Patent Publication Number: US-2022217943-A1

Title: System and method for eradicating ectoparasites

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     The present application is a non-provisional under 35 U.S.C. § 119(e), and claims benefit of priority from, U.S. Provisional Patent Application No. 63/135,219, filed Jan. 8, 2021, the entirety of which is expressly incorporated herein by reference. 
    
    
     FIELD OF INVENTION 
     This disclosure generally relates to an air conveying device and methods used to kill lice and lice eggs at the base of the hair shafts. More particularly this disclosure relates to a device that utilizes heated air to kill lice and lice eggs. 
     BACKGROUND OF THE INVENTION 
     The statements in this section merely provide background information related to the present disclosure and may not constitute prior art. All references cited herein are expressly incorporated herein by reference in their entirety. 
     Head lice is a parasitic insect that infects between 6 million to 12 million people a year in the United States and are typically found on the head, eyebrows, and eyelashes of humans. Although head lice can be found on virtually any human, they are most commonly found on children ages three to eleven attending preschool, or elementary school. This is likely due to the proximity and constant contact children have with each other in a school setting. Because head lice prefer warm humid environments, and do not live long without a blood supply, the most likely form of transmission is head-to-head or hair-to-hair contact and less likely due to the use of shared combs, brushes, towels, bedding or clothing. Lice are part of the ectoparasite family and are no larger than a sesame seed. According to the Centers for Disease Control and Prevention (CDC), nits (eggs) that are laid by the adult female louse are so small (about the size of pin head) that they are difficult to see with the naked eye and are often confused with dandruff. Nits are not laid directly on the scalp, but near the base of the hair shaft where they can easily find a food source when they hatch. They are very difficult to remove from the hair shaft because they are essentially glued to the hair when the eggs are laid. 
     The misconception of anyone who has not yet experienced a head lice infestation, is that the lice fly or jump from person to person, that the parasite is only attracted to dirty hair and that the entire household will be infected in a matter of seconds. The truth is that the degree of cleanliness and hygiene have very little or nothing to do with a lice infestation. Lice don&#39;t fly or jump, they crawl and they crawl fast. It is very difficult to find an adult louse scurrying around on the scalp of someone with a lot of hair because they are quick and will most likely be out of site before you have a chance to separate the hair. The key in determining an infestation of lice is knowing the locations of the scalp where they prefer to live and lay their eggs, which is behind the ears and on the neck. These areas of the scalp are both warm and humid which creates the perfect environment for lice to maintain body temperature and thrive. Head lice prefer environments that are of a favorable humidity and range in the temperature of 82 to 86 degrees Fahrenheit. 
     After treatment it can be difficult to determine if there is still an active infestation because even after the nits are dead or hatched, the egg will remain glued to the hair shaft until it is physically removed by a nit comb or the glue dries up and they fall off. However, the location of the nit on the hair shaft can be a good indicator of a current or past infestation. According to a “Human Lice” publication by the Texas A&amp;M AgriLife Extension Service, lice lay their eggs within 1 cm of the scalp, and human hair grows, on average, about ⅛″ per week. If it takes about 7 days for nits to hatch, it can be assumed that if a nit is found more than ¼″ from the scalp it is likely from a past infestation and the egg is either empty or dead. 
     According to the CDC, the recommended treatment for a person diagnosed with an active infestation is the use of over the counter (OTC) drugs or prescription medication. These medications, also called pediculicides, are most effective on lice, unless they have a strong ovicidal effect, then the nits have higher probability of being eradicated as well. In most cases retreatment is recommended, regardless of the strength of the ovicidal. According to an article published by the National Library of Medicine, studies have shown that due to the anatomy and physiology of head lice, they have become resistant to the most commonly used pediculicides. Because pediculicides are not 100% effective, an alternative treatment recommended by some experts, include the manual removal of nits that are near the base of the hair shaft with the with a nit comb. Nit combs are used to comb the hair to remove nits and lice every 2-3 days over a 2-3 week period. The effectiveness of the nit comb is impacted by the hair type and thickness as the tight spacing of the comb&#39;s teeth can induce a high degree of discomfort limiting the amount of the scalp treated. 
     A louse is a wingless insect which lives on warm-blooded hosts, including humans. Head lice, body lice and pubic lice may suck blood from the host, or even chew the skin of the host. Human head lice tend to live, feed, and lay their eggs (nits), within a distance of about 6 mm from the human scalp, where the conditions of temperature and humidity, as well as the proximity to their source of food is ideal for their survival. Female lice typically attach their eggs, the nits, to the base of the hair shaft within the 6 mm distance from the scalp. Nits hatch into nymphs and mature to become adult lice within a few weeks, at which point the female adult louse can lay eggs. 
     Head lice cannot hop or fly, but they can crawl very fast along a hair shaft. The greatest risk for exposure to infestation by head lice is head-to-head contact with a person who has a head lice infestation. Another risk, but a lesser one, is the shared use of personal items, such as bedding, towels, hats, scarves and hair brushes, as head lice can survive on a human host for approximately 30 days, but they generally cannot survive longer than 24 hours off the host. Once a lice infestation begins, it can become full-blown very quickly, as the female louse can lay several hundred eggs during her 30-day life span. The lice and nits further prove to be very resilient and difficult to get rid of. Lice have six legs equipped with claws with which they grip a strand of hair tightly. The female louse lays each egg into a glue-like casing on the hair shaft which firmly cements each nit to the strand of hair. Neither the lice nor the nits are easily dislodged from the hair. 
     Head lice are wingless insects that spend their entire lives on the human scalp and feeding exclusively on human blood. Humans are the only known hosts of this specific parasite, while chimpanzees host a closely related species,  Pediculus schaeffi . Other species of lice infest most orders of mammals and all orders of birds. en.wikipedia.org/wiki/Head_louse 
     Lice differ from other hematophagic ectoparasites such as fleas in spending their entire lifecycle on a host. Head lice cannot fly, and their short, stumpy legs render them incapable of jumping, or even walking efficiently on flat surfaces. 
     The non-disease-carrying head louse differs from the related disease-carrying body louse ( Pediculus humanus humanus ) in preferring to attach eggs to scalp hair rather than to clothing. The two subspecies are morphologically almost identical, but do not normally interbreed. From genetic studies, they are thought to have diverged as subspecies about 30,000-110,000 years ago, when many humans began to wear a significant amount of clothing. A much more distantly related species of hair-clinging louse, the pubic or crab louse ( Pthirus pubis ), also infests humans. It is morphologically different from the other two species and is much closer in appearance to the lice which infest other primates. Louse infestation of the body is known as pediculosis, pediculosis capitis for head lice, pediculosis corporis for body lice, and phthiriasis for pubic lice. 
     Head lice (especially in children) have been, and still are, subject to various eradication campaigns. Unlike body lice, head lice are not the vectors of any known diseases, however rare secondary infections can result from scratching at bites. Head louse infestations may be beneficial in helping to foster a natural immune response against lice which helps humans in defense against the far more dangerous body louse, which is capable of transmitting dangerous diseases. 
     Like other insects of the suborder Anoplura, adult head lice are small (2.5-3 mm long), dorsoventrally flattened (see anatomical terms of location), and wingless.[ 8 ] The thoracic segments are fused, but otherwise distinct from the head and abdomen, the latter being composed of seven visible segments. Head lice are grey in general, but their precise color varies according to the environment in which they were raised. After feeding, consumed blood causes the louse body to take on a reddish color. One pair of antennae, each with five segments, protrudes from the insect&#39;s head. Head lice also have one pair of eyes. Eyes are present in all species within the Pediculidae family, but are reduced or absent in most other members of the Anoplura suborder. Like other members of the Anoplura, head louse mouthparts are highly adapted for piercing the skin and sucking blood. These mouth parts are retracted into the insect&#39;s head except during feeding. 
     Six legs project from the fused segments of the thorax. As is typical in the Anoplura, these legs are short and terminate with a single claw and opposing “thumb”. Between its claw and thumb, the louse grasps the hair of its host. With their short legs and large claws, lice are well adapted to clinging to the hair of their host. These adaptations leave them incapable of jumping, or even walking efficiently on flat surfaces. Lice can climb up strands of hair very quickly, allowing them to move quickly and reach another host. 
     Like most insects, head lice are oviparous. Females lay about three or four eggs per day. Louse eggs (wrongly named also nits, see below), are attached near the base of a host hair shaft. Eggs are usually laid on the base of the hair, i.e., 3-5 mm off the scalp surface. In warm climates, and especially the tropics, eggs may be laid 6 inches (15 cm) or more down the hair shaft. To attach an egg, the adult female secretes a glue from her reproductive organ. This glue quickly hardens into a “nit sheath” that covers the hair shaft and large parts of the egg except for the operculum, a cap through which the embryo breathes. The glue was previously thought to be chitin-based, but more recent studies have shown it to be made of proteins similar to hair keratin. Each egg is oval-shaped and about 0.8 mm in length. They are bright, transparent, and tan to coffee-colored so long as they contain an embryo, but appear white after hatching. Head lice hatch typically six to nine days after oviposition. 
     After hatching, the louse nymph leaves behind its egg shell (usually known as a “nit”, see below), still attached to the hair shaft. The empty egg shell remains in place until physically removed by abrasion or the host, or until it slowly disintegrates, which may take 6 or more months. 
