GR1009187B - Mosquito-repelling and/or insecticide composition containing natural molecules of geranial and citral in precise concentrations - Google Patents

Abstract

The invention relates to a mosquito-repelling and/or insecticide composition containing natural molecules of geranial and citral in precise concentrations. The composition comes in the form of wax, gel, and liquid to be sprayed or diffused via an electric liquid evaporation device. The invention exhibits insecticide or mosquito-repelling action.

Description

DESCRIPTION

Insect repellent and/or insecticidal composition against mosquitoes which includes natural molecules of Geraniol and Citral in specific concentrations

Technical field of the invention

The invention relates to the pesticidal properties of compositions that combine molecules of natural Citral and natural Geraniol. After effectiveness tests, it has been proven that the composition ensures excellent repellency against many species of mosquitoes.

State of the art

The common perception that natural products can be friendlier to people and the environment than their synthetic counterparts, and at the same time just as effective, has led many industries to enrich their product range with natural products. The main goal is to identify, in nature, molecules that can replace their synthetic "counterparts" in forms that offer the same results to the consumer.

In the field of biocides, efforts are focused on the discovery of natural molecules that can be active against microorganisms (viruses and bacteria) and insects, or on the development of formulas based on mixtures of natural active ingredients that can on the one hand lead to effective products and on the other hand present lower risks to humans, pets and the environment The need to explore natural active ingredients and their properties comes from the common belief that the molecules in question may have evolved over thousands or even millions of years and thus be more selective in their action than their laboratory-grown counterparts. In other words, the notion that a naturally occurring molecule can have pesticidal, for example, activity, and at the same time can harm only the target insect while leaving other organisms intact, is gaining wider acceptance. Of course this perception is based more on emotion than logic and is not always accurate. Today it is scientifically known that some of the most dangerous poisons involve naturally occurring substances. Additionally, many naturally occurring molecules have been shown to have a wide range of activity affecting a wide variety of microorganisms or insects. Many times the effects of these naturally occurring molecules on the environment and mammals are undesirable. However, it is clear that in order to assess the effectiveness but above all the safety of a natural active product (or a natural product in general) it is vital to follow all the steps required to evaluate any molecule, regardless of whether it is natural or synthetic.

However, the mentioned emotional approach (that natural molecules can be effective and pose less risks to the environment and humans) has been proven accurate in many cases. A well-known example is natural pyrethrum. Natural pyrethrum is usually a mixture of natural Pyrethrins I and II, which, while having demonstrated sufficient efficacy against crawling and flying insects, has relatively low toxicity to humans and the environment. Therefore, although it may not be the norm, there is in several cases the theoretical scientific basis that supports this common perception. Of particular interest and promising results is the research of such new molecules or mixtures of natural molecules that can be effective and selective in their action.

According to the International Organization for Certification (ISO), "essential oil" is the term we use for "a product derived from a natural raw material of plant origin, through steam distillation, through mechanical processing from the exocarp of citrus fruits, or through dry distillation, after separation of the aqueous phase — if any — by physical treatment" [ISO 9235, http://www.iso.ore/iso/cataloeue detail.htm?csnumber=510171. Additionally, terpenes are "products consisting primarily of terpene hydrocarbons that are by-products of an essential oil by distillation, concentration, or other separation techniques" [ISO 9235, https://www.iso.ore/obp/ui/#iso:std: iso:9235:ed-2:yl:en:term:2.111 . Consequently, a product of plant origin, of medicinal importance, for the protection of humans against insects, has no fixed characteristics. In addition, from its main components (mainly terpenes) condensation and isomerization (some compounds, with the same molecular formula, exist in different forms - isomers) depend on many factors such as the geographical location of the harvest, the time of harvest and abiotic agents (non-living components of the biosphere).

