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Article

Field Evaluation of Deltamethrin and Ivermectin Applications to Cattle on Culicoides Host-Alighting, Blood-Feeding, and Emergence

by
Archie K. Murchie
1,*,
Geoff M. Thompson
2,
Sam Clawson
1,
Andrew Brown
3,
Alan W. Gordon
1 and
Stephen Jess
1
1
Agri-Food and Biosciences Institute, Newforge Lane, Belfast BT9 5PX, Northern Ireland, UK
2
Ulster Farmers’ Union, 475 Antrim Road, Belfast BT15 3DA, Northern Ireland, UK
3
Agri-Food and Biosciences Institute, Large Park, Hillsborough BT26 6DR, Northern Ireland, UK
*
Author to whom correspondence should be addressed.
Viruses 2019, 11(8), 731; https://doi.org/10.3390/v11080731
Submission received: 2 July 2019 / Revised: 30 July 2019 / Accepted: 2 August 2019 / Published: 8 August 2019
(This article belongs to the Special Issue Virus-Vector-Host Interactions of Culicoides-Borne Diseases)
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Abstract

:
The impact of topical applications of deltamethrin and ivermectin to cattle on Culicoides spp. landing and blood-feeding was studied in this work using sticky traps mounted on Friesian heifers’ backs. There was no effect of the insecticides on total numbers of Culicoides trapped or the proportion engorged. Deltamethrin and ivermectin treatment did not prevent blood-feeding on these animals. Deltamethrin did result in significant Culicoides mortality as evidenced by the numbers of dead midges combed from heifers’ upper flanks. The proximity of engorged midges on traps to dead midges in the hair suggests that blood-feeding took place despite midges receiving an ultimately lethal dose of deltamethrin. Ivermectin application resulted in a smaller proportion of nulliparous than parous females caught. There was no significant effect of ivermectin on the numbers of Culicoides that emerged from dung samples (but p was small at 0.095 for the Obsoletus group Culicoides). In cases of suspect animal imports, pour-on or spray applications of deltamethrin could reduce the risk of onward transmission of bluetongue virus.

Graphical Abstract

1. Introduction

Biting midges, Culicoides spp. (Diptera: Ceratopogonidae), are important vectors of viral pathogens of livestock. During 2006–2009, there was a serious outbreak of the midge-vectored virus, bluetongue virus (BTV) serotype 8, in north-western Europe. The virus causes a notifiable disease and the outbreak resulted in widespread disruption to the cattle and sheep livestock industries. Whilst vaccination was the ultimate solution to the bluetongue outbreak, at early stages of a disease outbreak vaccines may not be developed or available in sufficient quantities for disease management. At these crucial early stages, vector control is a valuable option to prevent spread of the disease [1]. The island of Ireland has remained free from bluetongue, and did so even during the 2006–2009 European outbreak. The main risk of incursion has been from imported livestock [2]. For example, in November 2018, four heifers and one bull were imported into a Northern Irish farm from France. Routine post-import testing found that one of the heifers tested PCR positive for BTV-8 [3]. The infected heifer was euthanized and the other animals quarantined. This was during the ‘vector-free’ period as defined by fewer than five parous Culicoides per light trap catch [4], but small numbers of midges were still flying. In cases such as this, insecticide application could reduce the likelihood of onward transmission of the pathogen.
Application of insecticides directly to animals is a common method of nuisance fly management. Two of the most commonly used insecticide groups approved for nuisance fly and ectoparasite control are the synthetic pyrethroids and avermectins (macrocyclic lactones), which both can be conveniently applied by farmers as topical applications, termed ‘pour-ons’, to the skin of the animal. The avermectins can also be applied by sub-cutaneous injections and for internal parasite control as oral doses. Several papers have reviewed Culicoides control with respect to disease management, including the use of synthetic pyrethroids and avermectins [1,5,6,7,8].
Whilst there has been much laboratory-based research showing the toxicity of pyrethroids to Culicoides, in a review of knowledge gaps in Culicoides control, Mullens et al. [9] commented that: “Protection studies are far more accurate and realistic when we use bait animals and measure natural midge attack and successful engorgement”. Such studies have mainly used enclosure trapping or drop nets, with midges vacuumed directly from the animals or collected with light traps. Worldwide, the results have been mixed. The most successful trials have been on cattle in Australia, where numbers of Culicoides spp. were significantly reduced on treated animals compared to controls—for example, deltamethrin and cypermethrin versus Culicoides brevitarsis Kieffer, 1917 [10]; deltamethrin, permethrin, and fenvalerate versus Culicoides actoni Smith, 1929 and Culicoides peregrinus Kieffer, 1910 [11,12]; and ‘Flyaway’ (a blend of repellents and permethrin) and fenvalerate versus C. brevitarsis and Culicoides wadai Kitaoka, 1980 [13]. In the US, there was no effect of a dorsal application of a permethrin pour-on on the numbers of Culicoides sonorensis Wirth and Jones, 1957 blood-feeding but a belly-spray of permethrin to calves reduced the number of engorged females trapped [14]. In Germany, a deltamethrin pour-on to Holstein-Friesian bulls did not reduce the numbers of engorged Obsoletus and Pulicaris group Culicoides caught in light traps [15]. For sheep, a study in Spain found that deltamethrin applied to susceptible areas by hand resulted in zero Culicoides engorgement [16] and in Germany a deltamethrin pour-on reduced the numbers of both unfed and blood-fed Culicoides collected from drop nets around sheep [17]. Yet in India, dipping sheep in a deltamethrin solution had no impact on Culicoides spp. caught in light traps in their pens [18]. Lastly, in the UK a pour-on application of deltamethrin to horses had no effect on light trap catches of Obsoletus and Pulicaris group Culicoides from within mesh enclosures [19].
Compared to the pyrethroids, there is less information on the effects of avermectins on Culicoides. In Australia, Hereford cattle were given a single subcutaneous injection of ivermectin and C. brevitarsis placed in feeding pots on the hosts’ ears. There was no significant effect on feeding propensity but 99% of engorged C. brevitarsis died after blood-feeding [20]. However, a comparable experiment in the US, caging Culicoides variipennis (Coquillett, 1901) on the shaved skin of ivermectin-injected beef calves, found no significant effect of the same 200 µg per kg of body weight dose on midge mortality [21], probably because the serum concentration was not high enough [22]. In a laboratory bioassay, C. sonorensis showed no significant mortality when fed blood from ivermectin-treated horses, sheep or elk, although the infection rate of treated midges with BTV-17 was significantly lower than untreated controls [23]. As avermectins are excreted in the dung, they can also have an effect on Culicoides larval survival. In a report on the Australian bluetongue control strategy, it was stated that dung treated with ivermectin was larvicidal for up to 28 days, but no details were given [24].
Thompson et al. [25] used sticky traps to assess on-animal alighting and host preferences between sheep and cattle. The advantage of these sticky trap plates was that they presented a standardised landing area for midges and therefore allowed a comparison between different treatments. They also permitted the animals to move naturally around pasture. However, it is acknowledged that the technique has some limitations. The main limitation is that the sticky plates have to be mounted on the heifers’ mid-backs, or else they will lick the trap or swat it with their tails ruining the catch. Other studies have shown that midges show a predilection for blood-feeding on the lower flanks, underbelly and inner legs where the softer skin and thinner hair may make blood uptake easier [26,27,28].
In this study, the sticky trap method was used in a series of three trials to assess the effects of deltamethrin and ivermectin pour-on applications on Culicoides landing and blood-feeding on Friesian heifers in a Northern Ireland pasture. Estimates of the persistence of chemical controls against Culicoides vary in the literature. For example, for deltamethrin, Weiher et al. [17] found negative effects on midges 35 days after treatment, whilst Venail et al. [29] predicted maximum mortality after 4 days but that the lethal effect could be as brief as 10 days. For ivermectin, maximum blood concentration occurs 3–4 days after topical application [30,31]. However, in a study on horses the concentration of ivermectin in hair at the pour-on application site was well above that likely to cause Culicoides mortality (i.e., 350 ng per mL [22]) at greater than 10 µg per g for at least 40 days [31]. Therefore, the first trial in this study looked at trapping midges for a prolonged period (5 weeks) post application, whilst the following two trials concentrated on a two-week period post application when effects on midges were most likely. In the main, two hypotheses were tested in these trials. The first was that treatment with insecticidal compounds would prevent midge alighting (repellency). The second was that treatment would prevent blood-feeding. In addition, dung samples were taken to assess the effects of drug residues on Culicoides emergence from dung.