     Head lice, like other insects of the order Phthiraptera, are hemimetabolous. Newly hatched nymphs will moult three times before reaching the sexually-mature adult stage. Thus, mobile head lice populations may contain eggs, nits, three nymphal instars, and the adults (male and female) (imago). Metamorphosis during head louse development is subtle. The only visible differences between different instars and the adult, other than size, is the relative length of the abdomen, which increases with each molt., as well as the existence of reproductive organs in the adults. Aside from reproduction, nymph behavior is similar to the adult. Like adults, nymphs feed also only on human blood (hematophagia), and cannot survive long away from a host. Outside their hosts lice can&#39;t survive more than 24 hrs. The time required for head lice to complete their nymph development to the imago lasts for 12-15 days. Nymph mortality in captivity is about 38%, especially within the first two days of life. In the wild, mortality may instead be highest in the third instar. Nymph hazards are numerous. Failure to completely hatch from the egg is invariably fatal. Death during molting can also occur, although it is reportedly uncommon. During feeding, the nymph gut can rupture, dispersing the host&#39;s blood throughout the insect body. This results in death within a day or two. During its lifespan of 4 weeks a female louse lays 50-150 eggs. Eggs hatch within 6-9 days, each nymphal stage lasts for 4-5 days and accordingly the period from egg to adults lasts for 18-24 days. Adult lice live for an additional 3-4 weeks. All stages except eggs are blood-feeders and bite the skin four to five times daily to feed. They inject saliva which contains an anticoagulant and suck blood. The digested blood is excreted as dark red frass. 
     Although any part of the scalp may be colonized, lice favor the nape of the neck and the area behind the ears, where the eggs are usually laid. Head lice are repelled by light and move towards shadows or dark-colored objects in their vicinity.
     Buxton, Patrick A. (1947). “The biology of  Pediculus humanus ”. The Louse; an account of the lice which infest man, their medical importance and control (2nd ed.). London: Edward Arnold. pp. 24-72.   Maunder, J. W. (1983). “The Appreciation of Lice”. Proceedings of the Royal Institution of Great Britain. 55: 1-31.   Buxton, Patrick A. (1947). “The crab louse  Pthirus pubis ”. The Louse; an account of the lice which infest man, their medical importance and control (2nd ed.). London: Edward Arnold. pp. 136-141.   Rozsa, L; Apari, P. (2012). “Why infest the loved ones—inherent human behaviour indicates former mutualism with head lice” (PDF). Parasitology. 139 (6): 696-700. doi:10.1017/s0031182012000017. PMID 22309598. S2CID 206247019.   Buxton, Patrick A. (1947). “The Anoplura or Sucking Lice”. The Louse; an account of the lice which infest man, their medical importance and control (2nd ed.). London: Edward Arnold. pp. 1-4.   Buxton, Patrick A. (1947). “The Anatomy of  Pediculus humanus ”. The Louse; an account of the lice which infest man, their medical importance and control (2nd ed.). London: Edward Arnold. pp. 5-23.   “Lice (Pediculosis)”. The Merck Veterinary Manual. Whitehouse Station, N J USA: Merck &amp; Co. 2008. Retrieved 2008-10-08.   Meinking, Terri Lynn (May-June 1999). “Infestations”. Current Problems in Dermatology. 11 (3): 75-118. doi:10.1016/S1040-0486(99)90005-4.   Burgess, I. F. (1995). “Human lice and their management”. Advances in Parasitology Volume 36. Advances in Parasitology. 36. pp. 271-342. doi:10.1016/50065-308X(08)60493-5. ISBN 978-0-12-031736-3. PMID 7484466.   Pollack R J, Kiszewski A E, Spielman A (August 2000). “Overdiagnosis and consequent mismanagement of head louse infestations in North America”. The Pediatric Infectious Disease Journal. 19 (8): 689-93, discussion 694. doi:10.1097/00006454-200008000-00003. PMID 10959734. S2CID 2557006.   Burgess, I. F. (2004). “Human lice and their control”. Annu. Rev. Entomol. 49: 457-81. doi:10.1146/annurev.ento.49.061802.123253. PMID 14651472.   “How to get rid of head lice”. 25 Dec. 2021. Retrieved 5 Aug. 2021.   “Back to school herbalism—natural ways to nuke nits”. Irish Examiner. 1 Sep. 2018. Retrieved 23 Dec. 2018.   Mumcuoglu K Y, Pollack R J, Reed D L, Barker S C, Gordon S, Toloza A C, Picollo M I, Taylan-Ozkan A, Chosidow O, Habedank B, Ibarra J, Meinking T L, Vander Stichele R H (March 2020). “International recommendations for an effective control of head louse infestations”. International Journal of Dermatology. 60 (3): 272-80. doi:10.1111/ijd.15096. PMC 7984059. PMID 32767380.   Bacot, A. (1917). “Contributions to the bionomics of  Pediculus humanus  (vestimenti) and  Pediculus  capitis”. Parasitology. 9 (2): 228-258. doi:10.1017/S0031182000006065.   Mumcuoglu K Y (May 2006). “Effective treatment of head louse with pediculicides”. Journal of Drugs in Dermatology. 5 (5): 451-2. PMID 16703782.   Weems, Jr., H. V.; Fasulo, T. R. (June 2007). “Human Lice: Body Louse,  Pediculus humanus humanus  Linnaeus and Head Louse,  Pediculus humanus  capitis De Geer (Insecta: Phthiraptera (=Anoplura): Pediculidae)”. University of Florida, Institute of Food and Agricultural Sciences. Retrieved 2008 Feb. 21.   Nuttall, George H. F. (1919). “The biology of  Pediculus humanus , Supplementary notes”. Parasitology. 11 (2): 201-221. doi:10.1017/s0031182000004194.   Mumcuoglu K Y, Barker S C, Burgess I E, et al. (April 2007). “International guidelines for effective control of head louse infestations”. Journal of Drugs in Dermatology. 6 (4): 409-14. PMID 17668538.   

     Various compositions, devices and methods have been devised to treat the head louse, the most common of which include pediculicides (substances used to treat lice, e.g., shampoos containing an insecticide) and fine-toothed nit combs. 
     Since the introduction of pediculicides to the lice-treatment market, lice have adapted and become resistant to some of the chemicals that once reliably killed them. Removal of lice and eggs from the head by fine-toothed comb is tedious, time-consuming, and often ultimately frustrating, as the efficacy of this treatment is highly dependent on the skill and meticulousness of the treatment provider. Due to the difficulties of treatment, head lice infestations cause inconvenience to millions of people each year, particularly when they occur among kindergarten and school-age children among whom head lice infestations can spread quickly. 
     Biologically, lice and nits cannot survive exposure to a blast of hot air for even a fraction of a second. When exposed to gradual heating, lice may have the opportunity to secrete hormones to increase their resistance to heat and their endurance in an overheated environment. In contrast, when lice and nits are exposed to a short pulse of extreme heat, their biological systems are overwhelmed by the mass of hot air, and they experience thermal shock. Following heat blast treatment on lice and nits, the shell of the louse shrinks and deforms, and the proteins in the body inside the shell undergo a process of coagulation, such as occurs to animal proteins cooked at high temperatures. 
     In an ordinary combing operation using the parasite eradicating device, lice and nits in an infestation area are exposed to a blast of hot air as the strands of hair on which they are located pass between the combing teeth of the device. The lice and nits are caught in the barrage of hot air propelled from each airflow outlet nozzle to its facing intake aperture in the spaces between the combing teeth. The lice are killed instantly or critically damaged by the blast of heat, and the nits are rendered non-viable, and will not hatch. 
     U.S. Pat. No. 5,261,427 discloses a lice comb device containing a blower heater, to heat and direct a stream of heated air toward a set of comb teeth attached to the device housing. 
     U.S. Pat. No. 5,261,427 discloses a comb by which it is possible to blow hot air steam through the teeth of the comb when the comb is run though the hair. The temperature of the steam and/or the chemical or natural agent added to the steam will kill the lice and nits when the comb is pulled though the hair. 
     US 20060130393 discloses a method of eliminating an ectoparasite infestation that includes steps of defining a target area on an animal having an ectoparasite infestation, heating a volume of air, and applying the heated air to the target area with an airflow. 
     CH 272949A already discloses an applicator that provides an air flow for treating animals with lice infestation, in order to substantially eliminate both the lice and the nits on the animal, and which essentially comprises a base applicator designed to be coupled to a blower, an applicator tip connected to the base applicator and a plurality of fingers on the applicator tip that act as ports to supply an air flow, since it is open on the same side, such that the applicator tip substantially supplies the entire air flow to a single input side of the applicator. Moreover, the applicator tip is dismountable. 
     EP2326200 also discloses an applicator designed to distribute an air flow to treat a subject with lice infestation, which, although it presents certain improvements with respect to the preceding document, is still based on a pronged applicator that is coupled to a blower equipped with a resistance, i.e., it is a hair drier thanks to which the parasites become dehydrated and die. 
     US 20180255901 discloses an apparatus for removing head lice consisting of a base comprising a drier, formed by a blower or turbine equipped with a resistance that expels air, coupled to an applicator with a dismountable pronged tip, and, further comprises a suction device formed by a second turbine, which in this case aspirates air, coupled to an applicator equipped with a dismountable tip in the form of a nozzle. The apparatus is equipped with two separate compartments in the casing that forms the base, wherein one houses the drier, i.e., the motor plus the resistance, and the other houses the suction device. The suction device makes it possible to clean the hair and eliminate the already dead, dehydrated head lice that still remain therein, together with the nits. To this end, the suction device comprises a “nit-removing comb”, or very fine comb coupled to the applicator nozzle, which completely removes any remaining head lice or nits from the hair. The device allows for the simultaneous use of both elements, such that the drier may utilize the heat generated by the suction device motor and use it for the blower, without switching on the resistance thereof; consequently, the device is not using a drier, but a “blower”, which utilizes the heat from the suction device motor to dehydrate the head lice, provided that both systems are used simultaneously. 
     US 20200268124 provides a parasite eradicating device configured for eradicating parasites by producing a high-temperature airflow, directing it in a stream at an infestation area where parasites thrive, and suctioning the airflow away from the infestation area, such that the parasites are killed and their eggs rendered nonviable by the heat of the airflow. 