Today there are a number of known active ingredients of natural origin with pesticidal and/or insect repellent properties. As mentioned above, in nature, essential oils derived from plants do not have constant characteristics from harvest to harvest and from one year to another, because these characteristics depend on factors such as the time of harvest within the year, weather conditions , the geographic location of the harvest, human interaction and other environmental factors. Also essential oils are compounds made up of many different molecules - their overall action/efficacy is usually considered in relation to their basic characteristics. In recent decades it has become common practice to move research and development of natural products away from natural oils and focus more on natural molecules, which are the essential components of oils, and more specifically on those molecules that may act against a organism (in our case, insects). The main source of natural oils or natural active ingredients are plants. In many cases, the extraction of these molecules can be done by animals, or even microorganisms, as is the case with the insecticidal molecule Spinosyn A, which comes from the species of bacteria Saccharopolyspora spinosa. To date, however, the vast majority of active molecules, especially in the case of insecticides, come from plants.

Medicinal plants are part of traditional culture and in many cases it is assumed that insect repellents or insecticides derived from plants are safer or less harmful or smell worse than commercial insect repellents [World Health Organization, WHO/Danida Course on the Appropriate Methodology for the Selection and Use of Traditional Remedies in National Health Care Programs. Document WHO/TRM/91.1, Geneva: World Health Organization, 1989], [Witting-Bissinger, B. E., Stumpf, C. F., Donohue, K. V., Apperson, C. S., & Roe, R. M. (2008). Novel arthropod repellent, BioUD, is an effective alternative to deet. Journal of medical entomology, 45(5), 891-898], [Goodyer, L., & Behrens, R.H. (1998). Short report: The safety and toxicity of insect repellents. The American journal of tropical medicine and hygiene, 59(2), 323-324], [White GB, Terminology of insect repellents, in Insect Repellents: Principles, Methods, and Uses, ed. by Debboun M, Frances SP and Strickman D. CRC Press, London, UK, pp. 31-46 (2007)], [Logan, J. G., 8i Birkett, M. A. (2007). Semiochemicals for biting fly control: their identification and exploitation. Pest Management Science, 63(7), 647-657]. There are patents aimed at solving specific problems using said molecules. Many are considered disinfectants or other medicinals and of course many pesticides to treat infestations by many types of insects both in the home and in public places. The pesticidal effect of pyrethrum, in particular, has been known for centuries and its use as an insecticide is particularly widespread worldwide. The name Pyrethrum was used for the genus of several Old World plants now classified as Chrysanthemum or Tanacetum (eg, C. coccineum) which were cultivated as ornamentals for their showy flowers. The term Pyrethrum continues to be used as a common name for plants formerly included in the genus Pyrethrum. Pyrethrum is also the name of a natural insecticide made from dried flowers of Chrysanthemum cinerariifolium and Chrysanthemum coccineum. Today, several synthetic additives are used to enhance the action of natural pyrethrum as an insecticide. The most common is piperonyl butoxide or PBO. Piperonyl butoxide (PBO) is an organic compound used as an ingredient in pesticidal formulations. It is a waxy white solid that acts as a synergist. That is, while it does not have any pesticidal activity by itself, this substance enhances the ability of certain pesticides such as carbamide compounds, pyrethrins, pyrethroids, and rotenone. PBO is a semi-synthetic derivative of safrole that was developed in the late 1930s and early 1940s to enhance the performance of the naturally occurring insecticide pyrethrum. Pyrethrum was and is an important insecticide against mosquitoes and other disease vectors, thus providing important public health benefits, e.g. malaria prevention. Although it has little intrinsic insecticidal activity by itself, PBO increases the effectiveness of Pyrethrins and for this reason together they are called synergistic substances. PBO was first patented in 1947 in the US by Herman Wachs.

