RU2790022C1 - Composition for insect repellent - Google Patents

Abstract

FIELD: insects repelling compositions.

SUBSTANCE: inventions group relates to a composition for repelling insects and a method for repelling insects. Composition for repelling insects, containing, in mass percent: 10-20% 2,6-dimethyl-7-octen-2-ol; 0.1-5% 2,6-octadienal, 3,7-dimethyl; 1-10% benzyl benzoate; 0.01-2% citral; 1-10% hexamethylindanopyran; 10-40% lavender oil; 20-50% Argentine lemon oil; 5-15% Mexican distilled lime oil; 0.01-3% limonene and 5-15% rosemary oil. A method for repelling insects, including the use of the composition described above.

EFFECT: above composition is effective for repelling insects.

22 cl, 2 tbl, 1 ex

Description

FIELD OF THE INVENTION

[0001] The present invention relates to an insect repellent composition, and in particular to a composition comprising various components in a formulation having insect repellent properties.

PRIOR ART

[0002] Insects perform valuable functions, including, but not limited to, pollinating plants, providing food, and performing other beneficial functions. However, some insects have undesirable effects, which include, but are not limited to, carrying and carrying diseases, as well as nuisances such as biting insects. For example, ticks and mosquitoes carry diseases that affect animals and humans.

[0003] Mosquitoes are the cause of the majority of human diseases, with an average of 500 million cases resulting in three million deaths each year. Ninety percent of these cases occur in Africa alone, and 2.5 billion people worldwide are at risk. Women are particularly at risk due to increased attraction to predatory mosquitoes due to the increased alkalinity of their skin.

[0004] In addition, mosquito-borne diseases are one of the most deadly threats to the population. Strategies should be developed to prevent mosquito-borne diseases, as the risk of these diseases will gradually increase as mosquitoes' natural habitats expand due to global warming. Currently, there are about 10 million species of insects in the world. It has been found that 10,000 of them actively feed on blood, and the number of those that feed on the blood of humans is about 100. Insects that attack humans must have developed many sensitive chemoreceptor networks that work in a certain coordination to find prey.

[0005] Currently, the best existing mosquito defense strategies for humans are N,N-diethylmetatoluamide (DETA), ethyl butylacetylaminopropionate (trade name IR3535), and picaridin. While these chemicals are effective, they do not have the major limitations that the present invention seeks to address. DEET, ethylbutylacetylaminopropionate, and picaridin are effective in that they stimulate a key receptor in the mosquito's chemosensory array, causing a deterrent response. This primary receptor is called the Or47a and Or83b DETA-like receptor. Influencing this receptor with DETA, ethylbutylacetylaminopropionate, or picaridin appears to be its own limitation, in which it acts only on this receptor. This strategy only serves to create a single method of repelling mosquitoes or predatory insects. The mosquito can still use other chemosensory receptors to locate prey, rendering the DEET receptor ineffective.

[0006] It is generally recognized that the use of plant extracts for mosquito repellent has limitations due to the toxic effects of some of the chemicals they contain in certain amounts. The toxic effects of most mosquito repellent fragrances or oils are of limited effectiveness due to the presence of other toxic chemicals in them. The following is a list of examples of popular mosquito repellent flavors/oils and their toxic effects; anise (Pimpinella anisum) is carcinogenic due to methyl eugenol, basil (Ocimum sp) is carcinogenic due to methyl eugenol, bergamot (Citrus bergamia) is a phototoxic skin irritant due to d-limonene, cajeput (Melaleuca alternifolia) is a phototoxic skin irritant due to -for methyleugenol, citronella (Cymbopogon nardus) is a skin irritant due to methyleugenol and citral, citrus oil (Citrus sp) is a phototoxic skin irritant due to bergapten and d-limonene, clove (Syzygium aromaticum) is a skin irritant due to methyleugenol , lemon bush (Lippia javanica) is a skin irritant due to citral, geranium (Pelargonium graveoiens) is a skin irritant due to citral, ginger (Zinziber sp) is a skin irritant due to citral, Macquarie pine (Langarostrobus franklini) is a skin irritant due to methyl eugenol, lemongrass (Cympogon cintratus) is a skin irritant due to citral, lime (Citrus aurantifolia) is lyceum (Litsea cubebia) is a skin irritant due to citral, marigold (Tagates minuta) is phototoxic, mugwort (Chenopodium ambrosiodes) is hepatotoxic, mint (Mentha piperata) is a skin irritant due to d-limonene, for trans-2-hexanol, nutmeg (Myristica fragrans) is a skin irritant due to methyleugenol, palmarosa (Cymbopogon martini) is carcinogenic due to methylfarnesol, pennyroyal (Mentyl pulegium) is toxic, pine (Pinus sylvestris) is phototoxic, rosemary (Rosemarinus officinalis) is a skin irritant due to methyl eugenol, rue (Ruta chalepensis) is phototoxic due to psoralen, thyme (Thymus vulgaris) is a skin irritant due to trans-2-hexanol, viola (viola odorata) is a skin irritant due to trans-2-hexanol.