     U.S. Pat. No. 7,789,902 provides a method of eliminating an ectoparasite infestation including defining a target area on an animal having an ectoparasite infestation, heating a volume of air to a temperature to form heated air, applying the heated air to the target area with an airflow such that the heated air impinges directly on substantially all ectoparasites located within the target area, and maintaining the heated air at the target area for a period of time sufficient to affect an ectoparasite mortality rate of at least 50%. 
     U.S. Pat. No. 8,475,510 discloses airflow applicators for delivering directional, heated air to, for example, the scalp and hair of humans and/or animals to eliminate ectoparasites, such as lice and lice eggs. In preferred embodiments, the applicators are configured to deliver heated airflow (from a separate device, or from another portion of a single device, that generates heated airflow) efficiently right to where ectoparasites and their eggs most frequently reside. Also disclosed are treatment methods, including preferred treatment patterns, for delivering heated airflows for use in eliminating ectoparasites and their eggs on an animal. 
     A blast of hot air having a high temperature in a range between 80° C. and 120° C. can exterminate/damage a louse in a fraction of a second. The parasite eradicating device according to the present disclosure can be configured so that the amount of time that parasites and nits can be exposed to the high-temperature airflow during combing operation, is sufficient for extermination of the parasites and nits exposed to the stream of hot air. 
     To maximize efficacy, the barrage of hot air propelled from an airflow outlet nozzle to a neighboring intake aperture can occur in close proximity to the infestation area surface, such as a range of 0-6 mm from the infestation area surface, and practically, from the distal end of the respective combing tooth. In a parasite infestation, the greatest concentration of parasites and nits can be found in this range of distance from the infestation area surface, where the conditions of temperature and humidity, as well as the proximity to their source of food is ideal for their survival and prosperity. 
     However, such high temperatures risk damage to the scalp. 
     A spacer can be a heat insulating element formed of a non-thermal conductive material, integral or integrated with an operational combing tooth and forming a separation between the operational combing tooth and the infestation area surface when the hand-held unit is brought as close as possible to the infestation area surface. The spacer can be integral with at least the distal end of the combing tooth, or integrated therewith. A spacer can also be an auxiliary combing tooth, located in a position adjacent to an operational combing tooth, so that when the hand-held unit is brought as close as possible to the infestation area surface, the auxiliary combing tooth comes into contact with the infestation area surface, but the operational combing tooth does not come into contact with the infestation area surface. 
     A spacer may have active cooling. The spacer can be formed of tubing made of a thermally conductive material, surrounding the distal end of the operational combing tooth in close proximity thereto, and forming part of a closed circuit through which coolant fluid can flow and draw heat away from the infestation area surface. The cooling fluid can absorb heat as it flows in the tubing around the distal end of an operational combing tooth near the infestation area surface, and can dissipate heat over the distance it flows through the circuit after flowing away from the infestation area surface. Alternatively, heat can be actively removed at an area remote from the infestation area surface, and the cooling fluid can be re-cooled and recirculated by the cooling system. 
     The temperature can be reduced by reducing the heat being delivered to the device in the vicinity of the temperature sensor. This can be accomplished, for example, by causing an automatic shut-off of the device, or by causing the heating element to turn off. In another example, the temperature sensed by the temperature sensor can be reduced by increasing the heat removal rate in the vicinity of the temperature sensor. This can be accomplished, for example, by causing an increase in the rate of suction flow suctioning hot air through at least the airflow intake aperture disposed at the location of the temperature sensor where the temperature was detected to rise above the allowable temperature threshold. 
     Likewise, when a detected temperature is determined to be lower than a pre-defined threshold value, the device can be configured to respond in such a way as to increase the flow of hot air at least where the temperature was detected to be below a minimum threshold value necessary for treatment. If the temperature remains lower than a pre-defined threshold value for a period of time exceeding a pre-defined duration, the device can be configured to shut down and to alert the user of an apparent malfunction preventing the temperature of the airflow from rising high enough so that effective treatment can be provided. Device can be preset to 3-6 treatment levels as option for the user to pre-define the treatment level of delivered energy (temperature and flow rate) to kill lice (aggressive, effective or gentle etc.) 
     A steam treatment of the hair near the scalp may damage the hair. It can also be difficult to direct enough steam into thick and curly hair to obtain the necessary temperature to kill the lice and nits that are near the hair roots, without applying too much steam and then either burning the scalp or damaging the hair. 
     Heat treatments can also be carried out by using a hair drying system comprising a cap which is connected to blowing and heating means. U.S. Pat. Nos. 5,829,157 and 5,887,357 discloses a cap for hair drying that can be used for heat treatment against lice and nits. However, practical experience has shown that heat treatment by the use of traditional hair drying caps against lice is poor due to the capability of the lice to adapt to the high temperatures under the cap. The ability of the lice to adapt and regulate to high temperatures are due to their exo-skeleton, which means that the skeleton is located on the outside on the lice. 
     See, 20200268124; 20180255901; 20140013653; 20130312780; 20100331931; 20180255901; 20160018100; 20110118196; 20100145417; 20100086577; 20100049286; 20080212312; 20080193387; U.S. Pat. Nos. 10,575,616; 8,475,510; 6,053,180; 8,475,510; US 20100071713 A1; Mar. 25 2010;; U.S. Pat. No. 3,721,250; 3,903,905; 3,955,065; 3,986,272; 4,003,388; 4,050,469; 4,085,309; 4,114,022; 4,295,283; 4,327,278; 4,376,441; 4,380,790; 4,557,247; 4,572,188; 4,671,303; 4,676,260; 4,683,370; 4,692,594; 4,759,135; 4,815,232; 4,819,670; 4,848,007; 4,904,847; D307192; 4,927,813; 4,955,145; 4,961,283; 5,067,444; 5,072,746; 5,078,157; 5,112,515; 5,157,757; 5,178,168; 5,195,253; 5,235,759; 5,261,427; 5,275,339; 5,287,635; 5,288,483; 5,292,504; 5,300,098; 5,300,101; 5,300,102; 5,303,483; D349585; 5,343,881; 5,350,417; D354,152; 5,434,946; D365,662; 5,486,205; 5,488,783; D368,342; D369,229; 5,526,578; 5,554,360; 5,621,980; 5,628,332; 5,636,646; 5,649,502; 5,658,750; D384,772; 5,674,269; D392,413; 5,727,331; 5,733,320; 5,765,292; 5,768,749; 5,783,202; 5,785,723; 5,858,383; 5,875,282; 5,876,428; 5,918,607; 5,937,139; 5,953,829; D414,896; 5,968,084; 5,968,507; 5,972,987; 5,977,186; 5,997,846; 5,997,847; 6,006,758; 6,053,180; 6,063,771; 6,086,682; D433,182; 6,126,681; 6,130,253; 6,139,859; 6,141,901; 6,143,020; 6,146,411; 6,146,412; 6,158,443; 6,169,850; D441,136; 6,254,337; 6,262,031; 6,265,384; 6,266,893; 6,269,549; 6,303,581; 6,342,253; 6,3424,82; 6,350,724; 6,350,734; 6,355,915; 6,357,491; 6,386,845; 6,408,533; 6,425,403; D462,141; 6,440,157; 6,440,388; 6,485,734; 6,524,604; 6,541,455; 6,541,740; 6,565,665; 6,572,333; D477,112; 6,588,140; 6,596,291; 6,607,716; 6,637,440; 6,663,860; 6,663,876; 6,678,994; 6,685,969; 6,689,079; 6,689,394; 6,691,713; D487,945; 6,701,552; 6,727,228; D490,185; 6,745,996; D493,571; 6,793,931; 6,827,729; 6,876,884; 6,936,269; 6,974,584; 7,030,095; 7,037,068; 7,040,037; 7,047,660; 7,064,108; D524,983; 7,089,945; 7,090,833; 7,178,261; 7,220,273; 7,264,004; 7,282,211; 7,294,342; 7,3579,39; 7,361,366; 7,389,779; 7,393,528; 7,412,781; 8,118,036; 5,435,327; 6,086,682; 20130284111; 20040126403; 20040126435; 20050013727; 20050051190; 20050261740; 20060130393; 20070068544; 20080214657; 20100049285; 20100049286; 20100071713; 20100145417; 20100331931; 20180255901; 20160018100; 20100145417; 20100086577; 20100049286; 20080212312; CH 272949; CH 272949; EP 2326200; ES 1094613; EP 0689783; EP 0693262; EP 1036522; WO 90/10432; WO 91/05561; WO 91/15953; WO 91/16032; WO 94/16665; WO 98/30124; WO 99/35498; WO 99/52410; WO 99/66790; WO 00/00213; WO 00/19857; WO 00/42982; WO 00/54816; WO 00/62613; WO 00/72814; WO 01/52689; WO 01/78750; WO 02/089584; WO 03/045145; WO 03/056972; WO 03/057231; WO 03/066009; WO 03/092583; WO 2005/007188; WO 2005/079563; WO 2005/107453; WO 2005/113060; WO 2006/017263; WO 2006/026806; WO 2006/071248; WO 2006/125160; WO 2006/137141; WO 2007/056813; WO 2007/104345; WO 2008/007055; WO 2008/022386; WO 2008/022387; WO 2008/038108; WO 2008/067054; WO 2008/087148; WO 2008/122837;
     Hiraoka Tauyoshi et al. “Thermotolerance of human body louse  Pediculus humanus  corporis 1: Treatment of adults and eggs by hot water” Jpn. J. Sanit. Zool. 1995 pp. 77-79 vol. 46.   Kobayashi Mutsuo et al. “Thermotolerance of human body louse  Pediculus humanus  corporis 2: Preliminary evaluation of hot air for killing adults and eggs” Jpn. J. Sanit. Zool. 1995 pp. 83-86 vol. 46.   Pearlman Dale Lawrence M D A Simple Treatment for Head Lice: Dry on Suffocation-Based Pediculicide Pediatrics Sep. 3, 2004 vol. 114.   