2. Material and Methods

Studies were conducted at the Agri-Food and Biosciences Institute’s (AFBI) Hillsborough research farm, Co. Down, Northern Ireland (54.445290° N, 6.065526° W). The experiments were conducted May–July 2012 (Trial 1) and September 2014 (Trial 2 and 3).

2.1. Trial 1—Five Week Study on the Effects of Deltamethrin and Ivermectin on Culicoides’ Landing and Emergence from Dung

The first trial used ivermectin (as Ivomec Classic Pour-On for Cattle, Boehringer Ingelheim Animal Health UK Ltd., Bracknell, UK) and deltamethrin (as Fly and Lice Spot On Insecticide, Zoetis UK Ltd., London, UK). Fifteen Friesian heifers (live weight ~370 kg) were selected from the farm’s herd at random and were allocated to three treatments: five were used as a control, five were treated with ivermectin, and five were treated with deltamethrin one day prior to the start of Culicoides monitoring. Animals were treated according to the manufacturers’ instructions. In brief, for ivermectin 1 mL product per 10 kg bodyweight (500 μg ivermectin per kg bodyweight) was applied along the mid-line of the back in a narrow strip between the withers and tailhead. For the deltamethrin, a standard 10 mL of product irrespective of animal weight (0.1 g deltamethrin) was applied as a single dose on the mid-line of the back, at the shoulders.
To monitor Culicoides landing, each animal had two white 200 cm2 sticky traps (Oecos Insect Monitoring, Kimpton, UK; Agralan Ltd, Swindon, UK) attached to its back using Velcro® and Kamar® adhesive glue (www.kamarinc.com) as per the method of Thompson et al. [25] (Figure 1). Traps were placed on the heifers 1 day after treatment. These traps were left in place for 24 h before being removed. This sampling was repeated at weekly intervals for a total of 5 weeks, equivalent to a period of 30 days after treatment. This first trial examined the persistence of any treatment effects over 5 weeks, whereas the two subsequent trials concentrated on multiple sampling within 15 days of application when insecticides were most bioavailable and effects most likely observed.
Culicoides caught on the sticky traps were left in situ. For Culicoides identification, specimens were not identified to species but were grouped primarily according to sub-genus and then sub-divided again by morphological characteristics, mainly wing patterning. This approach has been commonly used in the veterinary and applied studies of Culicoides [32,33]. The groups were categorised as Obsoletus (Culicoides chiopterus (Meigen, 1830); Culicoides dewulfi Goetghebuer, 1935; Culicoides obsoletus sensu stricto (Meigen, 1919); and Culicoides scoticus Downes and Kettle, 1952), Pulicaris (Culicoides pulicaris (Linnaeus, 1758); Culicoides punctatus (Meigen, 1804); and Culicoides newsteadi Austen, 1921), Impunctatus (Culicoides impunctatus Goetghebuer, 1920 and Culicoides grisescens Edwards, 1939) and Nubeculosus (Culicoides nubeculosus (Meigen, 1830), Culicoides puncticollis (Becker, 1903), and Culicoides riethi Kieffer, 1914) according to the key of Boorman [34]. Additionally, female parity was assessed by abdominal pigmentation using the method described by Dyce [35].
Dung samples were taken from each of the animals, either by collecting from dung pats immediately after defecation or directly from the rectum. Dung samples (300 mL) were laid out in an adjacent paddock in a randomised block design with 1 m between treatments and left exposed to Culicoides oviposition for one week before being covered with a bucket emergence trap for 4 weeks to allow for emergence [36]. Following this four week period, the bucket traps were removed and Culicoides counted. A soil core (diameter 10 cm and depth 6 cm) was then taken from each dung sample and put into a breathable tissue-culture bag (450 × 200 × 120 mm, Sigma-Aldrich) containing a 100 cm2 sticky trap and incubated for a further four weeks at 20 °C (light regime 16 h light, 8 h dark) to determine any midge emergence. Any Culicoides caught on the sticky traps were identified to group level and counted. The first dung samples were taken one day after treatment, with sampling repeated at weekly intervals for a total of 5 weeks, resulting in 75 dung samples in total (3 treatments × 5 replicates × 5 weeks); however, the initial samples were destroyed after cattle gained access to the paddock and trampled the emergence traps.