[0007] Aromatic oils such as citronella, rosemary, and eucalyptus have been used to repel insects for thousands of years. These aromatic oils are made up of VOCs (Volatile Organic Compounds) produced by flowers and fruits. These oils are collected as extracts from their respective sources and technically described as an accord. An accord is a collection of chemicals grouped together to create a specific scent. These chords can be replicated by perfumers to create specific fragrances and are composed of a top note, a middle note, and a base note. The volatility of these components is highest in the top note, somewhat variable in the middle note, and least variable in the base note.

[0008] In the case of citronella, the oil found in many botanical sources and known for its repellant activity has been found to consist of several blends of oils. It has been found that the accord that makes up the fragrance consists of sub-oils that have repellant factors and other sub-oils that are not repellent.

[0009] For example, citronella contains 18-20% geraniol, 9-11% limonene, 7-11% methylisoeugenol, 6-8% citronellol, and 5-15% citronellal. It is interesting to note that only the oils of geraniol, limonene and citronella have repellant properties, while the rest of the oils in the accord are for other purposes such as protection or attraction.

[0010] The same applies to eucalyptus oil, which consists of 60-80% cineole oil, and the remaining 40-20% are trace elements. The remaining trace oils are alpha-pinene 9%, beta-pinene 1.5%, alpha-phellandrene 1.5%, delta-limonene 12%, 1,8-cineol 70%, camphor 0.1%, and sabinene 0. 3%.

[0011] Studies have shown that the aromatic accords in most oils that repel insects (e.g., mosquitoes) are only partially responsible for repelling insects, with the remainder of the aromatic oils being used as insect attractants for pollination or acting to signal the characteristics of the condition, such as protective pheromones, nearby plants or similar objects.

[0012] For example, the fragrant aroma of a common tomato is a great example. The cell structures of the leaves are composed of glandular trichomes, which contain crystals and oils in their bulbous compartments. These structures contain oils that are responsible for several biological functions, including plant protection. The chemical constituents of the tomato leaf are tomatine, (Z)-3-hexenal, (E)-2-hexenal, eugenol, 1,8-cineol, caryophyllene, b-phellandrene, humulene, linalool. Each chemical in tomato has either a specific function or a synergistic function. In the case of tomato flavor, studies have shown that tomatine is a protective anti-membrane chemical that is used to prevent biofilm formation of attacking snails, bacteria or fungi, (Z)-hexenal is involved in wound healing as it has antimicrobial ability by inhibiting JA signaling from invading bacteria and fungi. (E)-2-hexenal, although similar to (Z)-3-hexenal, acts as an attractant for beneficial predatory insects. The chemical b-phellandrene is a chemical attractant known to attract parasitic predatory mites to the site of injury. Thus, the chemicals eugenol, 1,8-cineole, caryophyllene, humulene, and linalool remain the only chemicals in the tomato flavor accord responsible for repelling insects.

[0013] Another key disadvantage of using natural botanical plant extracts with known mosquito repelling properties is that some of the chemical components that make up the accord are actually chemical attractants for mosquitoes. This is clearly seen in the chemical accord of the well-known mosquito repellent extract, cedar oil, containing cedrol, isolongifolene and dehydroneolingifolene. It is well known that the replication cycle of mosquito-borne diseases is one of the most serious biological threats to humanity. All viruses that infect humans have a unique but similar cycle. A good example is the malaria contagion cycle. The cycle begins with a malaria-infected mosquito biting and infecting a human host. The malaria parasite then grows and waits in the human host until the next mosquito bites the host. The parasite then travels from the host to the mosquito, where it also becomes infected. The cycle repeats itself when the malaria parasite moves between two hosts, a human and a mosquito. It is important to consider that the malaria parasite has evolved to emit a chemical signal that "tells" the mosquito that it should come and pick up the parasite. As it nears maturity inside the human host, the parasite begins to secrete chemical signatures that attract mosquitoes to the infected human host.