     SUMMARY OF THE INVENTION 
     The present invention provides an ectoparasite eradicating device configured to eradicate lice and nits by conveying and directing heated air to the base of the hair shaft where lice live and lay eggs. Current methods for eradicating lice include pesticides, home remedies, and heated air treatments. The problem with the current methods is they are either dangerous, expensive, ineffective, time consuming or require the help of another person. 
     The system is designed to eliminate the challenges that many people encounter today when faced with a lice infestation, whether it is on someone else or them self. The device is designed with a combination of guides to direct the heated air more accurately in a forward direction, while staying parallel to the scalp during the treatment process. 
     The device uses a horizontal airflow guide designed at a specific height and shaped to match the curvature of the scalp to ensure that all the air being delivered is as close to the scalp as it needs to be, across the comb head of the device. Having the horizontal airflow guide that is perfectly horizontal could result in missed louse eggs on the hair shafts, which are contacted with the comb head at the outside edges where the biggest gaps will be between the guide and the scalp. To further facilitate accuracy of the heated airflow, the bottom of the combing teeth are curved to match the natural curvature of the scalp in both directions, such that the entire face of each tooth is in contact with scalp at all times. At the leading edge of the horizontal airflow guide, is a small abruption that trips a small portion of the lower part of the airflow stream, causing the air to be tripped and rolled creating a small vortex. The small vortex that is created develops a small boundary layer of air that essentially extends the boundary of the airflow guide allowing the airflow stream to extend further from the comb head before the air becomes turbulent and spreads out. 
     The device also embodies a swivel between the comb head and the airflow chamber that connects to the blow dryer. The airflow chamber has a bend in it such that when the treatment process is being performed and the device is being transitioned from the back of the head to the front of the head, the person performing the treatment can reach around the head without discomfort and repositioning device and oneself. Furthermore, having the ability to change the position of the blow dryer allows for a person to perform the treatment process independently on themself. 
     The device provides a universal connection using a ribbed, silicon sleeved, tapered collar, adapted to interface between blow dryers having a range of diameters. The most commonly used blow dryers used are designed with nozzles of similar size allowing the device to be functional without having to acquire additional equipment. Furthermore, almost all blow dryers on the market can deliver the minimum required temperature that will eradicate lice and nits, which is of temperature that could harm the patient, so developing a way to deliver the air to the lice and nit infested area is necessary to eliminate having to acquire special types of high temperature blowers. 
     It is therefore an object to provide an anti-ectoparasite apparatus, comprising a conduit, having a first axis and a fixation portion for releasable attachment to a tube, and being configured to receive a flow of heated air; a rotatable sleeve joint; and a comb unit connected to the conduit via the rotatable sleeve joint, the comb unit comprising; a hollow shell configured to angularly redirect air from the first axis defined by the conduit, to a second axis angularly displaced from the first axis; at least three parallel plates configured as a comb, extending from the hollow shell, the at least three parallel plates each having a foot defining a lower concave boundary configured to contact skin and move along the skin with the hair extending from the skin into the comb, wherein the at least three parallel plates are aligned with the second axis; and a surface parallel to the second axis, displaced from the feet of the at least three parallel plates, and being configured to separate the heated air received from the conduit from the skin, having a deflector situated within a space between adjacent parallel plates, the at least three parallel plates and the surface being together configured to redirect the flow of heated air from the tube along the at least three parallel plates and the surface, and dependent on a rotational angle of the rotatable sleeve joint, and to interrupt a flow of heated air along an upper side of the surface to locally introduce vortices to heat the hair proximate to a root of the hair without burning the skin. The heating of the hair is effective to kill insects, arthropods, and their eggs, e.g., of family Pediculidae and their eggs, e.g.,  Pediculus humanus.    
     The fixation portion may be configured for attachment to the tube comprising a blow dryer nozzle having a diameter between 1.4″ and 2.5″. 
     The first axis and the second axis differ by between 20° and 60°, and preferably the first axis and the second axis differ by between 30° and 60°, e.g., 40°. 
     The at least three parallel plates may comprise at least five intervening hot air flow spaces. 
     The surface may define a hollow space below the surface between the at least three parallel plates. 
     A flow of air over the surface may be configured to induce a flow of cool air in the hollow space below the surface between the at least three parallel plates. 
     The fixation portion may comprise a plurality of radial inwardly extending elastomer ribs. 
     The feet may define an interrupted surface which is concave in two dimensions. 
     It is also an object to provide an anti-ectoparasite apparatus, comprising a tubular adapter configured to surround a blow dryer nozzle having a diameter of between 3 cm and 8 cm, e.g., 3.5-7.5 cm, 4-7 cm; a rotatable sleeve, attached to the tubular adapter at an angle of between 15-60 degrees; and a diffuser, linked to the rotatable sleeve, comprising: a shroud; a comb comprising at least three parallel sheets extending from the shroud, each sheet having a lower edge configured to contact skin and move along the skin with the at least three parallel sheets perpendicular to a skin surface; and a plate parallel to the skin and intersecting the at least three parallel sheets displaced from the lower edge, defining a hot air space above the plate and cool air space below the plate, the plate having a flow deflection lip configured to interrupt a laminar air flow from the blow dryer above the plate, the rotatable sleeve being configured to reposition the shroud with respect to the blow dryer to maintain the lower edges against the scalp over a range of relative angles of the shroud and the nozzle. 
     The apparatus may be effective to kill insects of family Pediculidae and their eggs with hot air from the blow dryer. 
     The rotatable sleeve may be configured to provide at an angle of 30-60 degrees between the shroud and the nozzle. 
     A flow of the hot air above the plate may induce a flow of cool air below the plate. 
     The lower edges may define a concave surface. 
     It is a further object to provide A method for treating an ectoparasite colonization, comprising: attaching to a nozzle of a blow dryer a fixation portion of a conduit, the conduit having a first axis and being configured to receive a flow of heated air, the conduit being interfaced with a comb unit with a rotatable sleeve joint, the comb unit comprising; a hollow shell which angularly redirects air from the blow dryer along the first axis, to a second axis angularly displaced from the first axis; at least three parallel plates configured as a comb, extending from the hollow shell, the at least three parallel plates each having a foot defining a lower concave boundary configured to contact skin and move along the skin with the hair extending from the skin into the comb, wherein the at least three parallel plates are aligned with the second axis; and a surface parallel to the second axis, displaced from the feet of the at least three parallel plates, which separates the heated air from the blow dryer from the skin, having a deflector situated within a space between adjacent parallel plates, the at least three parallel plates and the surface together redirecting the flow of heated air from the blow dryer along the at least three parallel plates and the surface, and dependent on a rotational angle of the rotatable sleeve joint, interrupting a flow of heated air along an upper side of the surface to locally introduce vortices; placing the feet against a scalp with the blow dryer blowing hot air; and displacing the feet along the scalp it heat the ectoparasites at a distance of 5 mm from the scalp to a temperature above 120° F. for at least 5 seconds, without burning the scalp. 
     Said displacing may comprise holding sections of hair up and combing the hair opposite to the direction of hair growth with the comb. 
     The method may further comprise holding the feet with the hot air blowing at the treatment site for 5 to 15 seconds. 
     The hair is preferably dry (and combed) prior to treatment. 
     The exemplary embodiment of the presently disclosed subject matter, is a device that is configured to convey heated air, at a minimum temperature of 128° F., from a common, commercially available blow dryer, suitable for humans, and a method to eradicate ectoparasites, specifically lice and lice eggs, from the hair and scalp of a human head. The focus of the disclosure is specifically on the eradication of head lice and eggs, or nits, on a human host, but it should be known that the device and methods herein are not limited to lice but can also be applied to other species of ectoparasites. 
     All features disclosed in the specification, including the claims, abstract, and drawings, and all the steps in any method or process disclosed, may be combined in any combination, except combinations where at least some of such features and/or steps are mutually exclusive. Each feature disclosed in the specification, including the claims, abstract, and drawings, can be replaced by alternative features serving the same, equivalent, or similar purpose, unless expressly stated otherwise. 
    
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
       In order to better understand the subject matter that is disclosed herein and to exemplify how it may be carried out in practice, embodiments will be described, by way of non-limiting examples only, with reference to the accompanying drawings, in which: 
         FIG. 1  is a front perspective view of the ectoparasite eradicating device; 
         FIG. 2  is an exploded front perspective view of the hot air conveyance comb device showing the various elements that form the ectoparasite eradicating device shown in  FIG. 1 ; 
         FIG. 3  is a top view of the ectoparasite eradicating device shown in  FIG. 1  with a coordinate plane showing how the device and various elements of the device will be referenced throughout the disclosure; 
         FIG. 4  is a right-side view of the ectoparasite eradicating device shown in  FIG. 1  with a coordinate plane showing how the device and various elements of the device will be referenced throughout the disclosure; 
         FIG. 5A  is an enlarged top view of the unitized comb head; 
         FIG. 5B  is a detail view of  FIG. 5A ; 
         FIG. 6  is an elevational, cross-sectional view of the unitized comb head shown in  FIG. 5A ; 
         FIG. 7  is a top prospective, sectional view of the unitized comb head shown in FIG.; 
         FIG. 8  is a backside view of the unitized comb head shown in  FIG. 5A ; 
         FIG. 9  is top view of the unitized airflow chamber; 
         FIG. 10  is a cross-sectional view of the hot air conveyance comb elbow shown in  FIG. 9 ; 
         FIG. 11  is a cross-sectional view of the universal collar shown in  FIG. 9 ; 
         FIG. 12  is a right-side view of the ectoparasite eradicating device shown in  FIG. 1 ; 
         FIG. 13  is an enlarged, cross sectional view of the female and male interface rings shown in  FIG. 12 ; 
         FIG. 14  is a top prospective, cross sectional view of the ectoparasite eradicating device shown in  FIG. 1 ; 
         FIG. 15  is a top prospective view of the unitized hot air conveyance comb showing rotation between the unitized comb head and unitized airflow chamber, oriented so that the distal face of the combing teeth can be seen; 
         FIG. 16  is a top cross-sectional view of the ectoparasite eradicating device showing the airflow path from the blow dryer to the scalp of the actor; 
         FIG. 17  is a cross-sectional, elevation view of the ectoparasite eradicating device showing the airflow path from the hot air heating element to the scalp of the actor; 
         FIG. 18  shows the direction and location of where the ectoparasite eradicating device affixes to the blow dryer; 
         FIG. 19  shows the ectoparasite eradicating device affixed to the blow dryer; 
         FIG. 20  shows an elevation cross sectional view of how the ribbed sleeve interfaces with the universal collar of the ectoparasite eradicating device; 
         FIG. 21  is a top view of the ribbed sleeve interfacing with the universal collar; 
         FIG. 22  shows the start position of an exemplary method for treatment using the ectoparasite eradicating device; 
         FIG. 23  shows the direction and path taken in the exemplary method for treatment shown in  FIG. 22 ; 
         FIG. 24  shows the end position of the path taken in the exemplary method for treatment shown in  FIG. 23 ; 
         FIG. 25  shows the size of the ectoparasites at the three stages of life as it relates to the size of a 1 cent coin; 
         FIG. 26  is a visual representation of where the ectoparasites can be found on the hair shaft and scalp of a human head; 
         FIG. 27  is a detailed block diagram illustrating a method of using ectoparasite eradicating device according to one embodiment of the disclosure. 