2.2. Trial 2—Culicoides’ Landing and Blood-Feeding on Friesian Heifers Treated with Ivermectin Pour-On

Twenty Friesian heifers (live weight ~350 kg) were treated with two antihelmintics. Ten were treated with ivermectin (as Ivomec) as per trial 1, and the other 10 with fenbendazole. The latter treatment equates to the control as animal husbandry practices on the farm did not allow an untreated control at this time but required the use of an antihelmintic against gastrointestinal parasites. Fenbendazole, as Panacur® (MSD Animal Health, Walton, UK), was applied as a 10% oral suspension at 1 mL of the product per 13 kg bodyweight (7.5 mg fenbendazole per kg bodyweight). Five days after treatment, two white sticky traps (200 cm2) were mounted to the heifers’ backs for a 24 h period, a process which was repeated again the following day (Table 1). Total numbers of Culicoides and those blood-fed were counted immediately after collection.

2.3. Trial 3—Culicoides’ Landing, Blood-Feeding and Mortality on Friesian Heifers Treated with Deltamethrin and Ivermectin Pour-Ons

Following on directly from trial 2, one week after the initial treatments of ivermectin and fenbendazole, five of the fenbendazole (control) heifers were treated with deltamethrin (as ‘Fly and Lice Spot On Insecticide’) to give an experiment comprising three treatments, i.e., deltamethrin (plus fenbendazole), ivermectin and fenbendazole alone, with five replicate animals (Figure 2). Four days after deltamethrin application, sticky traps were mounted on the backs of heifers for four consecutive 24 h periods (Table 1). In addition to sticky trap sampling, to collect dead Culicoides in the heifers’ hair, the upper half of the flanks of each heifer were combed from the withers to hips with a plastic head lice comb (teeth 14 mm length, ~0.3 mm apart) (Superdrug, London, UK) on three consecutive days (Table 1). Combing was done by the same operator each time, taking care to ensure that the areas combed were comparable between animals.

2.4. Analyses

Culicoides count data were subjected to generalized linear mixed models (GLMMs) fitted with Poisson distributions and logarithmic link functions. Where proportion data were analysed, binomial distributions coupled with logit link functions were used. In the GLMMs, individual animals were modelled as random effects. The significance of the fixed effects in the models was assessed by comparing Wald statistics for each term against an appropriate F-distribution. All analyses were conducted using the statistical package GenStat v16.2 (VSN International Ltd, UK; www.vsni.co.uk).

3. Results

3.1. Trial 1—Five Week Study on the Effects of Ivermectin and Deltamethrin on Culicoides’ Landing and Emergence from Dung

The total number of Culicoides caught on sticky traps during this study was 1,889. All were female and belonged to the Obsoletus (67%) or Pulicaris (33%) groups. The numbers of Culicoides caught declined as the experiment progressed (Figure 3). However, there was no effect of deltamethrin or ivermectin treatment on the number of Culicoides caught on sticky traps (overall Culicoides per heifer, back-transformed (b-t) from GLMM predictions with 95% confidence intervals: Obsoletus group − control = 17.03 (11.01–26.32), ivermectin = 18.16 (11.96–27.57), deltamethrin = 19.90 (13.46–29.40), deviance ratio = 0.14, d.f. = 2, 65, p = 0.870; Pulicaris group − control = 7.47 (4.44–12.58), ivermectin = 7.79 (4.74–12.81), deltamethrin = 11.23 (7.45–16.94), deviance ratio = 0.92, d.f. = 2, 65, p = 0.404; Figure 3).
The proportion of nulliparous midges caught on animal-mounted traps was smaller in the ivermectin treatment than in the control or deltamethrin treatments for both Obsoletus and Pulicaris groups (b-t means, Obsoletus group control = 0.74 (0.64–0.82), ivermectin = 0.55 (0.46–0.65), deltamethrin = 0.68 (0.59–0.76), deviance ratio = 14.73, d.f. = 2, 54, p = 0.030; Pulicaris group control = 0.60 (0.42–0.76), ivermectin = 0.32 (0.19–0.50), deltamethrin = 0.61 (0.46–0.74), deviance ratio = 20.50, d.f. = 2, 52, p = 0.035).
Two-hundred and eighty-three Culicoides were reared from dung collected from the experimental heifers, with these being 106 female and 177 male and predominantly Obsoletus group (95%) and Pulicaris group (5%), with a single midge from the Impunctatus group (<1%). The bucket emergence traps collected 116 midges (41%) and the incubated soil cores 167 (59%). There was no effect of ivermectin or deltamethrin on Culicoides emergence at the 5% significance level (Wald statistic = 2.75, d.f. = 2, 53.1, p = 0.261); although for the Obsoletus group, p was less than 0.1 (b-t means, control = 6.25 (2.48–15.73), ivermectin = 1.76 (0.48–6.39), deltamethrin = 3.27 (1.12–9.52), F = 2.44, d.f. = 2, 68.1, p = 0.095).

3.2. Trial 2—Culicoides’ Landing and Blood-Feeding on Friesian Heifers Treated with Ivermectin Pour-On

A total of 15,766 Culicoides, with a maximum of 1,260 caught in a single trap, were collected from the 20 experimental heifers over 24 h. There was no significant effect of ivermectin treatment on the number of Culicoides trapped (Wald statistic = 0.01, d.f. = 1, 16.6, p = 0.918; Figure 4) or the proportion blood-fed (b-t means, proportion blood-fed, control = 0.14 (0.11–0.19), ivermectin = 0.15 (0.11–0.19), Wald statistic = 0.09, d.f. = 1, 15.2, p = 0.774).