SUMMARY OF THE INVENTION

[0014] The present invention relates to various compositions, which are compositions comprising several components. These components together, and also in combination with existing conventional, existing repellents such as (DETA), picaridin, ethyl butylacetylaminopropionate (trade name IR3535) and other known mosquito repellents, provide compositions that have an enhanced synergistic effect in terms of in terms of insect repellent properties compared to these components alone. Existing mosquito repellents only affect the taste buds of insects. The present composition utilizes a multi-receptor approach by targeting insect ionotropic, gustatory and olfactory receptors to provide a synergistic effect to repel insects as well as to inhibit the insect's ability to detect and seek prey.

[0015] Some components are found in botanical plants. In addition, some of the components or constituents are aromatic substances produced by plants, and such plants may contain a variety of other chemicals with properties that may or may not have insect repellent properties. These include chemosensory signals for protection, attraction, healing, and so on. An improved mosquito repellant can be enhanced by formulating repellents that include only active repellent chemicals from a wide range of mosquito repellent fragrances. Such a formulation would be superior as it would contain key chemical chemosensory inhibitors to inhibit the Or47a and Or83b DETA receptor, the AgOr65 protein receptor, the cpA carbon dioxide receptor, and the human specific AeegOr4 or AaegOr103 sulcatone receptor. The composition can be obtained by critical analysis and extrapolation of these chemoreceptor-specific compounds, all plant flavors known to have mosquito or insect repellent properties.

[0016] In addition to excellent repellent properties, the compositions of the present composition are safe for humans and animals.

[0017] Some of the compositions of the present invention are directed to a more useful strategy: a complex composition that can inhibit the entire chemosensory package of mosquitoes. It may include the AgOr65 protein receptor, the cpA carbon dioxide receptor, and the AaegOr4 or Aaeg103 receptor, which is sensitive to sulcatone, which is exclusively secreted by human hosts.

[0018] The present invention, in one form, relates to the following composition, in weight percent:

10-20% 2,6-dimethyl-7-octen-2-ol;

0.1-5% 2,6-octadienal, 3,7-dimethyl-;

1-10% benzyl benzoate;

0.01-2% citral;

1-10% hexamethylindanopyran;

10-40% lavender oil;

20-50% Argentine lemon oil;

5-15% Mexican distilled lime oil;

0.01-3% limonene and

5-15% rosemary oil.

Optionally, the composition may contain 0.1-10% alcohol such as ethanol, isopropanol and methanol.

[0019] The present invention, in another form, relates to the following composition, in mass percent:

10-20% 2,6-dimethyl-7-octen-2-ol;

0.1-5% 2,6-octadienal, 3,7-dimethyl-;

1-10% benzyl benzoate;

0.01-2% citral;

1-10% hexamethylindanopyran;

10-40% lavender oil;

20-50% Argentine lemon oil;

5-15% Mexican distilled lime oil;

0.01-3% limonene;

5-15% rosemary oil; And

0.1-10% insect repellant active ingredient selected from the group consisting of N,N-diethylmetatoluamide (DETA),

ethylbutylacetylaminopropionate and picaridin.

Optionally, the composition may contain 0.1-10% alcohol such as ethanol, isopropanol and methanol.

[0020] The present invention, in another form, relates to the following composition by weight percent:

12-18% 2,6-dimethyl-7-octen-2-ol;

0.1-1% 2,6-octadienal, 3,7-dimethyl-;

2-5% - benzyl benzoate;

0.01-1% citral;

2-5% - hexamethylindanopyran;

25-30% lavender oil;

30-40% Argentine lemon oil;

5-10% Mexican distilled lime oil;

0.01-0.1% limonene;

5-10% rosemary oil, and

optionally, 0.1-10% of an insect repellant active ingredient selected from the group consisting of N,N-diethylmetatoluamide (DETA), ethyl butylacetylaminopropionate and picaridin.

Optionally, the composition may contain 0.1-10% alcohol such as ethanol, isopropanol and methanol.