Citral consists of a pair of terpenoids, geranial and vermilion. The aforementioned terpenoids are isomers (based on the position of the double bonds) and thus have the same molecular formula: C10H16O. Geranial (also known as citral A) is the trans isomer, while geranial is the c/s isomer (also known as citral B). Citral is the main component of many members of the genus Cymbopogon and several citrus plants. Citral is commonly used in the perfume industry and is also effective as an insect repellent. Some of the plants whose oils contain citral are: Cymbopogon flexuosus (East Indian lemongrass), Cymbopogon citratus (lemongrass), Cymbopogonwinterianus (Javanese citronella), Zingiber officinale (Ginger or ginger), Ocimum basilicum (basil), Aloysia citrodora, Citrus limon, and Mentha rotundifolia. [Sarah J. Moore, Annick Lenglet, and Nigel Hill (2007) Plant-Based Insect Repellents. In: Debboun M, Frances SP, Strickman D. (eds) Insect Repellents: Principles, Methods and Uses. CRC Press, Boca Raton, p 147]. Geraniol (also known as rhodinol) is a monoterpene and its functional group is alcohol. It is the main component of rose oil and palmarosa and is also found in smaller amounts in citronella and essential oils derived from Lamiaceae plants. It is also found in many plants, such as Thymus vulgaris (common thyme), Ocimum gratissimum (bush basil), O. basilicum (basil), Cymbopogon nardus (citronella), C. martinii (palmarosa), C. winterianus (Java citronella), C. citratus (lemongrass), C. flexuosus (East Indian lemongrass), Pelargonium graveolens (scented pelargonium), Corymbia citriodora (lemon eucalyptus), Zingiber officinale (Ginger or ginger), and Mentha longifolia (peppermint). Geraniol is a component of many commercial insect repellents [Sarah J. Moore, Annick Lenglet, and Nigel Hill (2007) Plant-Based Insect Repellents. In: Debboun M, Frances SP, Strickman D. (eds) Insect Repellents: Principles, Methods and Uses. CRC Press, Boca Raton, p 147].

Both molecules (Kitral and Geraniol) have a very characteristic odor and by using them as active synergists there is no need to use synthetic fragrances in the final insecticide product to mark their use. This is important because all insecticides must have a scent as it is the best way to mark their use indoors and warn the consumer.

The insect repellent and insecticidal properties of Citral and Geraniol have already been described in previous studies. However, they have never described specific concentrations of their mixture, especially for the citral isomers. It should be noted that while isomers are compounds with the same molecular formula, they do not necessarily share similar properties. When conducting bioassays with citral it is difficult to predict bioefficacy results. This is due to the fact that the two compounds derived from Citral are isomers, based on the position of the double bonds, and their ratio is not constant (Geraniol and Neral). The invention is disclosed in detail in the claims. In this respect, the present invention utilizes specific compounds at an optimal concentration to control insects of medical importance. As disclosed below, the text of the invention mentions as examples a specific mixture (Geraniol with Citral) and its evaluation (activity) against mosquitoes.

These fixed ratios (specific concentrations) are crucial in that they allow reproducibility of results for each test/evaluation of the current mixture regardless of its natural origin. In addition, when conducting bioassays with insects of medical importance, traceability is a key factor for the mixture/product being tested. The last element is crucial for companies producing new insect repellents (repellent manufacturers) because they need to facilitate and speed up the licensing process.

Detailed description of the invention

MIXTURE "GERANIOL WITH GERAN YALI AND NERALI" IN CANDLE

The invention relates to a mixture of Geraniol with Geranial (Citral A) and Neral (Citral B), among others, in a wax. All "insect repellent candles" were prepared using 240 - 260 g of paraffin wax containing 6% Geraniol, 2% Geranial and 2% Neral. Each candle had the same weight: 240 gr or 260 gr. A wax of the same weight without any component (only wax / paraffin) was used as a control. The candles were placed in metal mugs, the mugs had dimensions of 94mm diameter and 49mm style.