3.3. Trial 3—Culicoides’ Landing, Blood-Feeding and Mortality on Friesian Heifers Treated with Deltamethrin and Ivermectin Pour-Ons

A total of 19,720 Culicoides (a maximum of 641 on a single trap) were caught on sticky traps on the 15 heifers over the four consecutive 24 h periods. Again, there was no significant effect of ivermectin or deltamethrin on the number of Culicoides caught on animal-mounted sticky traps (Wald statistic = 0.95, d.f. = 2, 13.5, p = 0.633; Figure 5) or the proportion of midges that had blood-fed (b-t means, proportion blood-fed, control = 0.11 (0.08–0.14), ivermectin = 0.14 (0.11–0.18), deltamethrin = 0.12 (0.10–0.16); Wald statistic = 2.63, d.f. = 2, 11.2, p = 0.307).
A total of 737 dead Culicoides were combed from the hair of the 15 experimental heifers from samples taken on two consecutive days. There were significantly more Culicoides removed from the hair of deltamethrin-treated heifers than those treated with ivermectin or the control heifers (Wald statistic = 19.71, d.f. = 2, 13.1, p = 0.002; Figure 6). Due to the dehydrated condition of these midges it was not possible to determine visually if they were blood-fed.

4. Discussion

To use insecticides to protect livestock from Culicoides–vectored pathogens requires that the relationships between midges alighting on the host, blood-feeding, insecticide-repellence and insecticide-toxicity are understood. In these three trials, there was no effect of ivermectin or deltamethrin on the numbers of Culicoides caught on animal-mounted sticky traps, indicating that these treatments did not deter landing. This is perhaps to be expected as the main actions of deltamethrin and ivermectin are toxicity, although there is also some evidence of contact irritancy and repellence to deltamethrin [18,37,38] and ivermectin has reduced the responses of Culicoides imicola Kieffer, 1913 to host cues in an olfactometer [39]. Crucially, there was also no difference detected in the proportion of Culicoides blood-fed between treatments. The midges caught in this study were fresh blood-fed, which implied that they had fed on the heifers on which they were trapped. After engorgement, haematophagous insects leave the host to digest their blood meal. Therefore, this result indicates that the deltamethrin and ivermectin treatments did not prevent blood-feeding.
Maclachlan and Mayo [5] suggest that insecticides which allow Culicoides to blood-feed are not effective in bluetongue control as feeding midges can transmit the virus before dying. Robin et al. [19] found that a topical application of deltamethrin did not prevent blood-feeding on horses but did consider that if such treatments killed midges they could have a role in reducing onward transmission of disease from viraemic horses or suppressing the immediate Culicoides population. The combing technique in the present study showed that deltamethrin was killing midges that alighted on the heifers’ upper flanks. Deltamethrin is lipophilic and is disseminated by the natural oil secretions of the coat, with the midges exposed to the insecticide as they crawl through the hair. Deltamethrin is highly toxic to European C. obsoletus, with an LD50 of 1.33 × 10−4% [40] but despite this, blood-feeding was not prevented. Other studies have found that the insecticide concentration declines from the mid-line of the back to the belly, legs or face [6,15,30,41]. However, in this study, since engorged Culicoides were trapped on the middle of the back of the heifers close to the deltamethrin deposition point and surrounded by dead midges in the hair, it is reasonable to assume that these midges were able to blood-feed despite receiving a subsequently lethal dose of insecticide. This differs from the conclusions of earlier studies exposing hair from treated animals to Culicoides. These considered that the rapid knockdown of Culicoides by deltamethrin would prevent blood-feeding [42,43].
Ivermectin has a different mode of action to deltamethrin. It is highly lipophilic but also systemic, being absorbed through the skin to the subcutaneous fat reserves and bloodstream. It may also bind to the hair and be retained on the skin [31]. There was no evidence of Culicoides mortality in this study but this cannot be discounted as ivermectin does not have the same knockdown effects as deltamethrin and midges may fly from the animal before dying. Furthermore, sub-lethal effects may have a role in suppressing disease transmission through reduced lifespan, fecundity, dispersal or altered vector-pathogen interactions. A good example of this is that ivermectin reduced the bluetongue (BTV-17) infection rate of C. sonorensis by 40% with a 29% reduction in dissemination of the virus from the midges’ bodies to the heads [23]. The only significant effect of ivermectin on Culicoides in this study was a reduction in the proportion of nulliparous midges caught. The reasons for this are unknown. Different physiological states can influence how vectors respond to host cues. It is possible that nulliparous females are more sensitive to stimuli than older parous females [44] and are deterred by subtle changes in the host olfactory profile brought about by ivermectin treatment [39].
Ivermectin is excreted in the animals’ dung and can have negative effects on dung-dwelling fauna [45,46,47], including nuisance and biting fly larvae [48,49]. In this study, the numbers of Culicoides that emerged from the dung samples was small. There was a tentative suggestion of a negative effect of ivermectin on emergence of the Obsoletus group, the main vector risk group, but this was not significant at the 5% level (p = 0.095). Nevertheless, ivermectin excreted in the dung is not considered a viable widespread strategy to reduce Culicoides population levels due to the adverse effect on beneficial non-target invertebrates and also the availability of other larval breeding sites for Culicoides. Deltamethrin may also have residual insecticidal activity in dung [50,51].
The technique of using sticky traps to provide a standardised method of assessing Culicoides landing on experimental animals generally worked well. The numbers of Culicoides caught on traps were variable but in the second and third trials in September, they were substantial. In the third trial, a mean control of 172 (maximum of 1260) Culicoides were caught per 200 cm2 trap over a 24 h period. It is unknown to what extent these traps were attracting Culicoides to land on them compared to the surrounding animal’s skin. However, if such figures are extrapolated to the surface area of the heifers, and allowing for preferential feeding on different areas of the body, then animals in this location face a biting intensity of tens of thousands of Culicoides per night. One disadvantage of sticky traps is that specimens are distorted and difficult to identify to species level. Light trap catches at this location were mostly Obsoletus group [52], a subsample of which were subsequently identified to species level with C. obsoletus s.l./scoticus, Culicoides lupicaris and Culicoides dewulfi predominant (Bruno Mathieu and Thomas Balenghien, pers. comm.) Although UV light trapping may overestimate the biting rates of C. obsoletus, they nonetheless give a reasonable indication of the species involved [53].