     
    
    
     The drawings described herein are for illustration purposes and are not intended to limit the scope of the present disclosure in any way. 
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     A common blow dryer applies high temperature airflow streams from to the base of the hair shaft of a human scalp. In general terms a blow dryer is an electric device used to dry a person&#39;s hair by blowing warm air over the hair. Because head lice are highly susceptible to heat and do not live long when exposed to temperatures above 130° F., high temperature heat cycles from the blow dryer become a viable option in the eradication of head lice and nits. 
     Although blow dryers are most commonly used as a styling tool, they serve many purposes by men, women and children. Most blow dryers comprise a heating element, blower, handle, air intake and a nozzle. Regardless of the blow dryer brand, they are relatively similar in size and shape. Typically, the only major difference you will find, depending on the country you are in, is the plug. The most widely used blow dryers have nozzles diameter that ranges between 1.8″ and 2.3″. According to published data a typical blow dryer can blow hot air consistently in the temperature range of 80° F. and 140° F. 
     Because blow dryers have multiple settings to adjust the velocity and temperature of the airstream, testing of the various combinations was conducted. Knowing which combinations were best for killing lice was necessary to the design of the device. The method of testing included measuring the temperature of the heated air stream exiting the blow dryer at various temperature settings and velocities for two commonly found brands of blow dryers, Remington and MHU. A typical blow dryer has three temperature settings of cool, warm, and hot; and two speed settings of low and high. The testing procedure included measuring the heated air stream, at various combinations of each setting, using a high temperature digital thermometer, set at a specific distance from the blow dryer nozzle. The temperature needed to be measured at a set distance from the face of the blow dryer nozzle because placing the thermometer directly against the face of the nozzle would create inaccurate temperature readings. This is because the nozzle contains multiple components that block and deflect the airstream in various directions making it difficult to locate the best place for temperature measurement. To facility accurate airflow temperature readings, the air was channeled in a single direction using 4″ long 3D printed cylinder. One end of the cylinder diverges to allow for connection to the tapering end of a blow dryer. The diameter of the cylinder at the diverging end is about 2.5″ and the diameter of the cylinder at the opposite end is about 2″. A hole was drilled at a distance of about 3″ from the diverging end of the cylinder for insertion of the thermometer which provided a gap of about 1.5″ between the nozzle face and the thermometer. The thermometer was placed at a location where the deflected air streams converged and in proximity of the nozzle due to how quickly the heated air cools once it exits the nozzle. Because the cylinder creates a barrier between the ambient air and heated airstream, the air can be projected further before it starts to cool. Next, the temperature of the airstream was measured and recorded at a combination of settings for each blow dryer three times and the readings averaged. 
     At a setting of low heat and low speed, the Remington blow dryer supplied air at an average temperature of 88° F. At the same setting, the MHU blow dryer supplied air at an average temperature of 89° F. 
     At a setting of low heat and high speed, the Remington blow dryer supplied air at an average temperature of 113° F. At the same setting, the MHU blow dryer supplied air at an average temperature of 114° F. 
     At a setting of high heat and low speed, the Remington blow dryer supplied air at an average temperature of 140° F. At the same setting, the MHU blow dryer supplied air at an average temperature of 146° F. 
     At a setting of high heat and high speed, the Remington blow dryer supplied air at an average temperature of 178° F. At the same setting, the MHU blow dryer supplied air at an average temperature of 201° F. 
     The results showed that a common blow dryer can supply air at temperatures significantly higher than 140° F. According to an article published in July 2021 by the website “Top Ten Reviews” hair dryers can reach temperatures of around 197° F. which coincides with the testing results. 
     The results also show that in order to effectively eradicate lice and nits, the temperature setting needs to be at the highest heat setting, but can vary due to airflow speed. 
     According the National institute of Standards and Technology, the human skin begins to feel pain at a temperature off 111° F. and sustain first degree burns at 118° F. when exposed for a specific period of time. 
     The threshold at which a human feels pain depends on a variety of factors including length of exposure, location of exposure, sex, age, health status, skin type, etc. For the human scalp, exposure times and thresholds can be significantly different depending on the amount and thickness of the hair on the head. The pain threshold of a person exposed to heated air directed at the scalp with respect to age, hair type and sex, is a key factor in the design of a device used to convey high temperature air in proximity of the scalp. 
     A test was conducted to determine the pain threshold when exposed to heated air directed at the scalp of five individuals. 
     The test consisted of using a common blow dryer (Remington) and an infrared laser thermometer. The five individuals ranged in sex and age. Individual A was a 38 year old female, individual B was a 12 year old female, individual C was a 48 year old male, individual D was a 30 year old male and individual E was a 10 year old male. The parameters of the test included directing a heated air stream, at a combination of airflow settings, to the scalp of the individuals. The following data was recorded: temperature and airflow setting, distance the blow dryer nozzle was from the scalp, the quantity of time until the individual felt pain and the temperature of the scalp at the the pain was felt. 
     Following are the test results for the pain threshold recorded for each individual with the blow dryer set to high heat, low airflow and the nozzle at a distance of 6″ from the scalp. Individual A Results: 1 minute 42 seconds to feel pain. The air temperature averaged 140° F. 
     Individual B Results: 1 minute 32 seconds to feel pain. The air temperature averaged 139° F. 
     Individual C Results: Did not feel pain at 2 minutes. The air temperature averaged 132° F. 
     Individual D Results: 1 minute 24 seconds to feel pain. The air temperature averaged 136° F. 
     Individual E Results: 1 minute 26 seconds to feel pain. The air temperature averaged 137° F. 
     Following are the test results for the pain threshold recorded for each individual with the blow dryer set to high heat, high airflow and the nozzle at a distance of 6″ from the scalp. 
     Individual A Results: 70 seconds to feel pain. The air temperature averaged 162° F. 
     Individual B Results: 66 seconds to feel pain. The air temperature averaged 145° F. 
     Individual C Results: 90 seconds to feel pain. The air temperature averaged 149° F. 
     Individual D Results: 65 seconds to feel pain. The air temperature averaged 153° F. 
     Individual E Results: 50 seconds to feel pain. The air temperature averaged 145° F. 
     Following are the test results for the pain threshold recorded for each individual with the blow dryer set to high heat, low airflow and the nozzle at a distance of 3″ from the scalp. 
     Individual A Results: 25 seconds to feel pain. The air temperature averaged 143° F. 
     Individual B Results: 66 seconds to feel pain. The air temperature averaged 133° F. 
     Individual C Results: 35 seconds to feel pain. The air temperature averaged 132° F. 
     Individual D Results: 72 seconds to feel pain. The air temperature averaged 139° F. 
     Individual E Results: 52 seconds to feel pain. The air temperature averaged 131° F. 
     Following are the test results for the pain threshold recorded for each individual with the blow dryer set to high heat, high airflow and the nozzle at a distance of 3″ from the scalp. 
     Individual A Results: 3 seconds to feel pain. The air temperature averaged 173° F. 
     Individual G Results: 3 seconds to feel pain. The air temperature averaged 158° F. 
     Individual C Results: 8 seconds to feel pain. The air temperature averaged 152° F. 
     Individual D Results: 5 seconds to feel pain. The air temperature averaged 166° F. 
     Individual E Results: 3 seconds to feel pain. The air temperature averaged 156° F. 
     The results show that regardless of the age and sex of the person tested, the pain threshold fell within a certain temperature range. A heated airstream, at low velocity, directed at the scalp fell within the range of 126° F.-144° F. at a distance of 3″ and 6″. When the velocity of the air increased (while maintain the same temperature setting) the pain threshold fell within the range of 145° F.-173° F. This information is significant to the invention because it defines the safety parameters of the invention. 
     The ectoparasite eradicating device, when affixed to a blow dryer, will direct the heated air parallel to the scalp to where lice live and lay eggs. To ensure the heated air is being properly directed to the target area, the device uses horizontal and vertical airflow guides to channel and direct the airflow. The device is cylindrical shaped with combing teeth to separate and lift the hair during treatment. The horizontal guide is also used to keep the heated air stream off the scalp. The material of the device is of a material of low thermal conductance that can withstand temperatures above 400° F. for long periods of time without the structure being negatively impacted. The material used allows for the internal surface of the device to be smooth to induce laminar flow and reduce static pressure. 