"GERANIOL WITH GERANIAL AND NERALI" MIXTURE IN ELECTRIC LIQUID SHEARING DEVICE (LED)

The invention relates to a mixture of Geraniol with Geranial (Kitral A) and Neral (Kitral B), among others, in LEDs. The LEDs used in the experiments were produced using 78.5% isopropyl myristate, 10% PPG-2 Methyl Ether, and 1.5% BHT, 8% Geraniol, 1% Geranial, and 1% Neral. Each LED bottle had the same weight: 30 gr. The bottles were connected to an electric diffusion device that helped the active substances (Geraniol / Geranial / Neral) to be mixed through a ceramic plate using thermal sonication.

Evaluation of the bioactivity of the mixture of "Geraniol with Geranial and Neral" in a wax against Culex mites under field conditions.

For the repellent effect of the mixture of "Geraniol with Geranial and Neral" in wax the evaluation was based on human contact measurements (Govere JM, Durrheim DV (2006) In: Insect Repellents: Principles, Methods and Uses. Debboun M, Frances SP, Strickman D, editor. Boca Raton Florida: CRC Press; 2006. Techniques for evaluating repellents; Giatropoulos, A., Papachristos, D.P., Kimbaris, A., Koliopoulos, G., Polissiou, M.G., Emmanouel, N. and Michaelakis, A. Evaluation of bioefficacy of three Citrus essential oils against the dengue vector Aedes albopictus (Diptera: Culicidae) in correlation to their components enantiomeric distribution. Parasitology Research, 2012, 111, 2253-2263). The study was conducted on 2 consecutive nights: in urban suburban areas (summer period) and times: from 21:00 to 22:00 (for both areas on the first two days). Control treatments, waxes without ingredients, were also used for repellency tests as standards on the third day. The two inventors acted as volunteers and thus were fully aware of the nature and purposes of the test and provided full consent, after medical review. Both volunteers abstained from alcohol, caffeine and fragrance products throughout the effect studies. The right arms and hands of the volunteers were used as the "test area" for the impact studies. The rest of the body, outside the test area, was covered with clothes, and especially for the head and neck, the volunteers wore hats with a mosquito net.

The two volunteers were 12 m apart and changed position in each repetition (position exchange to avoid site preference). The candles (with or without mixture) were placed on a table half the distance from each volunteer (5m from each). Mosquito activity was recorded by each volunteer at 5 minute intervals (within one hour 6 intervals - repetitions). Before starting each treatment, volunteers checked the density and willingness of mosquitoes to bite (to ensure mosquito activity). Each treatment (day) started five minutes after lighting the candle (with or without the mixture) to ensure evaporation of the mixture. Mosquito contacts were counted and mosquitoes were removed (by blowing) from the test area before any blood collection. Mosquito samples were collected at each treatment (day) and then identified as belonging mainly to Culex species. The mean number of mosquito activity (contacts) for each treatment (day) is shown in Table 1. Differences in number of contacts are detected between treatments and control trials. In the untreated control (unmixed candles) a large number of contacts were found (23 contacts on average), while the mixed candles provided complete protection (almost zero contacts). The results revealed that the mixture of Geraniol with Geranial and Neral in a wax (ie the disclosed invention) had strong repellent properties against Culex mosquito species.

Bioactivity evaluation of "Geraniol with Geranial and Neral" mixture in Asian tiger mosquito wax under field conditions. For the repellent effect of the mixture of "Geraniol with Geranial and Neral" in a candle the evaluation was based on human contact measurements (Govere JM, Durrheim DV (2006) In: Insect Repellents: Principles, Methods and Uses. Debboun M, Frances SP, Strickman D, editor. Boca Raton Florida: CRC Press; 2006. Techniques for evaluating repellents; Giatropoulos, A., Papachristos, D.P., Kimbaris, A., Koliopoulos, G., Polissiou, M.G., Emmanouel, N. and Michaelakis, A. . Evaluation of bioefficacy of three Citrus essential oils against the dengue vector Aedes albopictus (Diptera: Culicidae) in correlation to their components enantiomeric distribution. Parasitology Research, 2012, 111, 2253-2263). The study was conducted on 2 consecutive nights: in urban suburban areas (autumn period) and times: from 19:00 to 20:00 (for both areas on the first two days). Control treatments, i.e. candles without ingredients, were also used for repellency tests as standards on the third day. The two inventors acted as volunteers and thus were fully aware of the nature and purposes of the test and provided full consent, after medical review. Both volunteers abstained from alcohol, caffeine and fragrance products throughout the effect studies. The right arms and hands of the volunteers were used as the "test area" for the impact studies. The rest of the body, outside the test area, was covered with clothes, and especially for the head and neck, the volunteers wore hats with a mosquito net.