5. Conclusions

The main result from this study is that neither deltamethrin nor ivermectin prevented blood-feeding by Culicoides midges on cattle in a field situation. The implications of this are that these treatments do not have a protective effect for individual animals but could prevent onward transmission of pathogens via post-feeding mortality of the vector. This would certainly seem to be the case for deltamethrin, where large numbers of dead Culicoides were collected on the upper flanks of the animals. For ivermectin, it was not possible to assess the mortality of affected Culicoides as they most likely died off the animal. Therefore, at the present time, in cases of suspect imported livestock, which represent the most significant risk of bluetongue incursion into Ireland, application of deltamethrin as a pour-on or spray treatment applied to the quarantine animals would be advocated to reduce the risk of onward transmission. This should be combined with spraying of the housing using a residual insecticide and where possible screening of the entrances. Any native livestock on the farm should be situated as far as possible from the quarantine housing, although it should be considered that Culicoides can disperse up to 5 km within a few days [54].
Although the sticky trap technique worked well, the position of the traps was restricted to the mid-back where the heifers could not lick or swat the traps with their tails. The coverage provided by pour-on treatments diminishes with distance from the application site, so in a future study it would be valuable to assess Culicoides mortality in distal areas with maximal midge feeding, such as the underbelly [26], possibly using a sticky substance applied directly to the hair rather than sticky plastic plates.

Author Contributions

Conceptualization, A.K.M., G.M.T. and S.J.; data curation, S.C.; formal analysis, A.K.M. and A.W.G.; funding acquisition, A.K.M.; methodology, A.K.M., G.M.T., S.C. and A.B.; writing—original draft, A.K.M.; writing—review and editing, A.K.M., G.M.T., A.W.G. and S.J.

Funding

This project was funded by the Department of Agriculture, Environment and Rural Affairs (Northern Ireland) through the Evidence and Innovation Strategy (Project 16/3/07-48109).

Acknowledgments

We wish to gratefully acknowledge the help of Ian Rea, Ivan Forsythe, Robert Jamison and Aaron Brunt in conducting the experiments, collecting samples and tabulating data. The suggestions of two anonymous reviewers substantially improved the paper.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