[0021] The present invention, in another form, relates to a method of repelling insects using the following composition, in mass percent:

10-20% 2,6-dimethyl-7-octen-2-ol;

0.1-5% 2,6-octadienal, 3,7-dimethyl-;

1-10% benzyl benzoate;

0.01-2% citral;

1-10% hexamethylindanopyran;

10-40% lavender oil;

20-50% Argentine lemon oil;

5-15% Mexican distilled lime oil;

0.01-3% limonene;

5-15% rosemary oil, and

optionally, 0.1-10% of an insect repellant active ingredient selected from the group consisting of N,N-diethylmetatoluamide (DETA), ethyl butylacetylaminopropionate and picaridin.

Optionally, the composition may contain 0.1-10% alcohol such as ethanol, isopropanol and methanol.

[0022] In yet another form thereof, a method of repelling insects includes the use of the following composition containing, in mass percent:

12-18% 2,6-dimethyl-7-octen-2-ol;

0.1-1% 2,6-octadienal, 3,7-dimethyl-;

2-5% - benzyl benzoate;

0.01-1% citral;

2-5% - hexamethylindanopyran;

25-30% lavender oil;

30-40% Argentine lemon oil;

5-10% Mexican distilled lime oil;

0.01-0.1% limonene;

5-10% rosemary oil, and

optionally, 0.1-10% of an insect repellant active ingredient selected from the group consisting of N,N-diethylmetatoluamide (DETA), ethyl butylacetylaminopropionate and picaridin.

Optionally, the composition may contain 0.1-10% alcohol such as ethanol, isopropanol and methanol.

[0023] The composition can be formulated as a solid, liquid such as an oil or lotion, etc. The composition can be applied by topical application of the composition to an individual (human or animal), by spraying the composition onto an individual or in an environment in which insects are to be repelled, by burning the composition, and so on.

[0024] The advantages of the present composition and method include, but are not limited to, a more effective insect repellent, including mosquitoes, than conventional compositions.

DETAILED DESCRIPTION OF THE INVENTION

[0025] The composition of the present invention acts as an insect repellant, including mosquitoes. The mechanism of action of the present invention varies depending on the specific components of the composition. The composition includes components such as aromatic substances that act on the olfactory sensory neurons of the insect. Other components in the present composition act on other senses of the insect.

[0026] In one preferred embodiment, the present composition provides an excellent insect repellant that focuses on repellant factors while avoiding the limitations of toxicity to humans, animals, or other living beings, including plants that are required to repel insects.

[0027] Speaking specifically about how the various formulations of the present composition affect insects, and in particular mosquitoes, each mosquito olfactory sensory neuron expresses one flavor receptor that recognizes specific structural features or epitopes in flavor molecules. Axons of neurons expressing the same receptor converge in one glomerulus. Therefore, a particular aromatic substance may have structural features recognized by the olfactory receptors Or83b, Or47a, Or4, Or103, and cpA, which activate the corresponding glomeruli. Another aromatic substance may have different epitopes and may activate alternative receptors. Aromatic substances of the third type can have completely different epitopes and simultaneously activate several receptors. Therefore, a scent receptor and its corresponding glomerulus can be activated by several different scents, but each scent likely elicits a unique pattern of glomerular activation. This model is a scent-specific neural model that the mosquito uses to find prey.

[0028] One aspect of the present composition focuses on specific components or constituents that inhibit these olfactory receptors, either specifically or universally, to effectively blind an insect (eg, mosquito) to a human prey. This strategy allows the selection of certain components and appropriate concentrations to be included in the compositions of the present composition, sufficient to provide an insect repellent with synergistic, superior insect repellent properties compared to the properties of DEET, IR3535 or picaridin alone, which act only on individual receptors.

[0029] In accordance with another aspect of the present composition, the composition may be formulated to make the individual to whom the composition is applied "shielded" against insects, such as, but not limited to, mosquitoes or other biting insects, by inhibition of protein receptors that detect human or animal body odor. These specialized receptors detect specific body odor proteins emitted by a person. These odors are sulcatone and lactic acid. Mosquito antennae have specialized receptors (AaegOr4, AaegOr65, and AaegOr103) that detect human body odors, sulcatone, and lactic acid, which are specific for detecting human prey. All of these receptors require the function of P450 isoenzymes in order for the receptors to detect these human-specific aromatics. It would be a unique strategy to include key chemicals in a repellant that sufficiently inhibits the function of the AaegOr4, AaegOr65 and AaegOr103 receptors. Successful deactivation of these key receptors through inhibition of the P450 isoenzyme will blind the mosquito to the presence of a human host. Accordingly, some formulations of the present composition include components designed to blind mosquito sulcatone and lactic acid receptors by inactivating native receptor P450 isoenzymes.