The two volunteers were 12 m apart and changed position in each repetition (position exchange to avoid site preference). The candles (with or without mixture) were placed on a table half the distance from each volunteer (5m from each). Mosquito activity was recorded by each volunteer at 5 minute intervals (within one hour 6 intervals - repetitions). Before starting each treatment, volunteers checked the density and willingness of mosquitoes to bite (to ensure mosquito activity). Each treatment (day) started five minutes after lighting the candle (with or without the mixture) to ensure evaporation of the mixture. Mosquito contacts were counted and mosquitoes were removed (by blowing) from the test area before any blood collection. Mosquito species were collected in each treatment (day) and later identified mainly as Aedes albopictus, also known as (Asian) tiger mosquitoes (and some Culex mosquito species).

The mean number of mosquito activity (contacts of Aedes albopictus only) for each treatment (day) is presented in Table 2. Differences in the number of contacts are detected between treatments and control trials. In the untreated control (unmixed candles) a large number of contacts were found (average =21 contacts), while the mixed candles provided complete protection (almost zero contacts). The results revealed that the mixture of Geraniol with Geranial and Neral in a wax (ie the disclosed invention) had strong repellent properties against the mosquito species Aedes albopictus.

Evaluation of the bioactivity of the mixture of "Geraniol with Geranial and Neral" in a liquid shear electric device (LED) against Culex Pipiens and Asian tiger (Aedes albopictus) mosquitoes under controlled laboratory conditions.

Did the test method follow WHO/HTM/NTD/WHOPES/2009.3 Guidelines? FOR TESTING THE EFFECTIVENESS OF INSECTICIDE PRODUCTS FOR HOUSEHOLDS. The specific method is part of the Annex of approved methodologies for the registration of Biocides, in the "DRAFT Guidelines for the replacement of part of the Annexes in chapter 7 (pages 187 to 200) by the Technical Notes for Guidance (TNsG) on Product evaluation". Deviations from the standard:

The test chamber was a 49 m3 room made of glass and non-absorbent materials (6.5m high x 3m wide x 4m long) and with a constant temperature of 25°C+2ºC and a relative humidity of 65%+5% during the tests . Ventilation was disabled during the tests. Insects were released into the test chamber (flying freely). The diffuser was activated 1 h before the insects were introduced into the chamber. 50+/-2 mosquitoes were released into the test chamber. The experimenter recorded insect paralysis at intervals to calculate KT50 and KT100 values (Killing Time 50% and 100% = the exposure time required to achieve 50% and 100% kills/paralysis). Climatic conditions: 28°C+1°C 75+5% RH light 1200 lux. Control of non-treated insects: some insects were managed in the same way but without the treatment to check the viability of the live material. The insect control was carried out with two objectives:

• observation of the effect of paralysis (KD),

• observation of lethal effect.