     The opening of the comb where the heated air exits out of is sized to be of an area similar to the that of a blow dryer nozzle. If the opening of the device head is too small, static pressure can increase putting an extraneous load on the motor of the blow dryer potentially causing damage to it. In one embodiment a low voltage temperature sensor is used to alert the user that the temperature of the scalp is approaching a specified threshold temperature. For example, the top of the comb head comprises a detachable compartment that contains a battery, speaker and circuitry to convert the signal from the temperature sensor to an audio or visual alert mounted to the top of the compartment. The temperature sensor is placed at the underside of the horizontal airflow guide that enunciates an alarm when the temperature of the scalp rises above a specified temperature. Other sensors may include sensors at the base of the teeth that alarm when the combing teeth lose contact with the scalp indicating that the device may be tipped to far forward potentially burning the scalp of the actor. 
     Optionally, ultraviolet (UV) illuminators are provided to illuminate the tips of the combing teeth to illuminate the lice or make them glow. Because the UV is not as effective in spotting nits, special shampoos or dye can be used to coat the nits causing them to glow. 
     In another embodiment, small LED illuminators are provided at the base of the comb, directed at the scalp in front of the comb to improve the detection of the tiny nits at the base of the hair shafts. 
     Another embodiment includes a “bumper” in front of the comb that comprises vertical guides that detangle, separate and raise the hair prior contact with the comb head, allowing the heated air to flow between the strands of hair more easily. 
     In another form, the device can be used on animals to eradicate flees, ticks or other parasites that are highly susceptible to hot air. The comb used on a pet would be smaller than that used for a human scalp, allowing the device head to be more easily guided around the animal&#39;s extremities. The teeth of the comb may be more rounded and tighter together to separate and lift and animals course fur or hair and overcome the animal&#39;s loose skin. 
     The following discussion provides a general overview of the exemplary embodiments of the presently disclosed subject matter. Subsequent to the general overview will be a more detailed discussion of the exemplary embodiments and methods represented in the figures of the present invention. 
     The following terms shall be interchangeable, “parasite eradicating device” and “device”.  FIG. 3  shows a top view of the device  104 , with arrows that represent the direction at which the embodiment is being viewed. The front view is represented by arrow  130 . The left view is represented by arrow  128 . The right view is represented by arrow  124  and the back view is represented by arrow  126 .  FIG. 3  also shows the x-y coordinate plane, which will be used when describing a direction relative to a top view of an embodiment. The positive direction of the x-axis or forward direction, in the coordinate plane depicted, is represented by reference number  118 . The positive direction of the y-axis or horizontal direction, in the coordinate plane depicted, is represented by reference number  120 . 
     For the following general description of the ectoparasite eradicating device, reference  FIGS. 1-6 .  FIG. 1  is a front perspective view of the ectoparasite eradicating device  104  according to one embodiment of the presently disclosed subject matter. The illustration shows two, separate unitary parts of the device, the comb head  110  and the airflow chamber  108 . The comb head  110  comprises a set of combing teeth  76  used to guide the airflow in the horizontal direction  120 , while also separating the hair and exposing the lice and eggs to the heated air delivered by the device. The airflow in the horizontal direction is limited by the outer combing teeth  76   a  and  76   f , as shown in  FIG. 5A . 
       FIG. 4  shows an elevation view of the device  104 , with arrows that represent the direction at which the embodiment is being viewed. The front view is represented by arrow  130 . The bottom view is represented by arrow  134 . The back view is represented by arrow  126  and the top view is represented by arrow  132 .  FIG. 4  also shows the x-z coordinate plane, which will be used when describing an embodiment from an elevation view. The positive direction of the x-axis or forward direction, in the coordinate plane depicted, is represented by reference number  118 . The positive direction of the z-axis or vertical direction, in the coordinate plane depicted, is represented by reference number  140 . 
     The comb head  110  also comprises a horizontal airflow guide  74  that guides the heated air in the vertical direction  140 , at a given elevation above the scalp, to the targeted lice infested area. The airflow is limited in the vertical direction by the comb head cap  78  as shown the sectional elevation view of  FIG. 6 . The airflow chamber  108  comprises a universal collar  94  that is used to affix the device to the blow dryer. The airflow chamber  108  channels the heated air from the blow dryer, through the comb head  110 , to roots of the hair. The comb head  110  and the airflow chamber  108  couple by means of a female interface ring  70  and a male interface ring  82  in a way that enables one part to rotate about the x-axis  118 , without rotation of the other part (also known as swiveling). The shape and size of the comb head  110  and airflow chamber  108  are not limited to the shape and size depicted in the embodiments described herein. The method of interface between the comb head  110  and the airflow chamber  108  is not limited to the shape, form, size and interface method described herein. 
     Following is a more detailed description of the figures that depict various elements of the ectoparasite eradicating device  104  of the presently disclosed subject matter.  FIG. 2  represents an exploded, front prospective view of the ectoparasite eradicating device  104 . The comb head  110  comprises a set of combing teeth  76 , a comb head cap  78 , a horizontal airflow guide  74 , a square to round transition  72  and the female interface ring  70 . The airflow chamber  108  comprises a male interface ring  82 , an airflow chamber elbow  90  and a universal collar  94 . Although the comb head  110  and the airflow chamber  108  are separate unitary parts, in  FIG. 2 , the components of the comb head  110  and airflow chamber  108  have been exploded to provide a better understanding of the geometry of each element and how they interface to create a unitary part. 
     Following is a detailed description of the comb head  110  in the exemplary embodiment of the presently disclosed subject matter.  FIGS. 5-8  show how the elements of the comb head  110  interface to form a unitary part. As shown in  FIGS. 1, 2, and 5  the comb head  110  comprises six combing teeth  76   a - 76   f . The combing teeth  76   a - 76   f  are evenly spanned across the front of the comb head  110  in the horizontal direction. As shown in  FIG. 5A  combing teeth  76   a  and  76   f  create the outer boundaries of the comb head  110 . As shown in  FIGS. 16 and 17 , one purpose of the combing teeth  76   a - 76   f  is to channel the air flow stream  136 , from the blow dryer  102 , and direct it toward the targeted lice and egg infested area of the hair shafts. The set of combing teeth  76  are of a thickness that will allow the teeth to maintain rigidity and not bend or flex when the comb head  110  is guided along the surface of the scalp  106 , through all types of hair including, but is not limited to curly hair, coarse hair, tangled hair and long hair. 
     The set of combing teeth  76  are of a thickness and material that will allow for the combing teeth  76   a - 76   f  to maintain rigidity while exposed to temperatures above 128° F. for any given timeframe as the device, in one embodiment, could be used more than once, on multiple human heads, in a single setting. The quantity of combing teeth is not limited to six. The comb head  110  should comprise a minimum of two combing teeth. The quantity of combing teeth should not be of an about that negatively impacts the method of treatment described in the present disclosure. The overall shape and size of the comb head  110  is not limited to a specific size, shape or length. The set of combing teeth could be of different lengths or all the same length by really long or short, but should be of a size and shape that does not negatively impact the performance of the device during treatment. 
     The geometry of each combing tooth  76   a - 76   f  will be described using  FIGS. 5-8 .  FIG. 5A  is an elevational section view of the comb head  110 . The combing teeth  76   a - 76   f  are shaped similarly to a right triangle. The bottom side of the triangular shaped combing teeth  76   a - 76   f , which come into contact with the scalp  106  during treatment, is concaved to match the natural curvature of the human head. The front side of the combing teeth  76   a - 76   f , is shaped similarly to the letter “S”. The back side of the combing teeth  76   a - 76   f  is in the shape of a vertical line. As shown in  FIG. 6 , the point where the bottom side and front side of the combing tooth converge is rounded. The point where the back side and bottom side of the combing tooth converge is of an angle slightly less than 90°. The backside and the front side of the combing tooth do not converge, but are intersected by the comb head cap  78 , creating a flat surface at the top of the combing tooth. As shown in the backside elevation view of the comb head  110  in  FIG. 8 , the bottom of the combing tooth is chamfered  116 . 
     Although the combing teeth  76   a - 76   f  are being described singularly, the shape described is not limited to a single combing tooth but applies to all of the combing teeth  76   a - 76   f  in the embodiment of the presently disclosed subject matter. The geometry of the combing teeth  76   a - 76   f  is not limited to shape described herein. For example, the overall shape of the combing teeth  76   a - 76   f  can be, but is not limited to, elliptical, square, circular, hexagonal or in the shape of a trapezoid. Furthermore, the bottom side of the combing teeth  76   a - 76   f  can be, but is not limited to, rounded, square or comprise two or more shapes; the points at where the various sides of the combing tooth converge can be, but is not limited to, triangular or beveled; the side of the combing teeth  76   a - 76   f  that comes into contact with the scalp  106  can be, but is not limited to, flat, curving outward (convex) or wavy; the height and thickness of the combing teeth,  76   a - 76   f  can be of various heights and thicknesses. 
     Following is a detailed description of the horizontal airflow guide  74  in the exemplary embodiment of the presently disclosed subject matter.  FIGS. 2-8 and 17  shall be referenced as the horizontal airflow guide  74  is described. The purpose of the horizontal airflow guide  74  is to direct the heated airflow stream  136 , exiting the comb head  110 , in a lateral direction that is parallel to the scalp  106 , at the targeted lice and nit infested area of the hair shafts. As shown in  FIGS. 2, 5 and 7 , the horizontal airflow guide  74  spans across the entire width of the comb head  110  intersecting combing teeth  76   b - 76   e . The backside of the airflow guide  74  is flush with the back side of the combing teeth  76   a - 76   f  as shown in the perspective back sectional view of the comb head  110  in  FIG. 7 . 