References

  1. Harrup, L.E.; Miranda, M.A.; Carpenter, S. Advances in control techniques for Culicoides and future prospects. Vet. Ital. 2016, 52, 247–264. [Google Scholar] [PubMed]
  2. Menzies, F.D.; McCullough, S.J.; McKeown, I.M.; Forster, J.L.; Jess, S.; Batten, C.; Murchie, A.K.; Gloster, J.; Fallows, J.G.; Pelgrim, W.; et al. Evidence for transplacental and contact transmission of bluetongue virus in cattle. Vet. Rec. 2008, 163, 203–209. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  3. DAERA. Bluetongue Detected in Imported Animal. Available online: https://www.daera-ni.gov.uk/news/bluetongue-detected-imported-animal (accessed on 6 December 2018).
  4. European Commission. Commission Regulation number 1266/2007 on implementation rules for Council Directive 2005/75/EC as regards the control, monitoring, surveillance and restrictions on movements of certain animals of susceptible species in relation to Bluetongue. OJEU 2007, 283, 37–52. [Google Scholar]
  5. Maclachlan, N.J.; Mayo, C.E. Potential strategies for control of bluetongue, a globally emerging, Culicoides-transmitted viral disease of ruminant livestock and wildlife. Antiviral Res. 2013, 99, 79–90. [Google Scholar] [CrossRef] [PubMed]
  6. Carpenter, S.; Mellor, P.S.; Torr, S.J. Control techniques for Culicoides biting midges and their application in the U.K. and northwestern Palaearctic. Med. Vet. Entomol. 2008, 22, 175–187. [Google Scholar] [CrossRef] [PubMed]
  7. EFSA. Scientific Opinion of the Scientific Panel on Animal Health and Welfare on request from the European Commission on bluetongue vectors and vaccines. EFSA J. 2007, 479, 1–29. [Google Scholar]
  8. EFSA. Bluetongue vectors and insecticides. Scientific Opinion of the Panel on Animal Health and Welfare on a request from the European Commission (DG SANCO) on Bluetongue. EFSA J. 2008, 735, 1–70. [Google Scholar]
  9. Mullens, B.A.; McDermott, E.G.; Gerry, A.C. Progress and knowledge gaps in Culicoides ecology and control. Vet. Ital. 2015, 51, 313–323. [Google Scholar]
  10. Doherty, W.M.; Johnson, S.J.; Reid, A.E. Suppression of Culicoides brevitarsis (Kieffer) (Diptera: Ceratopogonidae) on cattle in Queensland with deltamethrin and cypermethrin. Gen. Appl. Ent. 2001, 30, 45–47. [Google Scholar]
  11. Melville, L.; Hunt, N.; Bellis, G.; Pinch, D. Evaluation of chemical treatments to prevent Culicoides spp. (Diptera: Ceratopogonidae) feeding on cattle in the Northern Territory. Gen. Appl. Ent. 2001, 30, 41–44. [Google Scholar]
  12. Melville, L.V.; Hunt, N.T.; Bellis, G.; Pinch, D. An assessment of insecticides to minimize the transmission of arbovirus in cattle. Arbovirus Res. Aust. 2004, 8, 249–255. [Google Scholar]
  13. Doherty, W.M.; Bishop, A.L.; Melville, L.F.; Johnson, S.J.; Bellis, G.A.; Hunt, N.T. Protection of cattle from Culicoides spp. in Australia by shelter and chemical treatments. Vet. Ital. 2004, 40, 321. [Google Scholar]
  14. Mullens, B.A.; Velten, R.K.; Gerry, A.C.; Braverman, Y.; Endris, R.G. Feeding and survival of Culicoides sonorensis on cattle treated with permethrin or pirimiphos-methyl. Med. Vet. Entomol. 2000, 14, 313–320. [Google Scholar] [CrossRef] [PubMed]
  15. Bauer, B.; Jandowsky, A.; Schein, E.; Mehlitz, D.; Clausen, P.-H. An appraisal of current and new techniques intended to protect bulls against Culicoides and other haematophagous nematocera: the case of Schmergow, Brandenburg, Germany. Parasitol. Res. 2009, 105, 359–365. [Google Scholar] [CrossRef] [PubMed]
  16. Mullens, B.A.; Gerry, A.C.; Monteys, V.S.I.; Pinna, M.; Gonzalez, A. Field studies on Culicoides (Diptera: Ceratopogonidae) activity and response to deltamethrin applications to sheep in northeastern Spain. J. Med. Entomol. 2010, 47, 106–110. [Google Scholar] [CrossRef] [PubMed]
  17. Weiher, W.; Bauer, B.; Mehlitz, D.; Nijhof, A.M.; Clausen, P.-H. Field trials assessing deltamethrin (Butox®) treatments of sheep against Culicoides species. Parasitol. Res. 2014, 113, 2641–2645. [Google Scholar] [CrossRef] [PubMed]
  18. De Keyser, R.; Cassidy, C.; Laban, S.; Gopal, P.; Pickett, J.A.; Reddy, Y.K.; Prasad, M.; Prasad, G.; Chirukandoth, S.; Senthilven, K.; et al. Insecticidal effects of deltamethrin in laboratory and field populations of Culicoides species: how effective are host-contact reduction methods in India? Parasit. Vectors. 2017, 10, 54. [Google Scholar] [CrossRef] [PubMed]
  19. Robin, M.; Archer, D.; McGowan, C.; Garros, C.; Gardès, L.; Baylis, M. Repellent effect of topical deltamethrin on blood feeding by Culicoides on horses. Vet. Rec. 2015, 176, 574. [Google Scholar] [CrossRef]
  20. Standfast, H.A.; Muller, M.J.; Wilson, D.D. Mortality of Culicoides brevitarsis (Diptera: Ceratopogonidae) fed on cattle treated with Ivermectin. J. Econ. Entomol. 1984, 77, 419–421. [Google Scholar] [CrossRef]
  21. Holbrook, F.R. Survival, fecundity, and egg fertility of Culicoides variipennis (Diptera: Ceratopogonidae) fed on calves inoculated with ivermectin. J. Am. Mosq. Control. Assoc. 1994, 10, 7. [Google Scholar]
  22. Holbrook, F.R.; Mullens, B.A. Effects of ivermectin on survival, fecundity, and egg fertility in Culicoides variipennis (Diptera: Ceratopogonidae). J. Am. Mosq. Control. Assoc. 1994, 10, 70–73. [Google Scholar] [PubMed]
  23. Reeves, W.K.; Nol, P.; Miller, M.M.; Jones, G.Z. Effects of ivermectin on the susceptibility of Culicoides sonorensis (Diptera: Ceratopogonidae) to bluetongue and epizootic hemorrhagic disease viruses. J. Vector Ecol. 2009, 34, 161–163. [Google Scholar] [CrossRef] [PubMed]
  24. Webster, W.R.; Gard, G.P.; St. George, T.D.; Kirkland, P.D. The Australian Bluetongue Control Strategy. In Proceedings of the Second International Symposium: Bluetongue, African Horse Sickness, and Related Orbiviruses, Paris, France, 17–21 June 1991; CRC Press Inc.: Boca Raton, FL, USA, 1992; pp. 843–850. [Google Scholar]
  25. Thompson, G.M.; Jess, S.; Gordon, A.W.; Murchie, A.K. Sticky-trapping biting midges (Culicoides spp.) alighting on cattle and sheep: Effects of trap colour and evidence for host preference. Parasitol. Res. 2014, 113, 3085–3094. [Google Scholar] [CrossRef] [PubMed]
  26. Ayllón, T.; Nijhof, A.M.; Weiher, W.; Bauer, B.; Allène, X.; Clausen, P.-H. Feeding behaviour of Culicoides spp. (Diptera: Ceratopogonidae) on cattle and sheep in northeast Germany. Parasit. Vectors 2014, 7, 34. [Google Scholar] [CrossRef] [PubMed]
  27. Nielsen, B.O. Some observations on biting midges (Diptera: Ceratopogonidae) attacking grazing cattle in Denmark. Entomol. Scand. 1971, 2, 94–98. [Google Scholar] [CrossRef]
  28. Townley, P.; Baker, K.; Quinn, P. Preferential landing and engorging sites of Culicoides species landing on a horse in Ireland. Equine Vet. J. 1984, 16, 117–120. [Google Scholar] [CrossRef] [PubMed]
  29. Venail, R.; Mathieu, B.; Setier-Rio, M.-L.; Borba, C.; Alexandre, M.; Viudes, G.; Garros, C.; Allene, X.; Carpenter, S.; Baldet, T. Laboratory and field-based tests of deltamethrin insecticides against adult Culicoides biting midges. J. Med. Entomol. 2011, 48, 351–357. [Google Scholar] [CrossRef]
  30. Gayrard, V.; Alvinerie, M.; Toutain, P. Comparison of pharmacokinetic profiles of doramectin and ivermectin pour-on formulations in cattle. Vet. Parasitol. 1999, 81, 47–55. [Google Scholar] [CrossRef]
  31. Gokbulut, C.; Cirak, V.Y.; Senlik, B.; Aksit, D.; Durmaz, M.; McKellar, Q.A. Comparative plasma disposition, bioavailability and efficacy of ivermectin following oral and pour-on administrations in horses. Vet. Parasitol. 2010, 170, 120–126. [Google Scholar] [CrossRef]
  32. Nielsen, S.A.; Kristensen, M. Morphological and molecular identification of species of the Obsoletus group (Diptera: Ceratopogonidae) in Scandinavia. Parasitol. Res. 2011, 109, 1133–1141. [Google Scholar] [CrossRef]
  33. Bartsch, S.; Bauer, B.; Wiemann, A.; Clausen, P.-H.; Steuber, S. Feeding patterns of biting midges of the Culicoides obsoletus and Culicoides pulicaris groups on selected farms in Brandenburg, Germany. Parasitol. Res. 2009, 105, 373–380. [Google Scholar] [CrossRef] [PubMed]
  34. Boorman, J. A short key to British Culicoides of veterinary importance. Available online: http: www.culicoides.net/taxonomy/identification-keys/UK01–1 (accessed on 3 July 2012).
  35. Dyce, A.L. The recognition of nulliparous and parous Culicoides (Diptera: Ceratopogonidae) without dissection. J. Aust. Entomol. Soc. 1969, 8, 11–15. [Google Scholar] [CrossRef]
  36. Thompson, G.M.; Brunt, A.; Loye, S.; Jess, S.; Murchie, A.K. A low-cost bucket trap for newly emerged insects. Ir. Nat. J. 2013, 32, 117–120. [Google Scholar]
  37. Achee, N.L.; Sardelis, M.S.; Dusfour, I.; Chauhan, K.R.; Grieco, J.P. Characterisation of spatial repellent, contact irritant, and toxicant chemical actions of standard vector control compounds. J. Am. Mosq. Control. Assoc. 2009, 25, 156–157. [Google Scholar] [CrossRef] [PubMed]