EXAMPLES

[0030] The following are examples of formulations and uses of the present composition.

[0031] Example 1

[0032] Formulation 1 - Formulation 1 composition contains the following components in mass percent:

1. 2,6-dimethyl-7-octen-2-ol 14.20% 2. 2,6-octadienal, 3,7-dimethyl 0.44% 3. ethanol 0.15% 4. benzyl benzoate 3.55% 5. citral 0.06% 6. hexamethylindanopyran 3.55% 7. lavender oil 28.80% 8. Argentine lemon oil 35.00% 9. Mexican distilled lime oil 7.10% 10. limonene 0.06% 11. rosemary oil 7.10%

EXPERIMENTS

[0033] Table 1 (below) demonstrates the repellency of Formulation 1 in inhibiting both landing and probing (feeding behavior) of mosquitoes.

[0034] For testing liquid test substances, collagen membranes were used as a skin analog. The collagen membranes were moistened with water and the surface dried before application to provide a texture and consistency that is similar to human skin. The application was carried out with collagen membranes by shaking the test substances well, then applying the test substance to the membranes until wet, and then gently rubbing the test substance into the membranes.

[0035] The membranes were placed on top of water-moistened paper towels (slightly moistened) to maintain a leather-like consistency by preventing complete loss of moisture from the membranes upon aging. The membranes were placed on paper towels with the raw side in contact with the paper towels and water was added to the paper towels as needed to maintain moisture during the aging process. Each test substance was evaluated 1 and 2 hours after application. Each evaluation consisted of two (2) repetitions for each period.

[0036] Twenty-five (25) female mosquitoes were released into a 1×1 inch cage and kept without food for at least 2 hours prior to testing. The cage had a 1" x 1" wooden lid at the top of the cage and an approximately 2.5" x 6" removable section in the center. The section was removable to provide an opening at the top of the cage to accommodate the test surface and to allow mosquitoes to attempt to feed on the subject's arm above the test surface. A mesh was placed on the top side of the test surface to prevent direct contact of the test surface with the test subject's hand, and disposable wooden spacers were placed over the top cover to raise the test surface's hand above the test substance and prevent mosquitoes from feeding on the test subject.

[0037] A pre-treatment evaluation of the untreated surface was performed prior to testing the treated test surface by counting the number of mosquitoes that landed and probed the untreated test surface over a 5-minute time period. The treated surface was evaluated in the same manner as the untreated surface, and repellency was calculated by comparing the number of landings and probings during the evaluation of the untreated surface with the number of landings and probings during the evaluation of the treated surface. The study was conducted using two different subjects for each test substance and period.

[0038]

[0039] Collagen membranes were used as a skin analog for testing liquid test substances. Collagen membranes were moistened with water and the surface dried before application to provide a texture and consistency that is similar to human skin. The application to the collagen membranes was carried out by thoroughly shaking the test substances, then the test substance was applied to the membranes in an amount of 1 g/600 cm ² , and then the test substance was gently rubbed into the membranes.

[0040] The membranes selected as untreated controls were moistened with water but not subjected to any other application. The membranes were placed on top of water-moistened paper towels (slightly dampened) to maintain a leather-like consistency by preventing complete loss of moisture from the membranes upon aging. The membranes were placed on paper towels with the raw side in contact with the paper towels and water was added to the paper towels as needed to maintain moisture during the aging process. The test substances were evaluated 6 and 8 hours after application. Each assessment consisted of 4 replicates for controls and 4 replicates for each test substance per period.

[0041] Twenty-five (25) female mosquitoes were released into a 1×1 inch cage and kept without food for at least 2 hours prior to testing. The cage had a 1" x 1" wooden lid at the top of the cage and an approximately 2.5" x 6" removable section in the center. The section was removable to provide an opening at the top of the cage to accommodate the test surface and to allow mosquitoes to attempt to feed on the subject's hand above the test surface. A mesh was placed on the top side of the test surface to prevent direct contact of the test surface with the test subject's hand, and disposable wooden spacers were placed over the top cover to raise the test surface's hand above the test substance and prevent mosquitoes from feeding on the test subject. The pre-treatment evaluation of the untreated surface was performed prior to testing the treated test surface by counting the number of mosquitoes that landed on and probed the untreated test surface during a 5 minute time period. The treated surface was evaluated in the same manner as the untreated surface, and repellency was calculated by comparing the number of landings and probings during the evaluation of the untreated surface with the number of landings and probings during the evaluation of the treated surface. The study was performed using two different test subjects for each test substance and period.