     As shown in the sectional view of  FIG. 6 , the horizontal airflow guide  74  is at a height  112  above the apex of the concaved combing teeth  76   a - 76   f . The horizontal airflow guide  74  is of a height  112  such that when pressure is placed on the scalp  106 , by the comb head  110  during treatment, the bottom side of the horizontal airflow guide  74  remains at a minimum distance of 1/16″ off the surface of the scalp  106 . Furthermore, the gap that is created between the bottom of the horizontal airflow guide  74  and the surface of the scalp  106 , allows for the treated hair to pass under the comb head  110  while the ectoparasite eradicating device  104  is being used during the treatment process. The thickness of the airflow guide  74  is of a thickness that will allow the horizontal airflow guide  74  to maintain rigidity and not bend or flex when the comb head  110  is guided along the surface of the scalp  106 , through all types of hair including, but not limited to curly hair, coarse hair, tangled hair and long hair. The horizontal airflow guide  74  is of a thickness that will allow for the horizontal airflow guide  74  to maintain rigidity while exposed to temperatures above 128° F. for any given timeframe as the device, in one embodiment, could be used for more than one treatment, on multiple human heads, in a single setting. The width of the horizontal airflow guide  74 , in the direction of the x-axis  118 , is of a width that will guide the heated air laterally as it exits the comb head  110 . If the horizontal airflow guide  74  is not wide enough, in direction of the x-axis  118 , the heated air exiting the comb head  110  could contact the scalp  106  and potentially cause burns or discomfort to the actor. If the horizontal airflow guide  74  is too wide, in the direction of the x-axis  118 , the set of comb teeth  76  will not be able to properly separate the hair during treatment. In the embodiment of the presently disclosed subject matter, there is a single horizontal airflow guide  74 , however additional horizontal airflow guides  74  can be used so long as the performance of the device  104  is not negatively impacted, and treatment can be performed to the extent required to eradicate the lice and lice eggs. 
     As shown in  FIG. 2 , the horizontal airflow guide  74 , is slightly concave to match the natural curvature of the human scalp  106 . The purpose of the concaved horizontal airflow guide  74  is so that heated air exiting the comb head  110  is projected laterally and parallel to the scalp  106 . 
     As shown in  FIG. 5B  the front, top edge of the horizontal airflow guide  74  projects slightly upward in the vertical direction forming a ridge  144  along the front edge as shown. The bottom front edge of the horizontal airflow guide  74  is beveled as shown in  FIGS. 6 and 7 . The purpose of the ridge  144  is to abrupt the airflow steam  136 , and cause the airflow to separate. While most of the air exiting the comb head  110  will continue laterally, along the x-axis  118 , the air that exits over the ridge  144  of the horizontal airflow guide  74  will separate and deflect some of the air slightly upward and some of the air downward. The airflow stream  136  being defected in the upward direction, will create a slight curvature in the airflow stream  136 . The air that is not deflected upward will pass over the ridge  144  and drop creating a small vortex  142 , or back flow, at the front of the horizontal airflow guide  74 , as shown in  FIG. 17 . A vortex is naturally created when laminar airflow is abrupted when it passes over a projection protruding into the airflow. The size of the vortex is dependent on the velocity of the airflow, the size and shape of the projection and pressure difference. The small vortex  142  that is created after the air passes over the ridge  144  of the horizontal airflow guide  74  helps to further induce curvature of the airflow that is deflected in the upward. Curvature of the airflow stream  136  better matches the curvature of the scalp allowing the heated air to be directed more accurately to the targeted infested area of the hair shafts. 
     Following is a detailed description of the vertical airflow guides  80   a - 80   d  in the exemplary embodiment of the presently disclosed subject matter.  FIGS. 2, 6-8, 14, 16 and 17  demonstrate the vertical airflow guides  80   a - 80   d . The vertical airflow guides  80   a - 80   d  are an extension of the combing teeth  76   b - 76   e  as shown in the perspective back sectional view of the ectoparasite eradiating device in  FIG. 14 . The purpose of the vertical airflow guides  80   a - 80   f  is to induce laminar flow as the heated air exits the comb head  110  as shown in  FIG. 16 . The thickness of the vertical airflow guides  80   a - 80   d  is of the same thickness of the combing teeth  76   a - 76   f  and extend through the square to round transition  72  to be flush with the back side of the square to round transition  72  as shown in  FIGS. 6, 7, 14, 16 and 17 . The back face of the vertical airflow guides  80   a - 80   d  are chamfered to maintain laminar airflow and not create an abruption in the airflow as that would create turbulent airflow which is more difficult to direct to a targeted area. The back side of the vertical airflow guides  80   a - 80   d  are not limited to a chamfer. They can be of any shape so long as the performance of the device  104  is not negatively impacted, and treatment can be performed to the extent required to eradicate the lice and lice eggs. 
     As shown in  FIGS. 8 and 16 , combing tooth  76   a  and vertical airflow guide  80   d  are a unitary element; combing tooth  76   c  and vertical airflow guide  80   c  are a unitary element; combing tooth  76   d  and vertical airflow guide  80   b  are a unitary element; and combing tooth  76   e  and vertical airflow guide  80   a  are a unitary element. The top and bottom shape of the vertical airflow guides  80   a - 80   d  is defined by the shape of the square to round transition as the vertical airflow guides extend from the bottom interior surface to the top interior surface of the square to round transition. In one example of an embodiment if the square to round transition changed in shape to be a round transition, because the comb head was cylindrical, the top and bottom shape of the vertical airflow guides would be of a shape that matches the new shape of the transition. The vertical airflow guides are not limited to the quantity of combing teeth. Additional airflow guides can be added or removed so long as the performance of the device  104  is not negatively impacted, and treatment can be performed to the extent required to eradicate the lice and lice eggs. 
     Following is a detailed description of the square to round transition  72  in the exemplary embodiment of the presently disclosed subject matter.  FIGS. 2, 5-8, 14, 16 and 17  shall be referenced as the square to round transition  72  is described. The purpose of the square to round transition  72  is to transition from the cylindrical shaped airflow chamber  108  to the rectangular, back face of the set of combing teeth  76  comprising the comb head cap  78  and the horizontal airflow guide  74 . As shown in  FIG. 6 , the bottom, front face of the square to round transition  72  aligns with the back face of the horizontal airflow guide  74 . The top front face of the square to round transition  72  aligns with the back face of the comb head cap  78 , also shown in  FIG. 6 . The front faces of the left and right sides of the square to round transition  72  align with the two outer, left and right combing teeth,  76   a  and  76   f  as shown in  FIG. 5A . 
     As shown in  FIG. 6 , the square to round transition  72  slopes upward, increasing the distance between the bottom face of the square to round and the human scalp  106 . Because the square to round transition slopes upward, the top face of the square to round transition is above the top of the set of coming teeth  76 . The purpose of sloping the transition in the upward direction is so that the airflow chamber  108  and connected blow dryer  102  can swivel freely about the comb head  110  as the device  104  is guided around the head during the treatment process. If the square to round transition  72  extends laterally or downward, full contact between the human scalp  106  and the bottom of the set of comb teeth  76  could be hindered as the device would have to be tilted to swivel the airflow chamber  108  and connected blow dryer  102  without the handle of the blow dryer  102  coming into contact with the actor. If the device  104  is tipped toward the human scalp  106  to swivel the blow dryer  102 , during the treatment process, the actor could sustain burns or other injuries to the scalp  106 . Increasing the overall width of the square to round transition  72  (increasing the size in the direction of the x-axis), will increase the distance between the handle of the blow dryer  102  and the actor as airflow chamber  108  and the blow dryer  102  swivel about the comb head  110  during the treatment process. If the width of the square to round transition is to long, the actor will have a difficult time performing the treatment process alone. The width of the square to round transition  72  should be of a length that does not negatively impact the performance of the device  104  allowing the treatment to be performed to the extent required to eradicate the lice and lice eggs. The overall size and shape of the square to round transition  72  should be of a shape and size that provides a smooth transition between the airflow chamber  108  and comb head  110  to maintain laminar flow as the air exits the device  104 . 
     In one embodiment of the parasite eradicating device  104 , the combing teeth  76   a - 76   f  comprising of the airflow guide  74  and the comb head cap  78  could be of a cylindrical shape similar in size to the cylindrical airflow chamber  108  making a transition of any sort unnecessary between the comb head  110  and the airflow chamber  108 . A transition is only necessary if the two parts being interfaced are of different sizes or shapes. 
     Following is a detailed description of the female interface ring  70  and the male interface ring  82  in the exemplary embodiment of the presently disclosed subject matter.  FIGS. 2, 6-9, 12-15  shall be referenced as the female interface ring  70  is described. The female interface ring  70  is an element of the unitized comb head  110 . The male interface ring  82  is an element of the unitized airflow chamber  108 . The female interface ring  70  interfaces with the male interface ring  82  of the airflow chamber. The interface of the two elements is not a fixed interface, but a swiveling connection as shown by the arrows  98  and  100  in  FIG. 15 . The arrows  98  and  100  represent that there is rotation in either direction at the connection point between the comb head  110  and the airflow chamber  108 . More specifically, comb head  110  can swivel freely about the airflow chamber  108 , about the x-axis  118 , which is represented by arrow  98 . The airflow chamber  108  can swivel freely about the comb head  110 , about the x-axis  118 , which is represented by arrow  100 . 
       FIG. 12  is a right side elevation view of the ectoparasite eradicating device  104 . 
       FIG. 13  shows a blown up, partial elevational section view of the connection point between the female interface ring  70  and the male interface ring  82 . The female interface ring  70  is shown to have a small flange that protrudes inward, toward the center of the ring. The male interface ring  82  is shown to have a small flange that protrudes outward, away from the center of the ring. When the two rings are combined, this is the mechanism that holds the comb head  110  and the airflow chamber  108  together as shown in  FIG. 13 . The flanges on both the female interface ring  70  and the male interface ring  82  are sized so that when combined, a uniform gap  84  is created between the interfacing elements of the flanges. The uniform gap  84  that is created shall be large enough to allow the comb head  110  and the airflow chamber  108  to swivel about each other freely, yet small enough to keep the two parts from coming apart as shown in  FIG. 13 . When combined, the outside diameters of the female interface ring  70  and the male interface ring  82  should be of similar size to allow for a smooth transition between the swiveling parts. The front face of the female interface ring  70  aligns flush against the back side (cylindrical side) of the square to round transition  72  as shown in  FIGS. 5-7, 12, 12-17 . The two mating faces of the female interface ring  70  and the square to round transition  72  have the same wall thickness for a smooth transition between the two elements as shown in  FIG. 13 . The back face of the male interface ring  82  aligns flush against the front face of the elbow  90  of the airflow chamber  108  as shown in  FIGS. 2, 9 and 12-14 . The two mating faces of the male interface ring  82  and the airflow chamber elbow  90  have the same wall thickness for a smooth transition between the two elements as shown in  FIG. 13 . 