  38. Mehlhorn, H.; Al-Rasheid, K.A.S.; Abdel-Ghaffar, F.; Klimpel, S.; Pohle, H. Life cycle and attacks of ectoparasites on ruminants during the year in Central Europe: recommendations for treatment with insecticides (e.g., Butox®). Parasitol. Res. 2010, 107, 425–431. [Google Scholar] [CrossRef] [PubMed]
  39. Sollai, G.; Solari, P.; Masala, C.; Crnjar, R.; Liscia, A. Effects of avermectins on olfactory responses of Culicoides imicola (Diptera: Ceratopogonidae). J. Med. Entomol. 2007, 44, 656–659. [Google Scholar] [CrossRef]
  40. Del Río, R.; Venail, R.; Calvete, C.; Barceló, C.; Baldet, T.; Lucientes, J.; Miranda, M.A. Sensitivity of Culicoides obsoletus (Meigen) (Diptera: Ceratopogonidae) to deltamethrin determined by an adapted WHO standard susceptibility test. Parasitology 2014, 141, 542–546. [Google Scholar] [CrossRef] [PubMed]
  41. Carpenter, S.; Mellor, P.; Torr, S. Bluetongue and midge control. Vet. Rec. 2007, 161, 633. [Google Scholar] [CrossRef]
  42. Schmahl, G.; Klimpel, S.; Walldorf, V.; Al-Quraishy, S.; Schumacher, B.; Jatzlau, A.; Mehlhorn, H. Pilot study on deltamethrin treatment (Butox® 7.5, Versatrine®) of cattle and sheep against midges (Culicoides species, Ceratopogonidae). Parasitol. Res. 2009, 104, 809–813. [Google Scholar] [CrossRef]
  43. Mehlhorn, H.; Schmahl, G.; D’Haese, J.; Schumacher, B. Butox 7.5 pour on: A deltamethrin treatment of sheep and cattle: pilot study of killing effects on Culicoides species (Ceratopogonidae). Parasitol. Res. 2008, 102, 515–518. [Google Scholar] [CrossRef]
  44. Murchie, A.K.; Clawson, S.; Rea, I.; Forsythe, I.W.N.; Gordon, A.W.; Jess, S. DEET (N,N-diethyl-meta-toluamide)/PMD (para-menthane-3,8-diol) repellent-treated mesh increases Culicoides catches in light traps. Parasitol. Res. 2016, 115, 3543–3549. [Google Scholar] [CrossRef] [PubMed]
  45. Wall, R.; Strong, L. Environmental consequences of treating cattle with the antiparasitic drug ivermectin. Nature 1987, 327, 418–421. [Google Scholar] [CrossRef] [PubMed]
  46. Strong, L. Avermectins: A review of their impact on insects of cattle dung. Bull. Entomol. Res. 1992, 82, 265–274. [Google Scholar] [CrossRef]
  47. Wall, R.; Beynon, S. Area-wide impact of macrocyclic lactone parasiticides in cattle dung. Med. Vet. Entomol. 2012, 26, 1–8. [Google Scholar] [CrossRef] [PubMed]
  48. Floate, K.D.; Spooner, R.W.; Colwell, D.D. Larvicidal activity of endectocides against pest flies in the dung of treated cattle. Med. Vet. Entomol. 2001, 15, 117–120. [Google Scholar] [CrossRef] [PubMed]
  49. Strong, L.; Brown, T.A. Avermectins in insect control and biology: A review. Bull. Entomol. Res. 1987, 77, 357–389. [Google Scholar] [CrossRef]
  50. Mann, C.M.; Barnes, S.; Offer, B.; Wall, R. Lethal and sub-lethal effects of faecal deltamethrin residues on dung-feeding insects. Med. Vet. Entomol. 2015, 29, 189–195. [Google Scholar] [CrossRef]
  51. Gilbert, G.; MacGillivray, F.S.; Robertson, H.L.; Jonsson, N.N. Adverse effects of routine bovine health treatments containing triclabendazole and synthetic pyrethroids on the abundance of dipteran larvae in bovine faeces. Sci. Rep. 2019, 9, 4315. [Google Scholar] [CrossRef]
  52. Jess, S.; Thompson, G.M.; Clawson, S.; Forsythe, I.W.N.; Rea, I.; Gordon, A.W.; Murchie, A.K. Surveillance of biting midges (Culicoides spp.) in Northern Ireland: influence of seasonality, surrounding habitat and livestock housing. Med. Vet. Entomol. 2018, 32, 48–60. [Google Scholar] [CrossRef]
  53. Viennet, E.; Garros, C.; Gardès, L.; Rakotoarivony, I.; Allène, X.; Lancelot, R.; Crochet, D.; Moulia, C.; Baldet, T.; Balenghien, T. Host preferences of Palaearctic Culicoides biting midges: implications for transmission of orbiviruses. Med. Vet. Entomol. 2013, 27, 255–266. [Google Scholar] [CrossRef]
  54. Elbers, A.; Koenraadt, C.; Meiswinkel, R. Mosquitoes and Culicoides biting midges: vector range and the influence of climate change. Rev. Sci. Tech. 2015, 34, 123–137. [Google Scholar] [CrossRef] [PubMed]
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Figure 1. Friesian heifers with two sticky traps mounted mid-back to monitor Culicoides landing and blood-feeding.
Figure 1. Friesian heifers with two sticky traps mounted mid-back to monitor Culicoides landing and blood-feeding.
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Figure 2. The relationship between the treatments in trial 2 and trial 3. Five heifers selected at random from the trial 2 ivermectin treatment were kept on for trial 3. The 10 heifers in the trial 2 control treatment were split into two groups of five for trial 3. One group was left as a control, whilst the other group was treated with deltamethrin.
Figure 2. The relationship between the treatments in trial 2 and trial 3. Five heifers selected at random from the trial 2 ivermectin treatment were kept on for trial 3. The 10 heifers in the trial 2 control treatment were split into two groups of five for trial 3. One group was left as a control, whilst the other group was treated with deltamethrin.
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Figure 3. Mean number (±95% confidence intervals) of female Culicoides for (a) Obsoletus group and (b) Pulicaris group captured on white sticky traps, mounted on the backs of Friesian heifers treated with deltamethrin, ivermectin and untreated control (n = 5) and released onto open pasture for 24 h, 1–5 weeks after treatment. Data are back-transformed from generalised linear mixed model (GLMM) predictions.
Figure 3. Mean number (±95% confidence intervals) of female Culicoides for (a) Obsoletus group and (b) Pulicaris group captured on white sticky traps, mounted on the backs of Friesian heifers treated with deltamethrin, ivermectin and untreated control (n = 5) and released onto open pasture for 24 h, 1–5 weeks after treatment. Data are back-transformed from generalised linear mixed model (GLMM) predictions.
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Figure 4. Mean number (±95% confidence intervals) of Culicoides and number blood-fed (grey bars) captured on 200 cm2 white sticky traps mounted on the backs of Friesian heifers, treated with ivermectin and fenbendazole (control) (n = 10) and released onto open pasture for 24 h. Data are back-transformed from GLMM predictions.
Figure 4. Mean number (±95% confidence intervals) of Culicoides and number blood-fed (grey bars) captured on 200 cm2 white sticky traps mounted on the backs of Friesian heifers, treated with ivermectin and fenbendazole (control) (n = 10) and released onto open pasture for 24 h. Data are back-transformed from GLMM predictions.
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Figure 5. Mean number (±95% confidence intervals) of Culicoides and number blood-fed (grey bars) captured on 200 cm2 white sticky traps which were mounted on the backs of Friesian heifers treated with ivermectin, deltamethrin or fenbendazole (control) (n = 5) and released onto open pasture for four consecutive 24 h periods. Data are back-transformed from GLMM predictions.
Figure 5. Mean number (±95% confidence intervals) of Culicoides and number blood-fed (grey bars) captured on 200 cm2 white sticky traps which were mounted on the backs of Friesian heifers treated with ivermectin, deltamethrin or fenbendazole (control) (n = 5) and released onto open pasture for four consecutive 24 h periods. Data are back-transformed from GLMM predictions.
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Figure 6. Mean number (±95% confidence intervals) of dead Culicoides combed from heifers treated with ivermectin, deltamethrin or fenbendazole (control) (n = 5). Data are back-transformed from GLMM predictions.
Figure 6. Mean number (±95% confidence intervals) of dead Culicoides combed from heifers treated with ivermectin, deltamethrin or fenbendazole (control) (n = 5). Data are back-transformed from GLMM predictions.
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Table
Table 1. Timing of treatments (days after application of ivermectin or deltamethrin) and sampling of heifers for Culicoides using sticky traps and combing in two consecutive trials in a Northern Irish pasture. The ivermectin-treated animals from trial 2 were also sampled in trial 3.
Table 1. Timing of treatments (days after application of ivermectin or deltamethrin) and sampling of heifers for Culicoides using sticky traps and combing in two consecutive trials in a Northern Irish pasture. The ivermectin-treated animals from trial 2 were also sampled in trial 3.
Trial NumberDateDays after Ivermectin TreatmentDays after Deltamethrin TreatmentActivity
Trial 228 Aug0-Ivermectin applied
2 Sep5-Sticky traps attached
3 Sep6-Sticky traps collected and attached
4 Sep7-Sticky traps collected
Trial 34 Sep70Deltamethrin applied
8 Sep114Sticky traps attached
9 Sep125Sticky traps collected and attached
10 Sep136Sticky traps collected and attached
Flanks combed
11 Sep147Sticky traps collected and attached
Flanks combed
12 Sep158Sticky traps collected
Flanks combed