[0042] It will now be clear that the present composition, in its various formulations, provides characteristics and benefits not found in prior art insect repellents. The composition of the present invention can be formulated in such a way that it has strong repellent properties while maintaining safety for humans and animals.

[0043] In addition, this composition can be formulated to have excellent mosquito repellent properties based on its components, including fragrances, created by selecting active extracts that have an effect on numerous predatory insect repellent strategies, such as, but not limited to mosquitoes, lice, mites, fleas, flies, bed bugs and mites.

[0044] In addition, the present composition can be optimized by selecting specific components in desired amounts to achieve the desired insect repellent property based on repelling the desired insect and based on the selected desire to protect mammals, including humans and animals, from insects, including stinging insects.

[0045] The selection of desired components to include in the compositions of the present composition is based on the inhibition of key insect receptors, which include mosquito receptors, to repel mosquitoes. This can be achieved synergistically by inhibiting carbon dioxide receptors, body odor receptors, DETA-like receptors, or dopamine receptors. Progressive inhibition of synaptic firing potentials at these key receptors causes the insect to regard the human target as undesirable and induce an aversion to feeding.

[0046] In addition, the composition can be modified such that, when applied to humans, the human becomes “invisible” or unattractive to insects such as mosquitoes by specifically selecting specific isolates containing an aromatic associated with ultrastimulatory key receptors used by mosquitoes. or other insects to select prey.

[0047] In various forms of the composition of the present invention, the components work synergistically to act on known DETA receptors in an insect, such as a mosquito. For example, there are two specific DETA receptors Or83B and Or47a. The proposed formulation contains linalool, which is known to affect these specific receptors, respectively.

[0048] In addition, the composition of the present invention can be formulated to inhibit key chemical tell-tale signs that modulate the feeding behavior of mosquitoes. This will reduce or control the level of mosquito-borne malaria. The malaria parasite is known to cause infected people to secrete chemical attractants that attract mosquitoes (pinene and limonene). The aim of the invention is to use α-pinene or limonene or both as chemical "blinding agents" by over-stimulating mosquito sensory receptors that detect these chemicals. Overstimulation of these key receptors will induce avoidance behavior in predatory mosquitoes.

[0049] In addition, the composition can be formulated with specific chemical components that make the insect "blind" to the perception of carbon dioxide emissions by animal and human hosts. Receptors, in particular, include the “taste” receptors gr1, gr2, and gr3, which include the sensory cluster of cpA receptors. The compositions are expected to contain ethyl pyruvate, 7-beta-nepatalactone, methyl salicylate either alone or in combination as taste inhibitors.

[0050] The composition can also be formulated to contain certain chemical isolates that blind the AaegOr4, AaegOr65 and AaegOr103 insect receptors by deactivating or inhibiting the P450 isoenzymes contained in the receptor. Deactivation of protein-specific receptors will prevent the mosquito from detecting the presence of sulcatone and lactic acid odors produced by human targets. These putative isolates are myrcene, borneol and pinene, which actively deactivate mosquito specific protein sulcatone and lactic acid receptors by direct and passive inhibition of native neuronal P450 receptor isoenzymes.

[0051] Alternatively, the present composition can be formulated to prevent malaria infection by making topical formulations from plant extracts that are toxic to malarial sporozoites (P. falciparum). It is assumed that some chemical components of plant extracts are toxic to malarial sporozoites and plasmodium. In addition, it is expected that a direct reduction in malaria infection can be achieved, since the proboscis of the mosquito comes into contact with these plant extracts at the beginning of entry into the host.

[0052] In yet another alternative, the composition of the present invention may be formulated to contain chemicals that inhibit the development of learned behavior in mosquitoes to avoid the aversive properties of DEET. Mosquitoes have been shown to be able to learn behaviors that bypass DEET and reduce its effectiveness. This learned behavior has been reliably determined to be one of the key factors that reduce the effectiveness of DEET. The object of the invention is to include monoterpenes in the composition for repelling mosquitoes as a means of inhibiting the loss of effectiveness of DEET due to the development of tolerance. The composition will include limonene.

[0053] In addition, modification of the components in the composition of the present invention will have the effect of changing the characteristic odor of the resulting composition, which, as a result of routine experimentation and optimization, will cause the insect repellent to act as a repellant from the desired insect or for a particular application or use. .

