragrance A (65% +enantiomer of linalool with 35% -enantiomer of linalool) candles, unscented tea candles, Fragrance B ((racemic linalool=35% -enantiomer of linalool with 65% +enantiomer of linalool) candles, and Off® Citronella candles.

 

Rank	Treatment	Total Collection	Mean Day Collection	Mean Subject Collection
1	Fragrance A	115	28.75	7.19
2	Tea Candle	155	38.75	9.69
3	Fragrance B	177	44.25	11.06
4	Citronella	212	53	13.25

 

Table 4. T-test comparison of mean number of mosquitoes collected per 10-min landing rate count at positions with Fragrance A (65% +enantiomer of linalool with 35% enantiomer of linalool) candles, unscented tea candles, Fragrance B ((racemic linalool=35% -enantiomer of linalool with 65% +enantiomer of linalool) candles, and Off® Citronella candles.

 

Comparison	Difference	90% Confidence Interval	Lower Limit %	Upper Limit %
Tea Candle – Fragrance A	-40	7.50	-30.64625586	-20.97
Tea Candle – Fragrance B	22	7.50	9.353744135	19.03
Tea Candle – Citronella	57	7.50	31.9343893	41.61

 

 

References Cited

British Pharmaceutical Codex. 1911. Council of the Pharmaceutical Society of Great Britain. http://www.ibiblio.org/herbmed/eclectic/bpc1911/linalool.html.

Borg-Karlson, A.K., J. Tengo, I.Valterova, C. R. Unelius, T. Taghizadeh, T. Tolasch, and W. Francke. 2003. (S)-(+)-Linalool, a Mate Attractant Pheromone Component in the Bee Colletes cunicularius. J of Chem Ecolog 29 (1): 1-14, January 2003.

Darsie, R. F., 2002. Revision of Darsie and Ward (1981) to include Ochlerotatus japonicus Theobald and a checklist of species referred to the genus Ochlerotatus in the Neartic region. J. Am. Mosq. Control Asso. 18(4):237-240.

Darsie, R. F. Jr., and R. A. Ward. 1981. Identification and geographical distribution of the mosquitoes of North America, north of Mexico. Mosq Sys. 1(Suppl): 1-313.

Freund, J. E. 1984. Modern Elementary Statistics, 6^th ed. Prentice-Hall, Inc. New Jersey. 561 p.

Glouck, H. K., T. P. McGovern, and M. Beroza. 1967. Chemicals tested as space repellents against yellow-fever mosquitoes. I Esters J Econ Entomol 60:1587-1590.

Kline, D. L., U. R. Bernier, K. H. Posey, and D. R. Barnard. 2003. Olfactometric evaluation of spatial repellents for Aedes aegypti. J Med Entomol 40(4):463-467.

Lindsay, L.R., G. A. Surgeoner, J.D. Heal and G. J. Gallivan. 1996. Evaluation of the efficacy of 3% citronella candles and 5% citronella incense for protection against field populations of Aedes mosquitoes. J Am Mosq Control Asso 12(2): 293-294.

NOAA-Bradley International Airport. 2003. http://www.erh.noaa.gov/box/dailystns.shtml

Nolen, J. A., R. H. Bedoukian, R. E. Maloney, and D. L. Kline. 2002. Method, apparatus and compositions for inhibiting the human scent tracking ability of mosquitoes in environmentally defined three dimensional spaces. U. S. Patent No. 6,362,235.

Peana A.T., P.S. D’Aquila, M.L. Chessa, M.D. Moretti , G. Serra, and P. Pippia. 2003. ()-Linalool produces antinociception in two experimental models of pain. Euro J Pharmacol. 460(1) Jan: 37-41.

Rosa, M. S. S.,  R. R. Mendonça-Filho, H. R. Bizzo, I.A. Rodrigues, R .M. A. Soares, T.Souto-Padrón, C. S. Alviano and A. H. C. S. Lopes. 2003. Antileishmanial Activity of a Linalool-Rich Essential Oil from Croton cajucara. Antimicrob Agents Chemother 47 (6): 1895–1901.