Most classical insecticides act on the nervous system and cause a series of successive symptoms: agitation, lack of coordination of movements, paralysis (knock down) and lethargy which finally leads to a fatal effect. These different stages are closely related to the dose of the active substance acting on the body. From a practical point of view, two main stages of the symptomatology are distinguished: the paralysis stage and the fatal stage. The paralysis stage can occur more or less quickly (shock effect) depending on the insecticide or acaricidal substance and depending on the dose. The return to normal behavior can occur after a more or less long period of paralysis (several days), always depending on the dose of the treatment and the duration of contact of the animal with the stock of the preparation. The lethal effect does not necessarily occur after the period of paralysis. Observations conducted on arthropods must take into account these two types of effect. • Observation of paralysis effect: count of paralysis is done at regular intervals during an exposure period of maximum 8 hours. The paralysis effect is judged by several counts of organisms that move normally and the rest (those unable to fly). • Observation of the lethal effect: 24 hours after exposure, counts of dead and live insects are made. All immobile insects that do not respond to a mechanical stimulus and any insect that, although still able to move its legs, is unable to move, is considered dead. At the end of the exposure period (8 h), all insects are collected by gentle suction into containers with sugar solution and stored in a room maintained at the same temperature and humidity as for the test.

The test chamber is washed, dried and ventilated with an exhaust fan of 1200 m3/h. Before testing each product, free-flying female mosquitoes are released into the chamber for 60 minutes, then collected with aspirators, transferred to holding cups, where they are provided with a 10% sugar solution on cotton and held for 24 hours at 27 ± 2 °C and 80 ± 10% RH for mortality observation. If mortality exceeds 20% in the control lot, the results of the entire test are rejected. 4 replicates per product were conducted.

Controlled insects:

Mosquitoes: 50+/-2 female Culex pipiens and Aedes albopictus mosquitoes, four to six days old, from laboratory-reared colonies since 1992 (origin from strains: ORSTOM / WHO - strain Bora-Bora and SEAMAR - strain Mouguerre 64). Females were not allowed a blood meal for 24 h prior to testing. No anesthetic was used to prepare the batches (insects were removed from the rearing cages extemporaneously).

Lifetime:

Efficacy was assessed after opening and after 35 8-hour nights (supported persistence). Between each trial, the perfusion device was set to release mode in a climate-controlled chamber with a timer so that there were 8 hours of activation per day. Climatic conditions in the storage/release chamber: 28°C+1°C ; 75+5% RH ; 8 hours light 1200 lux / 16 hours darkness, mild ventilation 20 m3/h.

Product, Dosage:

The experimental product consists of an electric diffusion device and a liquid replacement:

Electric diffusion device - Zelnova 1 - 2131

Liquid Replacement 4349 15/12/14 Active 4/6 2/5

DOSAGE: 1 diffuser in 49 m3. One hour pre-diffusion and then continuous diffusion during test.

RESULTS PARALYSIS / Summary of results (repetition means):

KT50 and KT100 = exposure time to achieve 50% and 100% paralysis OPENING TEST

TEST AT THE END OF LIFE (+35 x 8 hours)

Household insecticides are intended to have a "paralyzing effect" and an eventual lethal effect. The product was shown to have an effective paralyzing insecticidal effect and there was no recovery after 24 hours. The lethal effect was complete.

Claims (1)

1- Insect repellent and/or insecticidal composition against mosquitoes, which is characterized by including natural molecules of Geraniol and Citral in a specific concentration range, and, in particular, 6 - 8% Geraniol (Geraniol), 1 - 2% Geranial (Geranial or CitralA), and 1 - 2% Neral (Neral or CitralB). 2- Insect repellent and/or insecticidal composition against mosquitoes, according to claim 1, which is contained in a wax formulation. 3- Insect repellent and/or insecticidal composition against mosquitoes, according to claim 2, characterized in that the wax has been produced from paraffin. 4- Insect repellent and/or insecticidal composition against mosquitoes, according to claim 1, characterized in that it is in the form of a liquid, which is applied by spraying. 5- Insect repellent and/or insecticidal composition against mosquitoes, according to claim 1, in gel form. 6 - Insect repellent and/or insecticidal composition against mosquitoes, according to claim 1, characterized in that it is in liquid form, which is used with an electric liquid shearing device for insecticidal and/or insect repellent use against mosquitoes (LED).