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Murchie, A.K.; Thompson, G.M.; Clawson, S.; Brown, A.; Gordon, A.W.; Jess, S. Field Evaluation of Deltamethrin and Ivermectin Applications to Cattle on Culicoides Host-Alighting, Blood-Feeding, and Emergence. Viruses 2019, 11, 731. https://doi.org/10.3390/v11080731

AMA Style

Murchie AK, Thompson GM, Clawson S, Brown A, Gordon AW, Jess S. Field Evaluation of Deltamethrin and Ivermectin Applications to Cattle on Culicoides Host-Alighting, Blood-Feeding, and Emergence. Viruses. 2019; 11(8):731. https://doi.org/10.3390/v11080731

Chicago/Turabian Style

Murchie, Archie K., Geoff M. Thompson, Sam Clawson, Andrew Brown, Alan W. Gordon, and Stephen Jess. 2019. "Field Evaluation of Deltamethrin and Ivermectin Applications to Cattle on Culicoides Host-Alighting, Blood-Feeding, and Emergence" Viruses 11, no. 8: 731. https://doi.org/10.3390/v11080731

APA Style

Murchie, A. K., Thompson, G. M., Clawson, S., Brown, A., Gordon, A. W., & Jess, S. (2019). Field Evaluation of Deltamethrin and Ivermectin Applications to Cattle on Culicoides Host-Alighting, Blood-Feeding, and Emergence. Viruses, 11(8), 731. https://doi.org/10.3390/v11080731

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