     As described above, the interface of the two elements is not a fixed interface, but a swiveling connection as shown by the arrows  98  and  100  in  FIG. 15 . The flanges of the mating rings can be of various shapes and sizes to allow for a smoother transition between the elements. The outer diameters of the female interface ring  70  and the male interface ring  82  do not have to be of the same diameter or shape. The outer surface can have grooves or bumps. The internal surface of the interfacing rings  70  and  80  when combined should not create a surface where the performance of the device  104  is not negatively impacted, and treatment can be performed to the extent required to eradicate the lice and lice eggs. 
     Between the universal collar  94  and the male interface ring  70  is the airflow chamber elbow  90  as shown in  FIGS. 2, 9, 10 . The airflow chamber elbow is of a radius that allows the blow dryer  102 , when affixed to the device  104 , to rotate about the comb head  110  to a variety of positions that improve contact between the set of combing teeth  76  and the scalp  106 . The elbow  90  is of a diameter that allows the back face of the elbow to be flush to the front face of the universal collar  94  and the front face of the elbow to mate flush against the male interface ring  82 . The wall thickness is of a thickness that is of the same thickness as the surrounding elements. 
     As shown in  FIGS. 10 and 14 , the wall thickness of the male interface ring  82  and the wall thickness of the tapered end of the universal collar  94  are of different thicknesses. In  FIG. 14  it can be seen that the thickness of the elbow  90  wall gradually changes in size to meet the wall thickness of the surrounding elements to allow for smooth internal surface of the device  104 . The radius of the elbow  90  can be of any radius as long as the performance of the device  104  is not negatively impacted, and treatment can be performed to the extent required to eradicate the lice and lice eggs. 
     Following is a detailed description of the airflow chamber  108  in the exemplary embodiment of the presently disclosed subject matter.  FIGS. 9-11, 14 and 19-21  shows how the elements of the airflow chamber  108  interface to form a unitary part. As shown in  FIGS. 11 and 19  The airflow chamber comprises a tapered universal collar  94 , which is what affixes to the blow dryer  102 . The tapered shape of the universal collar  94  matches the general shape of most blow dryer  102  nozzles allowing for a secure fit. 
     As shown in  FIGS. 19 and 20  shaping the universal collar  94  to match the general shape of a blow dryer  102  nozzle allows for full contact between the outer surface of the nozzle and the inner surface of the universal collar  88 . The overall length of the universal collar  94  is of a length that allows the blow dryer  102  nozzle to be inserted into the universal collar  94  to a depth necessary to maintain a secure connection with the blow dryer  102  during the treatment process. The method chosen to affix the universal collar  94  to the blow dryer  102  nozzle will determine the internal diameter of the universal collar  94  at the insertion point. 
     In the embodiment of the presently disclosed subject matter the chosen method to affix the universal collar  94  to the blow dryer  102  nozzle is a friction connection using a silicon ribbed sleeve  96  inserted or molded to the interior surface of the universal collar  92  as shown in  FIGS. 20 and 21 . 
     Also, as shown in  FIG. 20 , the ribbed sleeve  96  does not extend the entire length of the universal collar  92 . The formula of the silicon used to create the ribbed sleeve is not within the scope of the invention. However, the methods, shape and size of the ribbed sleeve  96  are within the scope of the invention. The silicon used to create the ribbed sleeve  96  is of a formula that will not cause the ribbed sleeve tear, deform, disintegrate under high temperatures and multiple uses over long periods of time. The shape, size length and material of the ribbed sleeve  96  is not limited to silicon. For example, in lieu of using a ribbed sleeve to hold the blow dryer  102  nozzle in place, a sleeve with a series of bumps could be used. The sleeve could extend the entire length of the universal collar, or a series of sleeves could be used. The scope of the material used to create the ribbed sleeve  96  extends to any substance that is flexible and elastic in nature. 
     Following is a detailed description of a method of lice and nit eradication using the ectoparasite eradication device  104  in the exemplary embodiment of the presently disclosed subject matter as shown in  FIGS. 22-27 . 
       FIG. 25  shows the three stages of head lice, the egg (also referred to as nits)  150 , the nymph  146 , and the adult  148 . Also shown is how the size of the lice at the various stages in life relates to a United States one cent coin  154 . Head lice of the nymph  146  and Adult  148  stages feed on the blood of a host and typically live close to the human scalp  106 , but they lay their eggs  150  on strands of hair  152  near the base of the hair shaft  156  as shown in  FIG. 26 . Lice and nits are most commonly found behind the ears and around the neckline of a human head  114  as shown in  FIG. 26 . 
     An exemplary method of treatment to eradicate the lice and nits is shown  FIGS. 18, 19 and 22-27  of the presently disclosed subject matter. As shown in  FIGS. 18 and 19 , the ectoparasite eradicating device  104  shall be affixed to the blow dryer  102 . Once the device  104  has been affixed to the blow dryer  102  and adjusted to the proper heat setting, the blow dryer can be turned on and the process for treatment can begin. The first step in the exemplary method of treatment disclosed is to comb through the hair of the actor to remove tangles, lift the hair and remove loose lice and nits  158 . Once the hair has been combed though and the actor is ready for the next step, the starting position of where to begin the path for lice treatment needs to be identified  162 . The starting position should begin at the back hairline, behind the left ear  160  or right ear  163 . Once the location of the starting point has been identified, the bottom side of the set of combing teeth  76  shall be placed on the neck just prior to the hairline so that the set of combing teeth  76  are pointing toward the front of the scalp. Ensure that all combing teeth  76   a - 76   f  are making contact with the scalp and the airflow guide  74  is parallel to the scalp  106 . Once the comb head  110  is placed properly, the device  104  can be guided slowly in a path around the ear, toward the hairline at the front of the scalp  166 . 
       FIGS. 22-24  provide a visual representation of an exemplary path of treatment and may be referenced the method of treatment is being described to add clarity to the method of treatment.  FIG. 22  depicts the starting point for the path of treatment to be behind the actors left ear.  FIG. 23  depicts a representation of the comb head being guided towards the hairline at the front of the scalp  106 .  FIG. 24  depicts the end point for the initial path of treatment as the comb head has reached the hairline at the front of the scalp  106 . Also depicted in  FIGS. 22-24  is a representation of the swiveling of the ectoparasite eradicating device  104  during treatment. As the blow dryer  102  is being rotated, for comfort of the user and to avoid contact with the actor by the handle or electrical cord of the blow dryer, the set of combing teeth  76  are able to maintain contact with the scalp  106  while the comb head  110  is being guided to the front hair line of the scalp  106 . To improve the effectiveness of the process, as the device  104  is being guided the section of hair being treated shall be lifted to better expose the lice and nits to the heated air coming being coming out of the comb head  110 . Once the comb head  110  as passed through the section of hair being held, the hair can be let down allowing it to pass under the comb head  110 . As the treated hair is passing under the comb head  110 , the next section of hair in front of the comb head shall be lifted. This method shall be continued until the comb head  110  has reached the hairline at the front of the scalp. Once the comb head  110  has reached the front of the scalp, the comb head shall be repositioned at the back of the scalp similarly to position of the comb head  110  for the first path of treatment, except the comb head  110  shall be moved ½ the width of the comb head  110  in the direction of the untreated hair  168 . Once the comb head  110  is repositioned properly, the comb head  110  can be slowly guided toward the hairline at the front of the scalp  170 ; following the same procedures completed for the first path of treatment described above. These steps shall be repeated until the front hairline, above the ear on the opposite side of the head has been reached  172 . Once the comb head  110  has passed through all the hair on the scalp and reached the end point, the hair shall be combed though to remove dead lice and nits  174 . If live lice are found, the treatment process should be repeated as described above until the lice and nits have been eradicated. If no live lice have been identified, the lice treatment is complete  177 . The lice treatment process shall be repeated as described above in 24 hours to ensure total eradication. 
     The method of treatment is not limited to the process shown in  FIGS. 22-24 and 27 . It may be necessary for the actor to bathe and wash their hair prior to starting the exemplary method shown herein to remove tangles, clean the hair and scalp, remove loose lice and nits or lift the hair to make it easier for the comb head  110  of the ectoparasite eradicating device  104  to be guided though the hair. It should be known that if the hair and scalp  106  do get wet prior to treatment that the hair and scalp  106  must be completely dried first. Also, depending on the actor being treated, some steps may need to be skipped, added, modified, or completed in reverse. It may be desirable to start the treatment path at a different location on the head. Although, less effective, treatment could begin in the middle of the scalp, at the top of the head. The path of treatment could begin at the hairline at the front of the scalp directing the comb head  110  toward the back of the head. The path of treatment could also be completed perpendicular to the exemplary path described in the present disclosure. It may be necessary to tip the actors head upside down if sections of hair can not be lifted to better expose the lice and eggs to the heated air. 
     The method of treatment described in  FIGS. 22-24 and 27  is not limited to being completed with the help of an additional person to guide the comb head  110  through the hair. Due to the shape and swiveling configuration of the ectoparasite eradicating device  104 , the method of treatment can be completed solo, by the actor. 
     While particular embodiments of the invention have been illustrated and described, various modifications and combinations can be made without departing from the spirit and scope of the invention. All such modifications, combinations, and equivalents are intended to be covered and claimed.