The focus of this chapter is to describe the pharmacology of veterinary drugs and pesticides currently approved to control important ectoparasites that adversely affect domestic animal health and production. These ectoparasites are primarily insects (fleas, flies, lice) and ascarines (ticks and mites). Effective control of these ectoparasites is not only critically important for the veterinary patients, but also from a public health perspective as several of the animal ectoparasites not only transmit disease between animals but they can also transmit major diseases to humans. Fleas are known vectors for tapeworms, Diplidium caninum, and humans can develop cat scratch disease when Bartonella henselae is transmitted from cats to humans via cat fleas. Flea allergy dermatitis is major concern for companion animals. These are amongst the most important reasons why flea control in companion animals is critical, and explains why annual expenditures to control fleas have totaled in excess of $2.0 Billion in the USA and Western Europe (Kramer and Mencke, 2001). Ticks can transmit Lyme disease, Rocky Mountain spotted fever, babesia in dogs and cattle, and heartwater in ruminants, to mention only a few. Mosquitoes can transmit West Nile virus to humans and heartworm diseases to pets, malaria to birds, rodents, and primates, and they also serve as biological vectors of viral encephalitides in horses. Flies not only transmit disease and cause damage to hides and coat of pets, their nuisance can result in decreased feed intake in livestock and thus reduced timely weight gain, resulting in economic loss to livestock farmers. Face flies are known to transmit the causative agent (Moraxella bovis) of pink eye or infectious bovine keratoconjunctivitis in cattle. Control of myiasis-causing flies can be significantly improved with effective ectoparasiticides.

The feeding behavior of ectoparasites differ and this may be critical if the drug of choice is strictly a repellent or adulticide. Adult fleas usually engorge themselves with a blood meal from the host with 5 minutes to 1 hour of infestation of the animal, with female fleas feeding for about 25 minute and males feeding for 11 minutes (Cadiergues et al., 2000). In order to prevent flea allergy dermatitis, an effective ectoparasiticide should be able to prevent this feeding behavior. Comparative efficacy studies suggest that organophosphates (OPs) and/or pyrethroids are more effective than the newer ectoparasiticides in preventing the flea from taking the first blood meal (Franc and Cadiergues, 1998). Ticks feed on a blood meal for a longer period (days) before it is completed. Under these conditions pathogens such as Borrelia burgdorferi, which causes Lyme disease, become well adapted to this long feeding period. However, with other tick-borne pathogens, such as Ehrlica and Rickettsia, transmission can occur within the first hours. For these reasons, the use of combination drugs (insecticide and repellent) will prevent ticks from attaching and feeding (Young et al., 2003). A good example of this desired combined efficacy is a drug formulation containing the repellent permethrin and the acaricide imidacloprid.

The ideal ectoparasiticide should not only be an effective repellent and adulticide, it must also be persistent in the blood or skin surface at therapeutic concentrations for a significantly long time, such as 1–3 months, so that there is adequate client compliance. Another challenge is that the formulation of an insecticide must be stable to sunlight and also water/shampooing. An excellent example of this is imidacloprid, which is photostable and persistent after shampooing compared to the early generation pyrethroids that were not very stable in sunlight. Some formulations, such as Frontline Plus^®, contain the adulticide (fipronil) as well as an insect growth inhibitor (methoprene), because by the time pets are observed to be infested with fleas, the fleas would already have laid eggs. A final consideration in choice of therapy is whether to treat the environment as well as the animal. There appears to be a new paradigm within the last 10 years of treating the pet and not the environment (Rust, 2005).

Many of the commercial topical ectoparasiticides used to treat domestic animals are formulated to be released from (i) liquid organic/aqueous formulations and/or (ii) synthetic polymers such as collars and ear tags. The rate of penetration through the skin or translocation across the skin surface is dependent on several critical pharmaceutical properties. Liquid formulations include pour-ons, topical sprays, and dips, which consist of the active ingredient and other (formerly called inert) ingredients that can modulate dermal pharmacokinetics. These other ingredients include mostly alcohols, oils, and spreading agents (Magnusson et al., 2001). The ear tags are composed of a solid organic polymeric macromolecule (e.g., polyvinyl chloride) and an active ingredient that are mixed with the tag and formed by injection molding. These devices are designed to slowly release the insecticide over a defined time period (e.g., Cutter Gold^® last 5 months) as the animal moves its head, but it should be removed at the end of the fly season or before slaughter.