Claims (63)

1. Composition for repelling insects, containing, in mass percent: 10-20% 2,6-dimethyl-7-octen-2-ol; 0.1-5% 2,6-octadienal, 3,7-dimethyl-; 1-10% benzyl benzoate; 0.01-2% citral; 1-10% hexamethylindanopyran; 10-40% lavender oil; 20-50% Argentine lemon oil; 5-15% Mexican distilled lime oil; 0.01-3% limonene; And 5-15% rosemary oil. 2. The composition of claim 1 further comprising 0.1-10% of an insect repellant active ingredient selected from the group consisting of N,N-diethylmetatoluamide (DETA), ethyl butylacetylaminopropionate and picaridin. 3. The composition according to claim 1, additionally containing 0.1-10 wt.% alcohol selected from the group consisting of isopropanol, ethanol and methanol. 4. Composition according to claim 1, containing: 12-18% 2,6-dimethyl-7-octen-2-ol; 0.1-1% 2,6-octadienal, 3,7-dimethyl-; 2-5% benzyl benzoate; 0.01-1% citral; 2-5% hexamethylindanopyran; 25-30% lavender oil; 30-40% Argentine lemon oil; 5-10% Mexican distilled lime oil; 0.01-0.1% limonene; And 5-10% rosemary oil. 5. The composition of claim 4 further comprising 1-10% of an insect repellant active ingredient selected from the group consisting of N,N-diethylmetatoluamide (DETA), ethyl butylacetylaminopropionate and picaridin. 6. The composition according to claim 4, additionally containing 0.1-1 wt.% alcohol selected from the group consisting of isopropanol, ethanol and methanol. 7. The composition according to claim 1, further comprising an inactive carrier, which in combination thereby forms a local localization. 8. The composition according to claim 1, where the composition is in the form of a solution for application in the form of a spray or aerosol. 9. A method for repelling insects, including the use of a composition containing, in mass percent: 10-20% 2,6-dimethyl-7-octen-2-ol; 0.1-5% 2,6-octadienal, 3,7-dimethyl-; 1-10% benzyl benzoate; 0.01-2% citral; 1-10% hexamethylindanopyran; 10-40% lavender oil; 20-50% Argentine lemon oil; 5-15% Mexican distilled lime oil; 0.01-3% limonene; And 5-15% rosemary oil. 10. The method of claim 9, wherein the composition further comprises 0.1-10% of an insect repellant active ingredient selected from the group consisting of N,N-diethylmetatoluamide (DETA), ethyl butylacetylaminopropionate, and picaridin. 11. The method of claim 9, wherein the use of the composition comprises applying the composition to an individual to thereby repel insects from the individual. 12. The method of claim 9, wherein the use of the composition comprises spraying the composition into the area. 13. The method of claim 9, wherein the use of the composition comprises placing the composition in an area. 14. The method of claim 9, wherein the use of the composition comprises incinerating the composition to release its components into the environment to repel insects in that environment. 15. The method of claim. 9, where the use of the composition includes spraying or spraying the composition, made in the form of a solution for application as a liquid. 16. The method according to p. 9, where the composition contains: 12-18% 2,6-dimethyl-7-octen-2-ol; 0.1-1% 2,6-octadienal, 3,7-dimethyl-; 2-5% benzyl benzoate; 0.01-1% citral; 2-5% hexamethylindanopyran; 25-30% lavender oil; 30-40% Argentine lemon oil; 5-10% Mexican distilled lime oil; 0.01-0.1% limonene; And 5-10% rosemary oil. 17. The method of claim 16, wherein the composition further comprises 0.1-10% of an insect repellent active ingredient selected from the group consisting of N,N-diethylmetatoluamide (DETA), ethyl butylacetylaminopropionate, and picaridin. 18. The composition of claim. 5, additionally containing 0.1-10 wt.% alcohol selected from the group consisting of isopropanol, methanol and ethanol. 19. The composition according to claim 2, further comprising an inactive carrier, which in combination thereby forms a local localization. 20. The composition according to claim 2, wherein said composition is in the form of a solution for application in the form of a spray or aerosol. 21. The method of claim 10, wherein the use of the composition comprises applying the composition to an individual to thereby repel insects from the individual. 22. The method of claim 10, wherein the use of the composition comprises spraying the composition into the area. 23. The method of claim. 10, where the use of the composition includes placing the composition in the area.