Topical application is the more common for administration of ectoparasiticides. An understanding of the dermal pharmacokinetics of these drug and pesticide formulations will further the understanding of drug efficacy and safety. The fundamentals of this topic are covered in Chapter 47. Many of these drugs and pesticides are very lipophilic with large molecular weights, and therefore it is not surprising that there is slow dermal absorption and low systemic bioavailability, as well as a large volume of distribution and long plasma and tissue half-lives. All of these are important factors when considering repeat applications and strategies to minimize the emergence of pest resistance, whether it is in a house, kennel, or pasture, and also to minimize drug residues in food-producing animals.

The advantages of transdermal delivery include ease of application to the animal’s coat and it avoids the problems of first-pass metabolism and also the gastrointestinal degradation often associated with oral administration. Some of the major disadvantages associated with this route of administration are pet owners sometimes overdose the animal with topical sprays or pour-on formulations, which often result in toxicoses in sensitive populations such as feline species and juveniles. Licking is part of the natural grooming and social behavior of many animal species, which can result in significant oral absorption and subsequently increased systemic exposure in the treated and also untreated animals that are part of a large livestock herd (Laffont et al., 2003). Application of pour-on products to food animals can result in significantly longer withdrawal times when compared to administration by oral or injection routes. This is most evident with ivermectin pour-on products, which cause significant retention of ivermectin in the skin layers and thus prolong release of the drug. For example, this results in a 45-day withdrawal time for the pour-on product versus 35 days for the subcutaneous route (KuKanich et al., 2005).

Resistance has been widely reported for many popular ectoparasiticides such the avermectins, pyrethroids, and OPs. Resistance also tends to occur where there is intensive use of antiparasitic drugs, even on “well-managed” farms. There is some concern that as the newer insecticides such as the neonicotinoids become more frequently and inappropriately used, resistance can potentially emerge. However, there is little or no evidence of fleas developing resistance to the increasing and popular use of imidacloprid (Schroeder et al., 2003). Mechanisms of resistance may be related to decreased penetration, increased detoxification enzyme activity, and decreased sensitivity of the target site. These mechanisms have been more recently elucidated from a molecular basis using annotated insect genomes and recognizing that insect resistance is mediated by complex multigene enzyme systems. Pyrethroid resistance amongst insects has been associated with mutations in the sodium channel genes reducing the ability of the insecticide to bind to the sodium channel. Although resistance to imidacloprid has not been demonstrated in cat fleas, mutations in nicotinic acetylcholine receptors have been associated with some agronomic insects being resistant to this new class of insecticides (Liu et al., 2005).

Cross resistance for a specific target site is indeed very common within individual insecticide classes. However, cross-resistance across different target sites is a more severe consequence and limits insect management. Detoxification mechanisms are often the source of cross-resistance between insecticides that differ in their mechanisms of action. These detoxification enzymes include the carboxylesterases, cytochrome P450s, and glutathione-S-transferases, which are often implicated in pyrethroid and OP resistance. In a more recent observation, point mutations in the Rdl gene in a field population of cat fleas conferred cyclodiene resistance and cross-resistance to fipronil, which is one of the few new chemicals on the commercial market (Daborn et al., 2004).

Strategies that can prevent or delay resistance include: (i) appropriate selection of insecticides, (ii) insecticide rotations and mixtures, (iii) limited interactions with agricultural pesticides, and (iv) resistance monitoring. The latter is a major issue when it comes to treating fleas as there are no universally susceptible strains of cat flea known (Rust, 2005). However, the use of various genetic tools such as TaqMan-allele-specific amplification provide a promising method for assaying large populations of insects for insecticide resistance to the newer chemicals on the commercial market. With this in mind, the reader is encouraged to consult reviews (ffrench-Constant et al., 2004) on how the new genetic tools are addressing insecticide resistance.

Fipronil was first approved in 1996 for use in dogs and cats to treat for fleas and ticks. This chemical has been marketed as Frontline^® Top Spot and Frontline^® Plus for dogs, puppies, cats, and kittens, and Frontline^® Spray Treatments for cats and dogs. The Plus product indicates that fipronil was formulated with methoprene, which is an insect growth regulator (IGR) (methoprene is discussed in more detail in Section Insect Growth Regulators). The TopSpot product contains 9.7% fipronil and the Spray contains 0.29%. A more recent fipronil formulation is Frontline^® Tritak for dogs (9.8% fipronil, 8.8% methoprene, and 5.2% cyphenothrin) and Frontline^® Tritak for cats (9.8% fipronil, 11% methoprene, and 15% etofenprox). Cyphenothrin and etofenprox are pyrethroid or pyrethroid like and are discussed in Section Pyrethrins and Synthetic Pyrethroids.